diff --git a/esmvaltool/cmor/check.py b/esmvaltool/cmor/check.py index b46d1cb93d..3694b2c248 100644 --- a/esmvaltool/cmor/check.py +++ b/esmvaltool/cmor/check.py @@ -64,7 +64,7 @@ def __init__(self, self._errors = list() self._warnings = list() self._cmor_var = var_info - if frequency is None: + if not frequency: frequency = self._cmor_var.frequency self.frequency = frequency self.automatic_fixes = automatic_fixes diff --git a/esmvaltool/cmor/table.py b/esmvaltool/cmor/table.py index 805ede3a6a..f8006b02f0 100644 --- a/esmvaltool/cmor/table.py +++ b/esmvaltool/cmor/table.py @@ -76,6 +76,7 @@ def __init__(self, cmor_tables_path, default=None): self.default = default self.tables = {} + self.var_to_freq = {} self._load_coordinates() for json_file in glob.glob(os.path.join(self._cmor_folder, '*.json')): @@ -98,22 +99,25 @@ def _load_table(self, json_file): return table = TableInfo() header = raw_data['Header'] - table.name = header['table_id'][6:].split('_')[-1] - self.tables[table.name] = table - + table.name = header['table_id'].split(' ')[-1] generic_levels = header['generic_levels'].split() + table.realm = header['realm'].split() table.frequency = header.get('frequency', '') - table.realm = header.get('realm', '') + self.var_to_freq[table.name] = {} for var_name, var_data in raw_data['variable_entry'].items(): var = VariableInfo('CMIP6', var_name) - if 'frequency' in var_data: - var.frequency = var_data['frequency'] - else: - var.frequency = table.frequency - var.read_json(var_data) + var.read_json(var_data, table.frequency) self._assign_dimensions(var, generic_levels) table[var_name] = var + self.var_to_freq[table.name][var_name] = var.frequency + + if not table.frequency: + from collections import Counter + var_freqs = (var.frequency for var in table.values()) + table_freq, _ = Counter(var_freqs).most_common(1)[0] + table.frequency = table_freq + self.tables[table.name] = table def _assign_dimensions(self, var, generic_levels): for dimension in var.dimensions: @@ -184,7 +188,12 @@ def get_variable(self, table, short_name): new_short_name = CMIP6Info._CMIP_5to6_varname[short_name] return self.get_variable(table, new_short_name) if self.default: - return self.default.get_variable(table, short_name) + var_info = self.default.get_variable(table, short_name) + if var_info is None: + return None + var_info = var_info.copy() + var_info.frequency = self.tables[table].frequency + return var_info return None @staticmethod @@ -217,7 +226,7 @@ class JsonInfo(object): def __init__(self): self._json_data = {} - def _read_json_variable(self, parameter): + def _read_json_variable(self, parameter, default=''): """ Read a json parameter in json_data. @@ -233,7 +242,7 @@ def _read_json_variable(self, parameter): """ if parameter not in self._json_data: - return '' + return default return str(self._json_data[parameter]) def _read_json_list_variable(self, parameter): @@ -297,7 +306,20 @@ def __init__(self, table_type, short_name): self._json_data = None - def read_json(self, json_data): + def copy(self): + """ + Returns a shalow copy of VariableInfo + + Returns + ------- + VariableInfo + Shallow copy of this object + + """ + from copy import copy + return copy(self) + + def read_json(self, json_data, default_freq=''): """ Read variable information from json. @@ -309,6 +331,9 @@ def read_json(self, json_data): dictionary created by the json reader containing variable information + default_freq: str + Default frequency to use if it is not defined at variable level + """ self._json_data = json_data @@ -320,6 +345,7 @@ def read_json(self, json_data): self.positive = self._read_json_variable('positive') self.modeling_realm = \ self._read_json_variable('modeling_realm').split() + self.frequency = self._read_json_variable('frequency', default_freq) self.dimensions = self._read_json_variable('dimensions').split() @@ -556,7 +582,12 @@ def get_variable(self, table, short_name): """ var_info = self.tables.get(table, {}).get(short_name, None) if not var_info and self.default: - return self.default.get_variable(table, short_name) + var_info = self.default.get_variable(table, short_name) + if var_info is None: + return None + var_info = var_info.copy() + var_info.frequency = self.tables[table].frequency + return var_info return var_info @@ -576,6 +607,7 @@ def __init__(self, cmor_tables_path=None): cwd = os.path.dirname(os.path.realpath(__file__)) self._cmor_folder = os.path.join(cwd, 'tables', 'custom') self.tables = {} + self.var_to_freq = {} table = TableInfo() table.name = 'custom' self.tables[table.name] = table @@ -626,9 +658,18 @@ def get_variable(self, table, short_name): found, returns None if not """ - return self.tables['custom'].get(short_name, None) + var_info = self.tables['custom'].get(short_name, None) + return var_info def _read_table_file(self, table_file, table=None): + with open(table_file, 'r') as cmor_table: + all_lines = cmor_table.readlines() + all_lines = [x.strip() for x in all_lines] + keys_vals = [x.split(':') for x in all_lines] + var_frequency = None + for key in keys_vals: + if key[0] == 'frequency': + var_frequency = key[1].strip() with open(table_file) as self._current_table: self._read_line() while True: @@ -643,7 +684,8 @@ def _read_table_file(self, table_file, table=None): self.coords[value] = self._read_coordinate(value) continue elif key == 'variable_entry': - table[value] = self._read_variable(value, None) + self.var_to_freq[value] = var_frequency + table[value] = self._read_variable(value, var_frequency) continue if not self._read_line(): return diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_3hr.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_3hr.json index d9eb7a6f6f..b8ce631cff 100644 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_3hr.json +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_3hr.json @@ -1,27 +1,28 @@ { "Header": { - "data_specs_version": "01.00.10", + "data_specs_version": "01.00.30", + "cmor_version": "3.4", "table_id": "Table 3hr", "realm": "atmos", - "frequency": "3hr", - "cmor_version": "3.2", - "table_date": "10 May 2017", + "table_date": "11 March 2019", "missing_value": "1e20", + "int_missing_value": "-999", "product": "model-output", "approx_interval": "0.125000", "generic_levels": "", "mip_era": "CMIP6", - "Conventions": "CF-1.7 CMIP-6.0" + "Conventions": "CF-1.7 CMIP-6.2" }, "variable_entry": { "clt": { + "frequency": "3hr", "modeling_realm": "atmos", "standard_name": "cloud_area_fraction", "units": "%", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Total Cloud Fraction", - "comment": "Total cloud area fraction for the whole atmospheric column, as seen from the surface or the top of the atmosphere. Includes both large-scale and convective cloud.", + "long_name": "Total Cloud Cover Percentage", + "comment": "Total cloud area fraction (reported as a percentage) for the whole atmospheric column, as seen from the surface or the top of the atmosphere. Includes both large-scale and convective cloud.", "dimensions": "longitude latitude time", "out_name": "clt", "type": "real", @@ -32,13 +33,14 @@ "ok_max_mean_abs": "" }, "hfls": { + "frequency": "3hr", "modeling_realm": "atmos", "standard_name": "surface_upward_latent_heat_flux", "units": "W m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Surface Upward Latent Heat Flux", - "comment": "", + "comment": "The surface called 'surface' means the lower boundary of the atmosphere. 'Upward' indicates a vector component which is positive when directed upward (negative downward). The surface latent heat flux is the exchange of heat between the surface and the air on account of evaporation (including sublimation). In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions": "longitude latitude time", "out_name": "hfls", "type": "real", @@ -49,13 +51,14 @@ "ok_max_mean_abs": "" }, "hfss": { + "frequency": "3hr", "modeling_realm": "atmos", "standard_name": "surface_upward_sensible_heat_flux", "units": "W m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Surface Upward Sensible Heat Flux", - "comment": "", + "comment": "The surface sensible heat flux, also called turbulent heat flux, is the exchange of heat between the surface and the air by motion of air.", "dimensions": "longitude latitude time", "out_name": "hfss", "type": "real", @@ -66,9 +69,10 @@ "ok_max_mean_abs": "" }, "huss": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "specific_humidity", - "units": "1.0", + "units": "1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", "long_name": "Near-Surface Specific Humidity", @@ -83,6 +87,7 @@ "ok_max_mean_abs": "" }, "mrro": { + "frequency": "3hr", "modeling_realm": "land", "standard_name": "runoff_flux", "units": "kg m-2 s-1", @@ -100,8 +105,9 @@ "ok_max_mean_abs": "" }, "mrsos": { + "frequency": "3hrPt", "modeling_realm": "land", - "standard_name": "moisture_content_of_soil_layer", + "standard_name": "mass_content_of_water_in_soil_layer", "units": "kg m-2", "cell_methods": "area: mean where land time: point", "cell_measures": "area: areacella", @@ -117,6 +123,7 @@ "ok_max_mean_abs": "" }, "pr": { + "frequency": "3hr", "modeling_realm": "atmos", "standard_name": "precipitation_flux", "units": "kg m-2 s-1", @@ -134,6 +141,7 @@ "ok_max_mean_abs": "" }, "prc": { + "frequency": "3hr", "modeling_realm": "atmos", "standard_name": "convective_precipitation_flux", "units": "kg m-2 s-1", @@ -151,13 +159,14 @@ "ok_max_mean_abs": "" }, "prsn": { + "frequency": "3hr", "modeling_realm": "atmos", "standard_name": "snowfall_flux", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Snowfall Flux", - "comment": "at surface; includes precipitation of all forms of water in the solid phase", + "comment": "At surface; includes precipitation of all forms of water in the solid phase", "dimensions": "longitude latitude time", "out_name": "prsn", "type": "real", @@ -168,6 +177,7 @@ "ok_max_mean_abs": "" }, "ps": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "surface_air_pressure", "units": "Pa", @@ -185,13 +195,14 @@ "ok_max_mean_abs": "" }, "rlds": { + "frequency": "3hr", "modeling_realm": "atmos", "standard_name": "surface_downwelling_longwave_flux_in_air", "units": "W m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Surface Downwelling Longwave Radiation", - "comment": "", + "comment": "The surface called 'surface' means the lower boundary of the atmosphere. 'longwave' means longwave radiation. Downwelling radiation is radiation from above. It does not mean 'net downward'. When thought of as being incident on a surface, a radiative flux is sometimes called 'irradiance'. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called 'vector irradiance'. In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions": "longitude latitude time", "out_name": "rlds", "type": "real", @@ -202,6 +213,7 @@ "ok_max_mean_abs": "" }, "rldscs": { + "frequency": "3hr", "modeling_realm": "atmos", "standard_name": "surface_downwelling_longwave_flux_in_air_assuming_clear_sky", "units": "W m-2", @@ -219,13 +231,14 @@ "ok_max_mean_abs": "" }, "rlus": { + "frequency": "3hr", "modeling_realm": "atmos", "standard_name": "surface_upwelling_longwave_flux_in_air", "units": "W m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Surface Upwelling Longwave Radiation", - "comment": "", + "comment": "The surface called 'surface' means the lower boundary of the atmosphere. 'longwave' means longwave radiation. Upwelling radiation is radiation from below. It does not mean 'net upward'. When thought of as being incident on a surface, a radiative flux is sometimes called 'irradiance'. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called 'vector irradiance'. In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions": "longitude latitude time", "out_name": "rlus", "type": "real", @@ -236,13 +249,14 @@ "ok_max_mean_abs": "" }, "rsds": { + "frequency": "3hr", "modeling_realm": "atmos", "standard_name": "surface_downwelling_shortwave_flux_in_air", "units": "W m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Surface Downwelling Shortwave Radiation", - "comment": "surface solar irradiance for UV calculations", + "comment": "Surface solar irradiance for UV calculations.", "dimensions": "longitude latitude time", "out_name": "rsds", "type": "real", @@ -253,13 +267,14 @@ "ok_max_mean_abs": "" }, "rsdscs": { + "frequency": "3hr", "modeling_realm": "atmos", "standard_name": "surface_downwelling_shortwave_flux_in_air_assuming_clear_sky", "units": "W m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Surface Downwelling Clear-Sky Shortwave Radiation", - "comment": "surface solar irradiance clear sky for UV calculations", + "comment": "Surface solar irradiance clear sky for UV calculations", "dimensions": "longitude latitude time", "out_name": "rsdscs", "type": "real", @@ -270,30 +285,32 @@ "ok_max_mean_abs": "" }, "rsdsdiff": { + "frequency": "3hr", "modeling_realm": "atmos", "standard_name": "surface_diffuse_downwelling_shortwave_flux_in_air", "units": "W m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Surface Diffuse Downwelling Shortwave Radiation", - "comment": "", + "comment": "Surface downwelling solar irradiance from diffuse radiation for UV calculations.", "dimensions": "longitude latitude time", "out_name": "rsdsdiff", "type": "real", - "positive": "", + "positive": "down", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "rsus": { + "frequency": "3hr", "modeling_realm": "atmos", "standard_name": "surface_upwelling_shortwave_flux_in_air", "units": "W m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Surface Upwelling Shortwave Radiation", - "comment": "", + "comment": "The surface called 'surface' means the lower boundary of the atmosphere. 'shortwave' means shortwave radiation. Upwelling radiation is radiation from below. It does not mean 'net upward'. When thought of as being incident on a surface, a radiative flux is sometimes called 'irradiance'. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called 'vector irradiance'. In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions": "longitude latitude time", "out_name": "rsus", "type": "real", @@ -304,6 +321,7 @@ "ok_max_mean_abs": "" }, "rsuscs": { + "frequency": "3hr", "modeling_realm": "atmos", "standard_name": "surface_upwelling_shortwave_flux_in_air_assuming_clear_sky", "units": "W m-2", @@ -321,6 +339,7 @@ "ok_max_mean_abs": "" }, "tas": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "air_temperature", "units": "K", @@ -337,16 +356,17 @@ "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, - "tslsi": { - "modeling_realm": "land", - "standard_name": "surface_temperature", - "units": "K", - "cell_methods": "area: mean (comment: over land and sea ice) time: point", - "cell_measures": "area: areacella", - "long_name": "Surface Temperature Where Land or Sea Ice", - "comment": "'skin' temperature of all surfaces except open ocean.", + "tos": { + "frequency": "3hrPt", + "modeling_realm": "ocean", + "standard_name": "sea_surface_temperature", + "units": "degC", + "cell_methods": "area: mean where sea time: point", + "cell_measures": "area: areacello", + "long_name": "Sea Surface Temperature", + "comment": "Temperature of upper boundary of the liquid ocean, including temperatures below sea-ice and floating ice shelves.", "dimensions": "longitude latitude time1", - "out_name": "tslsi", + "out_name": "tos", "type": "real", "positive": "", "valid_min": "", @@ -354,16 +374,17 @@ "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, - "tso": { - "modeling_realm": "ocean", - "standard_name": "sea_surface_temperature", + "tslsi": { + "frequency": "3hrPt", + "modeling_realm": "land", + "standard_name": "surface_temperature", "units": "K", - "cell_methods": "area: mean where sea time: point", + "cell_methods": "area: mean (comment: over land and sea ice) time: point", "cell_measures": "area: areacella", - "long_name": "Sea Surface Temperature", - "comment": "temperature of surface of open ocean, sampled synoptically.", + "long_name": "Surface Temperature Where Land or Sea Ice", + "comment": "Surface temperature of all surfaces except open ocean.", "dimensions": "longitude latitude time1", - "out_name": "tso", + "out_name": "tslsi", "type": "real", "positive": "", "valid_min": "", @@ -372,12 +393,13 @@ "ok_max_mean_abs": "" }, "uas": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "eastward_wind", "units": "m s-1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "Eastward Near-Surface Wind Speed", + "long_name": "Eastward Near-Surface Wind", "comment": "Eastward component of the near-surface (usually, 10 meters) wind", "dimensions": "longitude latitude time1 height10m", "out_name": "uas", @@ -389,12 +411,13 @@ "ok_max_mean_abs": "" }, "vas": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "northward_wind", "units": "m s-1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "Northward Near-Surface Wind Speed", + "long_name": "Northward Near-Surface Wind", "comment": "Northward component of the near surface wind", "dimensions": "longitude latitude time1 height10m", "out_name": "vas", diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_6hrLev.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_6hrLev.json index e2ca5a56d6..9a7ee7ec02 100644 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_6hrLev.json +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_6hrLev.json @@ -1,30 +1,31 @@ { "Header": { - "data_specs_version": "01.00.10", + "data_specs_version": "01.00.30", + "cmor_version": "3.4", "table_id": "Table 6hrLev", "realm": "atmos", - "frequency": "6hr", - "cmor_version": "3.2", - "table_date": "10 May 2017", + "table_date": "11 March 2019", "missing_value": "1e20", + "int_missing_value": "-999", "product": "model-output", "approx_interval": "0.250000", - "generic_levels": "alevel", + "generic_levels": "alevel alevhalf", "mip_era": "CMIP6", - "Conventions": "CF-1.7 CMIP-6.0" + "Conventions": "CF-1.7 CMIP-6.2" }, "variable_entry": { "bs550aer": { + "frequency": "6hrPt", "modeling_realm": "aerosol", - "standard_name": "volume_lidar_backwards_scattering_coefficient_in_air_due_to_ambient_aerosol_particles", + "standard_name": "volume_scattering_function_of_radiative_flux_in_air_due_to_ambient_aerosol_particles", "units": "m-1 sr-1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "Aerosol backscatter coefficient", - "comment": "Aerosol Backscatter @550nm @ 180 degrees, computed from extinction and lidar ratio", - "dimensions": "longitude latitude alevel time1", + "long_name": "Aerosol Backscatter Coefficient", + "comment": "Aerosol Backscatter at 550nm and 180 degrees, computed from extinction and lidar ratio", + "dimensions": "longitude latitude time1 lambda550nm scatter180", "out_name": "bs550aer", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -32,16 +33,17 @@ "ok_max_mean_abs": "" }, "ec550aer": { + "frequency": "6hrPt", "modeling_realm": "aerosol", "standard_name": "volume_extinction_coefficient_in_air_due_to_ambient_aerosol_particles", "units": "m-1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "Aerosol extinction coefficient", - "comment": "Aerosol Extinction @550nm", - "dimensions": "longitude latitude alevel time1", + "long_name": "Aerosol Extinction Coefficient", + "comment": "Aerosol Extinction at 550nm", + "dimensions": "longitude latitude alevel time1 lambda550nm", "out_name": "ec550aer", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -49,13 +51,14 @@ "ok_max_mean_abs": "" }, "hus": { + "frequency": "6hrPt", "modeling_realm": "atmos", "standard_name": "specific_humidity", - "units": "1.0", + "units": "1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", "long_name": "Specific Humidity", - "comment": "", + "comment": "Specific humidity is the mass fraction of water vapor in (moist) air.", "dimensions": "longitude latitude alevel time1", "out_name": "hus", "type": "real", @@ -65,17 +68,18 @@ "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, - "pmlev": { + "pfull": { + "frequency": "6hrPt", "modeling_realm": "atmos", "standard_name": "air_pressure", "units": "Pa", - "cell_methods": "area: time: mean", + "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "Air Pressure", - "comment": "The atmospheric pressure at the model layer midpoints for all times and levels in the associated output variables", - "dimensions": "longitude latitude alevel time", - "out_name": "pmlev", - "type": "", + "long_name": "Pressure at Model Full-Levels", + "comment": "Air pressure on model levels", + "dimensions": "longitude latitude alevel time1", + "out_name": "pfull", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -83,6 +87,7 @@ "ok_max_mean_abs": "" }, "ps": { + "frequency": "6hrPt", "modeling_realm": "atmos", "standard_name": "surface_air_pressure", "units": "Pa", @@ -100,6 +105,7 @@ "ok_max_mean_abs": "" }, "ta": { + "frequency": "6hrPt", "modeling_realm": "atmos", "standard_name": "air_temperature", "units": "K", @@ -117,13 +123,14 @@ "ok_max_mean_abs": "" }, "ua": { + "frequency": "6hrPt", "modeling_realm": "atmos", "standard_name": "eastward_wind", "units": "m s-1", "cell_methods": "time: point", "cell_measures": "--OPT", "long_name": "Eastward Wind", - "comment": "", + "comment": "Zonal wind (positive in a eastward direction).", "dimensions": "longitude latitude alevel time1", "out_name": "ua", "type": "real", @@ -134,13 +141,14 @@ "ok_max_mean_abs": "" }, "va": { + "frequency": "6hrPt", "modeling_realm": "atmos", "standard_name": "northward_wind", "units": "m s-1", "cell_methods": "time: point", "cell_measures": "--OPT", "long_name": "Northward Wind", - "comment": "", + "comment": "Meridional wind (positive in a northward direction).", "dimensions": "longitude latitude alevel time1", "out_name": "va", "type": "real", diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_6hrPlev.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_6hrPlev.json index ec8a1fc662..5878a037e3 100644 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_6hrPlev.json +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_6hrPlev.json @@ -1,20 +1,21 @@ { "Header": { - "data_specs_version": "01.00.10", + "data_specs_version": "01.00.30", + "cmor_version": "3.4", "table_id": "Table 6hrPlev", "realm": "atmos", - "frequency": "6hr", - "cmor_version": "3.2", - "table_date": "10 May 2017", + "table_date": "11 March 2019", "missing_value": "1e20", + "int_missing_value": "-999", "product": "model-output", "approx_interval": "0.250000", "generic_levels": "", "mip_era": "CMIP6", - "Conventions": "CF-1.7 CMIP-6.0" + "Conventions": "CF-1.7 CMIP-6.2" }, "variable_entry": { "bldep": { + "frequency": "6hr", "modeling_realm": "aerosol", "standard_name": "atmosphere_boundary_layer_thickness", "units": "m", @@ -24,7 +25,7 @@ "comment": "Boundary layer depth", "dimensions": "longitude latitude time", "out_name": "bldep", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -32,6 +33,7 @@ "ok_max_mean_abs": "" }, "hurs": { + "frequency": "6hr", "modeling_realm": "atmos", "standard_name": "relative_humidity", "units": "%", @@ -49,16 +51,17 @@ "ok_max_mean_abs": "" }, "hus4": { + "frequency": "6hr", "modeling_realm": "atmos", "standard_name": "specific_humidity", - "units": "1.0", + "units": "1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Specific Humidity", - "comment": "", + "comment": "Specific humidity is the mass fraction of water vapor in (moist) air.", "dimensions": "longitude latitude plev4 time", "out_name": "hus", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -66,6 +69,7 @@ "ok_max_mean_abs": "" }, "pr": { + "frequency": "6hr", "modeling_realm": "atmos", "standard_name": "precipitation_flux", "units": "kg m-2 s-1", @@ -75,7 +79,7 @@ "comment": "includes both liquid and solid phases", "dimensions": "longitude latitude time", "out_name": "pr", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -83,16 +87,17 @@ "ok_max_mean_abs": "" }, "prhmax": { + "frequency": "6hr", "modeling_realm": "atmos", "standard_name": "precipitation_flux", "units": "kg m-2 s-1", "cell_methods": "area: mean time: mean within hours time: maximum over hours", "cell_measures": "area: areacella", "long_name": "Maximum Hourly Precipitation Rate", - "comment": "", + "comment": "In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions": "longitude latitude time", "out_name": "prhmax", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -100,8 +105,9 @@ "ok_max_mean_abs": "" }, "psl": { + "frequency": "6hr", "modeling_realm": "atmos", - "standard_name": "air_pressure_at_sea_level", + "standard_name": "air_pressure_at_mean_sea_level", "units": "Pa", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", @@ -117,16 +123,17 @@ "ok_max_mean_abs": "" }, "rv850": { + "frequency": "6hr", "modeling_realm": "atmos", "standard_name": "atmosphere_relative_vorticity", "units": "s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Relative Vorticity at 850 hPa", - "comment": "", + "long_name": "Relative Vorticity at 850hPa", + "comment": "Relative vorticity is the upward component of the vorticity vector i.e. the component which arises from horizontal velocity.", "dimensions": "longitude latitude time p850", "out_name": "rv850", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -134,6 +141,7 @@ "ok_max_mean_abs": "" }, "sfcWind": { + "frequency": "6hr", "modeling_realm": "atmos", "standard_name": "wind_speed", "units": "m s-1", @@ -151,16 +159,17 @@ "ok_max_mean_abs": "" }, "tas": { + "frequency": "6hr", "modeling_realm": "atmos", "standard_name": "air_temperature", "units": "K", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Surface Air Temperature", + "long_name": "Near-Surface Air Temperature", "comment": "near-surface (usually, 2 meter) air temperature", "dimensions": "longitude latitude time height2m", "out_name": "tas", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -168,7 +177,8 @@ "ok_max_mean_abs": "" }, "ua100m": { - "modeling_realm": "", + "frequency": "6hr", + "modeling_realm": "atmos", "standard_name": "eastward_wind", "units": "m s-1", "cell_methods": "area: time: mean", @@ -177,41 +187,7 @@ "comment": "Zonal wind at 100m height", "dimensions": "longitude latitude time height100m", "out_name": "ua100m", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "ua200": { - "modeling_realm": "atmos", - "standard_name": "eastward_wind", - "units": "m s-1", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "Eastward Wind at 200hPa", - "comment": "Zonal wind (positive eastwards) at 200hPa", - "dimensions": "longitude latitude time p200", - "out_name": "ua200", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "ua850": { - "modeling_realm": "atmos", - "standard_name": "eastward_wind", - "units": "m s-1", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "Eastward Wind at 850 hPa", - "comment": "Zonal wind on the 850 hPa surface", - "dimensions": "longitude latitude time p850", - "out_name": "ua850", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -219,6 +195,7 @@ "ok_max_mean_abs": "" }, "uas": { + "frequency": "6hr", "modeling_realm": "atmos", "standard_name": "eastward_wind", "units": "m s-1", @@ -228,7 +205,7 @@ "comment": "Eastward component of the near-surface (usually, 10 meters) wind", "dimensions": "longitude latitude time height10m", "out_name": "uas", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -236,7 +213,8 @@ "ok_max_mean_abs": "" }, "va100m": { - "modeling_realm": "", + "frequency": "6hr", + "modeling_realm": "atmos", "standard_name": "northward_wind", "units": "m s-1", "cell_methods": "area: time: mean", @@ -245,41 +223,25 @@ "comment": "Meridional wind at 100m above the surface.", "dimensions": "longitude latitude time height100m", "out_name": "va100m", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "va200": { - "modeling_realm": "atmos", - "standard_name": "northward_wind", - "units": "m s-1", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "Northward Wind", - "comment": "Northward component of the wind", - "dimensions": "longitude latitude time p200", - "out_name": "va200", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, - "va850": { + "vas": { + "frequency": "6hr", "modeling_realm": "atmos", "standard_name": "northward_wind", "units": "m s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Northward Wind", - "comment": "Northward component of the wind at 850hPa", - "dimensions": "longitude latitude time p850", - "out_name": "va850", - "type": "", + "long_name": "Northward Near-Surface Wind", + "comment": "Northward component of the near surface wind", + "dimensions": "longitude latitude time height10m", + "out_name": "vas", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -287,12 +249,13 @@ "ok_max_mean_abs": "" }, "wap4": { + "frequency": "6hr", "modeling_realm": "atmos", "standard_name": "lagrangian_tendency_of_air_pressure", "units": "Pa s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "omega (=dp/dt)", + "long_name": "Omega (=dp/dt)", "comment": "Omega (vertical velocity in pressure coordinates, positive downwards)", "dimensions": "longitude latitude plev4 time", "out_name": "wap", @@ -304,7 +267,8 @@ "ok_max_mean_abs": "" }, "wsgmax100m": { - "modeling_realm": "", + "frequency": "6hr", + "modeling_realm": "atmos", "standard_name": "wind_speed_of_gust", "units": "m s-1", "cell_methods": "area: mean time: maximum", @@ -313,7 +277,7 @@ "comment": "Wind speed gust maximum at 100m above surface", "dimensions": "longitude latitude time height100m", "out_name": "wsgmax100m", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -321,7 +285,8 @@ "ok_max_mean_abs": "" }, "wsgmax10m": { - "modeling_realm": "", + "frequency": "6hr", + "modeling_realm": "atmos", "standard_name": "wind_speed_of_gust", "units": "m s-1", "cell_methods": "area: mean time: maximum", @@ -330,7 +295,7 @@ "comment": "Wind speed gust maximum at 10m above surface", "dimensions": "longitude latitude time height10m", "out_name": "wsgmax10m", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -338,16 +303,17 @@ "ok_max_mean_abs": "" }, "zg1000": { + "frequency": "6hr", "modeling_realm": "atmos", "standard_name": "geopotential_height", "units": "m", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Geopotential Height at 1000 hPa", + "long_name": "Geopotential Height at 1000hPa", "comment": "Geopotential height on the 1000 hPa surface", "dimensions": "longitude latitude time p1000", "out_name": "zg1000", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_6hrPlevPt.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_6hrPlevPt.json index fae0c042d5..dad4b9fa9c 100644 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_6hrPlevPt.json +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_6hrPlevPt.json @@ -1,47 +1,31 @@ { "Header": { - "data_specs_version": "01.00.10", + "data_specs_version": "01.00.30", + "cmor_version": "3.4", "table_id": "Table 6hrPlevPt", "realm": "atmos", - "frequency": "6hr", - "cmor_version": "3.2", - "table_date": "10 May 2017", + "table_date": "11 March 2019", "missing_value": "1e20", + "int_missing_value": "-999", "product": "model-output", - "approx_interval": "", + "approx_interval": "0.250000", "generic_levels": "", "mip_era": "CMIP6", - "Conventions": "CF-1.7 CMIP-6.0" + "Conventions": "CF-1.7 CMIP-6.2" }, "variable_entry": { - "albsrfc": { - "modeling_realm": "aerosol", - "standard_name": "surface_albedo", - "units": "1.0", - "cell_methods": "area: mean time: point", - "cell_measures": "area: areacella", - "long_name": "surface albedo", - "comment": "", - "dimensions": "longitude latitude time1", - "out_name": "albsrfc", - "type": "float", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, "cldicemxrat27": { + "frequency": "6hrPt", "modeling_realm": "atmos", "standard_name": "cloud_ice_mixing_ratio", - "units": "1.0", + "units": "1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", "long_name": "Cloud Ice Mixing Ratio", "comment": "Cloud ice mixing ratio", "dimensions": "longitude latitude plev27 time1", "out_name": "cldicemxrat", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -49,16 +33,17 @@ "ok_max_mean_abs": "" }, "cldwatmxrat27": { + "frequency": "6hrPt", "modeling_realm": "atmos", "standard_name": "cloud_liquid_water_mixing_ratio", - "units": "1.0", + "units": "1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", "long_name": "Cloud Water Mixing Ratio", "comment": "Cloud water mixing ratio", "dimensions": "longitude latitude plev27 time1", "out_name": "cldwatmxrat", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -66,9 +51,10 @@ "ok_max_mean_abs": "" }, "dtauc": { + "frequency": "6hrPt", "modeling_realm": "atmos", "standard_name": "atmosphere_optical_thickness_due_to_convective_cloud", - "units": "1.0", + "units": "1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", "long_name": "Convective Cloud Optical Depth", @@ -83,9 +69,10 @@ "ok_max_mean_abs": "" }, "dtaus": { + "frequency": "6hrPt", "modeling_realm": "atmos", "standard_name": "atmosphere_optical_thickness_due_to_stratiform_cloud", - "units": "1.0", + "units": "1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", "long_name": "Stratiform Cloud Optical Depth", @@ -100,16 +87,17 @@ "ok_max_mean_abs": "" }, "grplmxrat27": { + "frequency": "6hrPt", "modeling_realm": "atmos", "standard_name": "mass_fraction_of_graupel_in_air", - "units": "1.0", + "units": "1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", "long_name": "Graupel Mixing Ratio", "comment": "Graupel mixing ratio", "dimensions": "longitude latitude plev27 time1", "out_name": "grplmxrat", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -117,16 +105,17 @@ "ok_max_mean_abs": "" }, "hus27": { + "frequency": "6hrPt", "modeling_realm": "atmos", "standard_name": "specific_humidity", - "units": "1.0", + "units": "1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", "long_name": "Specific Humidity", - "comment": "", + "comment": "Specific humidity is the mass fraction of water vapor in (moist) air.", "dimensions": "longitude latitude plev27 time1", "out_name": "hus", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -134,16 +123,17 @@ "ok_max_mean_abs": "" }, "hus7h": { + "frequency": "6hrPt", "modeling_realm": "atmos", "standard_name": "specific_humidity", - "units": "1.0", + "units": "1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", "long_name": "Specific Humidity", - "comment": "", + "comment": "Specific humidity is the mass fraction of water vapor in (moist) air.", "dimensions": "longitude latitude plev7h time1", "out_name": "hus", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -151,9 +141,10 @@ "ok_max_mean_abs": "" }, "huss": { + "frequency": "6hrPt", "modeling_realm": "atmos", "standard_name": "specific_humidity", - "units": "1.0", + "units": "1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", "long_name": "Near-Surface Specific Humidity", @@ -168,8 +159,9 @@ "ok_max_mean_abs": "" }, "lwsffluxaero": { + "frequency": "6hrPt", "modeling_realm": "atmos", - "standard_name": "longwave__flux__due_to_volcanic_aerosols_at_the_surface", + "standard_name": "surface_downwelling_longwave_flux_in_air_due_to_volcanic_ambient_aerosol_particles", "units": "W m-2", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", @@ -177,7 +169,7 @@ "comment": "downwelling longwave flux due to volcanic aerosols at the surface to be diagnosed through double radiation call", "dimensions": "longitude latitude time1", "out_name": "lwsffluxaero", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -185,32 +177,34 @@ "ok_max_mean_abs": "" }, "lwtoafluxaerocs": { + "frequency": "6hrPt", "modeling_realm": "atmos", - "standard_name": "longwave_flux_due_to_volcanic_aerosols_at_TOA_under_clear_sky", + "standard_name": "toa_outgoing_longwave_flux_due_to_volcanic_ambient_aerosol_particles_assuming_clear_sky", "units": "W m-2", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "Longwave flux due to volcanic aerosols at TOA under clear sky", + "long_name": "TOA Outgoing Clear-Sky Longwave Flux Due to Volcanic Aerosols", "comment": "downwelling longwave flux due to volcanic aerosols at TOA under clear sky to be diagnosed through double radiation call", "dimensions": "longitude latitude time1", "out_name": "lwtoafluxaerocs", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, - "mrlsl": { + "mrsol": { + "frequency": "6hrPt", "modeling_realm": "land", - "standard_name": "moisture_content_of_soil_layer", + "standard_name": "mass_content_of_water_in_soil_layer", "units": "kg m-2", - "cell_methods": "area: mean where land time: point", + "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "Water Content of Soil Layer", - "comment": "The mass of water in all phases, including ice, in soil layers. Report as missing for grid cells with no land.", - "dimensions": "longitude latitude time1 sdepth1", - "out_name": "mrlsl", + "long_name": "Total Water Content of Soil Layer", + "comment": "in each soil layer, the mass of water in all phases, including ice. Reported as 'missing' for grid cells occupied entirely by 'sea'", + "dimensions": "longitude latitude sdepth time1", + "out_name": "mrsol", "type": "real", "positive": "", "valid_min": "", @@ -219,8 +213,9 @@ "ok_max_mean_abs": "" }, "mrsos": { + "frequency": "6hrPt", "modeling_realm": "land", - "standard_name": "moisture_content_of_soil_layer", + "standard_name": "mass_content_of_water_in_soil_layer", "units": "kg m-2", "cell_methods": "area: mean where land time: point", "cell_measures": "area: areacella", @@ -235,26 +230,10 @@ "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, - "pfull27": { - "modeling_realm": "atmos", - "standard_name": "air_pressure", - "units": "Pa", - "cell_methods": "area: mean time: point", - "cell_measures": "area: areacella", - "long_name": "Pressure on Model Levels", - "comment": "Air pressure on model levels", - "dimensions": "longitude latitude plev27 time1", - "out_name": "pfull", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, "psl": { + "frequency": "6hrPt", "modeling_realm": "atmos", - "standard_name": "air_pressure_at_sea_level", + "standard_name": "air_pressure_at_mean_sea_level", "units": "Pa", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", @@ -270,16 +249,17 @@ "ok_max_mean_abs": "" }, "rainmxrat27": { + "frequency": "6hrPt", "modeling_realm": "atmos", "standard_name": "mass_fraction_of_rain_in_air", - "units": "1.0", + "units": "1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "rain_mixing_ratio", + "long_name": "Mass Fraction of Rain in Air", "comment": "Rain mixing ratio", "dimensions": "longitude latitude plev27 time1", "out_name": "rainmxrat", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -287,16 +267,17 @@ "ok_max_mean_abs": "" }, "rv850": { + "frequency": "6hrPt", "modeling_realm": "atmos", "standard_name": "atmosphere_relative_vorticity", "units": "s-1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "Relative Vorticity at 850 hPa", - "comment": "", + "long_name": "Relative Vorticity at 850hPa", + "comment": "Relative vorticity is the upward component of the vorticity vector i.e. the component which arises from horizontal velocity.", "dimensions": "longitude latitude time1 p850", "out_name": "rv850", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -304,6 +285,7 @@ "ok_max_mean_abs": "" }, "sfcWind": { + "frequency": "6hrPt", "modeling_realm": "atmos", "standard_name": "wind_speed", "units": "m s-1", @@ -321,16 +303,17 @@ "ok_max_mean_abs": "" }, "snowmxrat27": { + "frequency": "6hrPt", "modeling_realm": "atmos", "standard_name": "mass_fraction_of_snow_in_air", - "units": "1.0", + "units": "1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "snow_mixing_ratio", + "long_name": "Mass Fraction of Snow in Air", "comment": "Snow mixing ratio", "dimensions": "longitude latitude plev27 time1", "out_name": "snowmxrat", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -338,10 +321,11 @@ "ok_max_mean_abs": "" }, "snw": { + "frequency": "6hrPt", "modeling_realm": "landIce land", "standard_name": "surface_snow_amount", "units": "kg m-2", - "cell_methods": "area: mean time: point", + "cell_methods": "area: mean where land time: point", "cell_measures": "area: areacella", "long_name": "Surface Snow Amount", "comment": "The mass of surface snow on the land portion of the grid cell divided by the land area in the grid cell; reported as missing where the land fraction is 0; excludes snow on vegetation canopy or on sea ice.", @@ -355,16 +339,17 @@ "ok_max_mean_abs": "" }, "swsffluxaero": { + "frequency": "6hrPt", "modeling_realm": "atmos", - "standard_name": "shortwave__flux_due_to_volcanic_aerosols_at__the_surface", + "standard_name": "surface_downwelling_shortwave_flux_in_air_due_to_volcanic_ambient_aerosol_particles", "units": "W m-2", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "Shortwave heating rate due to volcanic aerosols", - "comment": "shortwave heating rate due to volcanic aerosols to be diagnosed through double radiation call, zonal average values required", + "long_name": "Shortwave Heating Rate Due to Volcanic Aerosols", + "comment": "Shortwave heating rate due to volcanic aerosols to be diagnosed through double radiation call", "dimensions": "longitude latitude time1", "out_name": "swsffluxaero", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -372,16 +357,17 @@ "ok_max_mean_abs": "" }, "swtoafluxaerocs": { + "frequency": "6hrPt", "modeling_realm": "atmos", - "standard_name": "shortwave_flux_due_to_volcanic_aerosols_at_TOA_under_clear_sky", + "standard_name": "toa_outgoing_shortwave_flux_due_to_volcanic_ambient_aerosol_particles_assuming_clear_sky", "units": "W m-2", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "Shortwave flux due to volcanic aerosols at TOA under clear sky", - "comment": "downwelling shortwave flux due to volcanic aerosols at TOA under clear sky to be diagnosed through double radiation call", + "long_name": "TOA Outgoing Clear-Sky Shortwave Flux Due to Volcanic Aerosols", + "comment": "Downwelling shortwave flux due to volcanic aerosols at TOA under clear sky to be diagnosed through double radiation call", "dimensions": "longitude latitude time1", "out_name": "swtoafluxaerocs", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -389,6 +375,7 @@ "ok_max_mean_abs": "" }, "ta": { + "frequency": "6hrPt", "modeling_realm": "atmos", "standard_name": "air_temperature", "units": "K", @@ -406,6 +393,7 @@ "ok_max_mean_abs": "" }, "ta27": { + "frequency": "6hrPt", "modeling_realm": "atmos", "standard_name": "air_temperature", "units": "K", @@ -415,7 +403,7 @@ "comment": "Air Temperature", "dimensions": "longitude latitude plev27 time1", "out_name": "ta", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -423,6 +411,7 @@ "ok_max_mean_abs": "" }, "ta7h": { + "frequency": "6hrPt", "modeling_realm": "atmos", "standard_name": "air_temperature", "units": "K", @@ -432,7 +421,7 @@ "comment": "Air Temperature", "dimensions": "longitude latitude plev7h time1", "out_name": "ta", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -440,16 +429,17 @@ "ok_max_mean_abs": "" }, "tas": { + "frequency": "6hrPt", "modeling_realm": "atmos", "standard_name": "air_temperature", "units": "K", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "Surface Air Temperature", + "long_name": "Near-Surface Air Temperature", "comment": "near-surface (usually, 2 meter) air temperature", "dimensions": "longitude latitude time1 height2m", "out_name": "tas", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -457,6 +447,7 @@ "ok_max_mean_abs": "" }, "ts": { + "frequency": "6hrPt", "modeling_realm": "atmos", "standard_name": "surface_temperature", "units": "K", @@ -474,13 +465,14 @@ "ok_max_mean_abs": "" }, "tsl": { + "frequency": "6hrPt", "modeling_realm": "land", "standard_name": "soil_temperature", "units": "K", "cell_methods": "area: mean where land time: point", "cell_measures": "area: areacella", "long_name": "Temperature of Soil", - "comment": "Temperature of each soil layer. Reported as missing for grid cells with no land.", + "comment": "Temperature of soil. Reported as missing for grid cells with no land.", "dimensions": "longitude latitude time1 sdepth1", "out_name": "tsl", "type": "real", @@ -491,13 +483,14 @@ "ok_max_mean_abs": "" }, "ua": { + "frequency": "6hrPt", "modeling_realm": "atmos", "standard_name": "eastward_wind", "units": "m s-1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", "long_name": "Eastward Wind", - "comment": "", + "comment": "Zonal wind (positive in a eastward direction).", "dimensions": "longitude latitude plev3 time1", "out_name": "ua", "type": "real", @@ -508,16 +501,17 @@ "ok_max_mean_abs": "" }, "ua7h": { + "frequency": "6hrPt", "modeling_realm": "atmos", "standard_name": "eastward_wind", "units": "m s-1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", "long_name": "Eastward Wind", - "comment": "", + "comment": "Zonal wind (positive in a eastward direction).", "dimensions": "longitude latitude plev7h time1", "out_name": "ua", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -525,6 +519,7 @@ "ok_max_mean_abs": "" }, "uas": { + "frequency": "6hrPt", "modeling_realm": "atmos", "standard_name": "eastward_wind", "units": "m s-1", @@ -534,7 +529,7 @@ "comment": "Eastward component of the near-surface (usually, 10 meters) wind", "dimensions": "longitude latitude time1 height10m", "out_name": "uas", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -542,13 +537,14 @@ "ok_max_mean_abs": "" }, "va": { + "frequency": "6hrPt", "modeling_realm": "atmos", "standard_name": "northward_wind", "units": "m s-1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", "long_name": "Northward Wind", - "comment": "", + "comment": "Meridional wind (positive in a northward direction).", "dimensions": "longitude latitude plev3 time1", "out_name": "va", "type": "real", @@ -559,16 +555,17 @@ "ok_max_mean_abs": "" }, "va7h": { + "frequency": "6hrPt", "modeling_realm": "atmos", "standard_name": "northward_wind", "units": "m s-1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", "long_name": "Northward Wind", - "comment": "", + "comment": "Meridional wind (positive in a northward direction).", "dimensions": "longitude latitude plev7h time1", "out_name": "va", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -576,6 +573,7 @@ "ok_max_mean_abs": "" }, "vas": { + "frequency": "6hrPt", "modeling_realm": "atmos", "standard_name": "northward_wind", "units": "m s-1", @@ -593,16 +591,17 @@ "ok_max_mean_abs": "" }, "vortmean": { + "frequency": "6hrPt", "modeling_realm": "atmos", "standard_name": "atmosphere_relative_vorticity", "units": "s-1", - "cell_methods": "time: point", + "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "atmosphere_relative_vorticity", + "long_name": "Relative Vorticity", "comment": "Mean vorticity over 850,700,600 hPa", "dimensions": "longitude latitude time1 pl700", "out_name": "vortmean", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -610,16 +609,17 @@ "ok_max_mean_abs": "" }, "wbptemp7h": { + "frequency": "6hrPt", "modeling_realm": "atmos", "standard_name": "wet_bulb_potential_temperature", "units": "K", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "wet_bulb_potential_temperature", + "long_name": "Wet Bulb Potential Temperature", "comment": "Wet bulb potential temperature", "dimensions": "longitude latitude plev7h time1", "out_name": "wbptemp", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -627,16 +627,17 @@ "ok_max_mean_abs": "" }, "zg27": { + "frequency": "6hrPt", "modeling_realm": "atmos", "standard_name": "geopotential_height", "units": "m", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", "long_name": "Geopotential Height", - "comment": "", + "comment": "Geopotential is the sum of the specific gravitational potential energy relative to the geoid and the specific centripetal potential energy. Geopotential height is the geopotential divided by the standard acceleration due to gravity. It is numerically similar to the altitude (or geometric height) and not to the quantity with standard name height, which is relative to the surface.", "dimensions": "longitude latitude plev27 time1", "out_name": "zg", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -644,16 +645,17 @@ "ok_max_mean_abs": "" }, "zg500": { + "frequency": "6hrPt", "modeling_realm": "aerosol", "standard_name": "geopotential_height", "units": "m", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "Geopotential Height at 500 hPa", + "long_name": "Geopotential Height at 500hPa", "comment": "geopotential height on the 500 hPa surface", "dimensions": "longitude latitude time1 p500", "out_name": "zg500", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -661,16 +663,17 @@ "ok_max_mean_abs": "" }, "zg7h": { + "frequency": "6hrPt", "modeling_realm": "atmos", "standard_name": "geopotential_height", "units": "m", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", "long_name": "Geopotential Height", - "comment": "", + "comment": "Geopotential is the sum of the specific gravitational potential energy relative to the geoid and the specific centripetal potential energy. Geopotential height is the geopotential divided by the standard acceleration due to gravity. It is numerically similar to the altitude (or geometric height) and not to the quantity with standard name height, which is relative to the surface.", "dimensions": "longitude latitude plev7h time1", "out_name": "zg", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_AERday.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_AERday.json index 99c62be838..41451f75c4 100644 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_AERday.json +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_AERday.json @@ -1,30 +1,31 @@ { "Header": { - "data_specs_version": "01.00.10", + "data_specs_version": "01.00.30", + "cmor_version": "3.4", "table_id": "Table AERday", "realm": "aerosol", - "frequency": "day", - "cmor_version": "3.2", - "table_date": "10 May 2017", + "table_date": "11 March 2019", "missing_value": "1e20", + "int_missing_value": "-999", "product": "model-output", - "approx_interval": "", + "approx_interval": "1.0", "generic_levels": "", "mip_era": "CMIP6", - "Conventions": "CF-1.7 CMIP-6.0" + "Conventions": "CF-1.7 CMIP-6.2" }, "variable_entry": { "cod": { + "frequency": "day", "modeling_realm": "aerosol", "standard_name": "atmosphere_optical_thickness_due_to_cloud", - "units": "1.0", + "units": "1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "cloud optical depth", - "comment": "", + "long_name": "Cloud Optical Depth", + "comment": "The optical thickness is the integral along the path of radiation of a volume scattering/absorption/attenuation coefficient. The radiative flux is reduced by a factor exp(-optical_thickness) on traversing the path. A coordinate variable of radiation_wavelength or radiation_frequency can be specified to indicate that the optical thickness applies at specific wavelengths or frequencies. The atmosphere optical thickness applies to radiation passing through the entire atmosphere. 'Cloud' means the component of extinction owing to the presence of liquid or ice water particles. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", "dimensions": "longitude latitude time", "out_name": "cod", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -32,16 +33,17 @@ "ok_max_mean_abs": "" }, "maxpblz": { + "frequency": "day", "modeling_realm": "aerosol", "standard_name": "atmosphere_boundary_layer_thickness", "units": "m", "cell_methods": "area: mean time: maximum", "cell_measures": "area: areacella", - "long_name": "maximum PBL height", + "long_name": "Maximum PBL Height", "comment": "maximum boundary layer height during the day (add cell_methods attribute: 'time: maximum')", "dimensions": "longitude latitude time", "out_name": "maxpblz", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -49,16 +51,17 @@ "ok_max_mean_abs": "" }, "minpblz": { + "frequency": "day", "modeling_realm": "aerosol", "standard_name": "atmosphere_boundary_layer_thickness", "units": "m", "cell_methods": "area: mean time: minimum", "cell_measures": "area: areacella", - "long_name": "minimum PBL height", + "long_name": "Minimum PBL Height", "comment": "minimum boundary layer height during the day (add cell_methods attribute: 'time: minimum')", "dimensions": "longitude latitude time", "out_name": "minpblz", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -66,16 +69,17 @@ "ok_max_mean_abs": "" }, "od550aer": { + "frequency": "day", "modeling_realm": "aerosol", "standard_name": "atmosphere_optical_thickness_due_to_ambient_aerosol_particles", - "units": "1.0", + "units": "1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "ambient aerosol optical thickness at 550 nm", - "comment": "AOD from the ambient aerosls (i.e., includes aerosol water). Does not include AOD from stratospheric aerosols if these are prescribed but includes other possible background aerosol types. Needs a comment attribute 'wavelength: 550 nm'", - "dimensions": "longitude latitude time", + "long_name": "Ambient Aerosol Optical Thickness at 550nm", + "comment": "AOD from the ambient aerosols (i.e., includes aerosol water). Does not include AOD from stratospheric aerosols if these are prescribed but includes other possible background aerosol types. Needs a comment attribute 'wavelength: 550nm'", + "dimensions": "longitude latitude time lambda550nm", "out_name": "od550aer", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -83,16 +87,17 @@ "ok_max_mean_abs": "" }, "sfo3max": { + "frequency": "day", "modeling_realm": "aerosol", "standard_name": "mole_fraction_of_ozone_in_air", "units": "mol mol-1", "cell_methods": "area: mean time: maximum", "cell_measures": "area: areacella", - "long_name": "daily maximum O3 volume mixing ratio in lowest model layer", - "comment": "", + "long_name": "Daily Maximum O3 Volume Mixing Ratio in Lowest Model Layer", + "comment": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", "dimensions": "longitude latitude time", "out_name": "sfo3max", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -100,16 +105,17 @@ "ok_max_mean_abs": "" }, "toz": { + "frequency": "day", "modeling_realm": "aerosol", "standard_name": "equivalent_thickness_at_stp_of_atmosphere_ozone_content", "units": "m", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Total Column Ozone", - "comment": "total ozone column in DU", + "comment": "Total ozone column calculated at 0 degrees C and 1 bar, such that 1m = 1e5 DU.", "dimensions": "longitude latitude time", "out_name": "toz", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -117,16 +123,17 @@ "ok_max_mean_abs": "" }, "ua10": { + "frequency": "day", "modeling_realm": "aerosol", "standard_name": "eastward_wind", "units": "m s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Eastward Wind at 10 hPa", + "long_name": "Eastward Wind at 10hPa", "comment": "Zonal wind on the 10 hPa surface", "dimensions": "longitude latitude time p10", "out_name": "ua10", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -134,16 +141,17 @@ "ok_max_mean_abs": "" }, "zg10": { + "frequency": "day", "modeling_realm": "aerosol", "standard_name": "geopotential_height", "units": "m", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Geopotential Height at 10 hPa", - "comment": "Geopotential height on the 10 hPa surface", + "long_name": "Geopotential Height at 10hPa", + "comment": "Geopotential height on the 10hPa surface", "dimensions": "longitude latitude time p10", "out_name": "zg10", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -151,16 +159,17 @@ "ok_max_mean_abs": "" }, "zg100": { + "frequency": "day", "modeling_realm": "aerosol", "standard_name": "geopotential_height", "units": "m", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Geopotential Height at 100 hPa", + "long_name": "Geopotential Height at 100hPa", "comment": "Geopotential height on the 100 hPa surface", "dimensions": "longitude latitude time p100", "out_name": "zg100", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -168,16 +177,17 @@ "ok_max_mean_abs": "" }, "zg1000": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "geopotential_height", "units": "m", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Geopotential Height at 1000 hPa", + "long_name": "Geopotential Height at 1000hPa", "comment": "Geopotential height on the 1000 hPa surface", "dimensions": "longitude latitude time p1000", "out_name": "zg1000", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -185,16 +195,17 @@ "ok_max_mean_abs": "" }, "zg500": { + "frequency": "day", "modeling_realm": "aerosol", "standard_name": "geopotential_height", "units": "m", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Geopotential Height at 500 hPa", + "long_name": "Geopotential Height at 500hPa", "comment": "geopotential height on the 500 hPa surface", "dimensions": "longitude latitude time p500", "out_name": "zg500", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_AERhr.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_AERhr.json index e8f32a625e..0eccc1ec5d 100644 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_AERhr.json +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_AERhr.json @@ -1,30 +1,31 @@ { "Header": { - "data_specs_version": "01.00.10", + "data_specs_version": "01.00.30", + "cmor_version": "3.4", "table_id": "Table AERhr", "realm": "aerosol", - "frequency": "hr", - "cmor_version": "3.2", - "table_date": "10 May 2017", + "table_date": "11 March 2019", "missing_value": "1e20", + "int_missing_value": "-999", "product": "model-output", - "approx_interval": "", - "generic_levels": "", + "approx_interval": "0.041667", + "generic_levels": "alevel alevhalf", "mip_era": "CMIP6", - "Conventions": "CF-1.7 CMIP-6.0" + "Conventions": "CF-1.7 CMIP-6.2" }, "variable_entry": { "ps": { + "frequency": "1hr", "modeling_realm": "atmos", "standard_name": "surface_air_pressure", "units": "Pa", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Surface pressure", + "long_name": "Surface Air Pressure", "comment": "surface pressure (not mean sea-level pressure), 2-D field to calculate the 3-D pressure field from hybrid coordinates", "dimensions": "longitude latitude time", "out_name": "ps", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -32,16 +33,17 @@ "ok_max_mean_abs": "" }, "sfno2": { + "frequency": "1hr", "modeling_realm": "aerosol", "standard_name": "mole_fraction_of_nitrogen_dioxide_in_air", "units": "mol mol-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "NO2 volume mixing ratio in lowest model layer", - "comment": "", + "long_name": "NO2 Volume Mixing Ratio in Lowest Model Layer", + "comment": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", "dimensions": "longitude latitude time", "out_name": "sfno2", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -49,16 +51,17 @@ "ok_max_mean_abs": "" }, "sfo3": { + "frequency": "1hr", "modeling_realm": "aerosol", "standard_name": "mole_fraction_of_ozone_in_air", "units": "mol mol-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "O3 volume mixing ratio in lowest model layer", - "comment": "", + "long_name": "O3 Volume Mixing Ratio in Lowest Model Layer", + "comment": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", "dimensions": "longitude latitude time", "out_name": "sfo3", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -66,16 +69,17 @@ "ok_max_mean_abs": "" }, "sfpm25": { + "frequency": "1hr", "modeling_realm": "aerosol", "standard_name": "mass_fraction_of_pm2p5_ambient_aerosol_particles_in_air", "units": "kg kg-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "PM2.5 mass mixing ratio in lowest model layer", - "comment": "", + "long_name": "PM2.5 Mass Mixing Ratio in Lowest Model Layer", + "comment": "Mass fraction of atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers. To specify the relative humidity and temperature at which the particle size applies, provide scalar coordinate variables with the standard names of 'relative_humidity' and 'air_temperature'.", "dimensions": "longitude latitude time", "out_name": "sfpm25", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -83,16 +87,17 @@ "ok_max_mean_abs": "" }, "tas": { + "frequency": "1hr", "modeling_realm": "atmos", "standard_name": "air_temperature", "units": "K", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Surface Temperature", + "long_name": "Near-Surface Air Temperature", "comment": "near-surface (usually, 2 meter) air temperature", "dimensions": "longitude latitude time height2m", "out_name": "tas", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_AERmon.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_AERmon.json index 5cd1dfb501..ab9c7a547b 100644 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_AERmon.json +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_AERmon.json @@ -1,30 +1,31 @@ { "Header": { - "data_specs_version": "01.00.10", + "data_specs_version": "01.00.30", + "cmor_version": "3.4", "table_id": "Table AERmon", "realm": "aerosol", - "frequency": "mon", - "cmor_version": "3.2", - "table_date": "10 May 2017", + "table_date": "11 March 2019", "missing_value": "1e20", + "int_missing_value": "-999", "product": "model-output", "approx_interval": "30.00000", - "generic_levels": "alevel", + "generic_levels": "alevel alevhalf", "mip_era": "CMIP6", - "Conventions": "CF-1.7 CMIP-6.0" + "Conventions": "CF-1.7 CMIP-6.2" }, "variable_entry": { "abs550aer": { + "frequency": "mon", "modeling_realm": "aerosol", - "standard_name": "atmosphere_absorption_optical_thickness_due_to_ambient_aerosol", - "units": "1.0", + "standard_name": "atmosphere_absorption_optical_thickness_due_to_ambient_aerosol_particles", + "units": "1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "ambient aerosol absorption optical thickness at 550 nm", - "comment": "", - "dimensions": "longitude latitude time", + "long_name": "Ambient Aerosol Absorption Optical Thickness at 550nm", + "comment": "Optical thickness of atmospheric aerosols at wavelength 550 nanometers.", + "dimensions": "longitude latitude time lambda550nm", "out_name": "abs550aer", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -32,50 +33,17 @@ "ok_max_mean_abs": "" }, "airmass": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "atmosphere_mass_of_air_per_unit_area", "units": "kg m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Vertically integrated mass content of air in layer", - "comment": "", + "long_name": "Vertically Integrated Mass Content of Air in Layer", + "comment": "The mass of air in an atmospheric layer.", "dimensions": "longitude latitude alevel time", "out_name": "airmass", - "type": "float", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "albs": { - "modeling_realm": "aerosol", - "standard_name": "surface_albedo", - "units": "1.0", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "planetary albedo", - "comment": "Grid cell average albedo for all wavelengths.", - "dimensions": "longitude latitude time", - "out_name": "albs", - "type": "float", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "albsrfc": { - "modeling_realm": "aerosol", - "standard_name": "surface_albedo", - "units": "1.0", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "surface albedo", - "comment": "", - "dimensions": "longitude latitude time", - "out_name": "albsrfc", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -83,16 +51,17 @@ "ok_max_mean_abs": "" }, "aoanh": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "tracer_lifetime", "units": "yr", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Tracer age of air Northern Hemisphere", + "long_name": "Northern Hemisphere Tracer Lifetime", "comment": "Fixed surface layer mixing ratio over 30o-50oN (0 ppbv), uniform fixed source (at all levels) everywhere else (source is unspecified but must be constant in space and time and documented). Note that the source could be 1yr/yr, so the tracer concentration provides mean age in years. For method using linearly increasing tracer include a method attribute: 'linearly increasing tracer'For method using uniform source (1yr/yr) include a method attribute: 'uniform source'", "dimensions": "longitude latitude alevel time", "out_name": "aoanh", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -100,6 +69,7 @@ "ok_max_mean_abs": "" }, "bldep": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "atmosphere_boundary_layer_thickness", "units": "m", @@ -109,7 +79,7 @@ "comment": "Boundary layer depth", "dimensions": "longitude latitude time", "out_name": "bldep", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -117,16 +87,17 @@ "ok_max_mean_abs": "" }, "c2h2": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "mole_fraction_of_ethyne_in_air", "units": "mol mol-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "C2H2 volume mixing ratio", - "comment": "", + "long_name": "C2H2 Volume Mixing Ratio", + "comment": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", "dimensions": "longitude latitude alevel time", "out_name": "c2h2", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -134,16 +105,17 @@ "ok_max_mean_abs": "" }, "c2h6": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "mole_fraction_of_ethane_in_air", "units": "mol mol-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "C2H6 volume mixing ratio", - "comment": "", + "long_name": "C2H6 Volume Mixing Ratio", + "comment": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", "dimensions": "longitude latitude alevel time", "out_name": "c2h6", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -151,16 +123,17 @@ "ok_max_mean_abs": "" }, "c3h6": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "mole_fraction_of_propene_in_air", "units": "mol mol-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "C3H6 volume mixing ratio", - "comment": "", + "comment": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", "dimensions": "longitude latitude alevel time", "out_name": "c3h6", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -168,16 +141,17 @@ "ok_max_mean_abs": "" }, "c3h8": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "mole_fraction_of_propane_in_air", "units": "mol mol-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "C3H8 volume mixing ratio", - "comment": "", + "comment": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", "dimensions": "longitude latitude alevel time", "out_name": "c3h8", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -185,16 +159,17 @@ "ok_max_mean_abs": "" }, "ccn": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "number_concentration_of_cloud_condensation_nuclei_at_stp_in_air", "units": "m-3", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "cloud condensation nuclei concentration at liquid cloud top", + "long_name": "Cloud Condensation Nuclei Concentration at Liquid Cloud Top", "comment": "proposed name: number_concentration_of_ambient_aerosol_in_air_at_liquid_water_cloud_top", "dimensions": "longitude latitude time", "out_name": "ccn", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -202,6 +177,7 @@ "ok_max_mean_abs": "" }, "cdnc": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "number_concentration_of_cloud_liquid_water_particles_in_air", "units": "m-3", @@ -211,7 +187,7 @@ "comment": "Cloud Droplet Number Concentration in liquid water clouds.", "dimensions": "longitude latitude alevel time", "out_name": "cdnc", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -219,16 +195,17 @@ "ok_max_mean_abs": "" }, "ch3coch3": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "mole_fraction_of_acetone_in_air", "units": "mol mol-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "CH3COCH3 volume mixing ratio", - "comment": "", + "comment": "Mole fraction is used in the construction 'mole_fraction_of_X_in_Y', where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. Acetone is an organic molecule with the chemical formula CH3CH3CO. The IUPAC name for acetone is propan-2-one. Acetone is a member of the group of organic compounds known as ketones. There are standard names for the ketone group as well as for some of the individual species.", "dimensions": "longitude latitude alevel time", "out_name": "ch3coch3", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -236,16 +213,17 @@ "ok_max_mean_abs": "" }, "ch4": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "mole_fraction_of_methane_in_air", "units": "mol mol-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "CH4 volume mixing ratio", - "comment": "", + "long_name": "Mole Fraction of CH4", + "comment": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", "dimensions": "longitude latitude alevel time", "out_name": "ch4", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -253,16 +231,17 @@ "ok_max_mean_abs": "" }, "cheaqpso4": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_aqueous_phase_net_chemical_production", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Aqueous-phase production rate of SO4", + "long_name": "Aqueous-Phase Production Rate of SO4", "comment": "proposed name: tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_due_to_aqueous_phase_net_chemical_production", "dimensions": "longitude latitude alevel time", "out_name": "cheaqpso4", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -270,16 +249,17 @@ "ok_max_mean_abs": "" }, "chegpso4": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_gaseous_phase_net_chemical_production", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Gas-phase production rate of SO4", + "long_name": "Gas-Phase Production Rate of SO4", "comment": "proposed name: tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_due_to_gas_phase_net_chemical_production", "dimensions": "longitude latitude alevel time", "out_name": "chegpso4", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -287,16 +267,17 @@ "ok_max_mean_abs": "" }, "chepasoa": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "tendency_of_atmosphere_mass_content_of_secondary_particulate_organic_matter_dry_aerosol_particles_due_to_net_chemical_production", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "total net production of anthropogenic secondary organic aerosol", + "long_name": "Total Net Production of Anthropogenic Secondary Organic Aerosol", "comment": "anthropogenic part of chepsoa", "dimensions": "longitude latitude time", "out_name": "chepasoa", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -304,16 +285,17 @@ "ok_max_mean_abs": "" }, "chepsoa": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "tendency_of_atmosphere_mass_content_of_secondary_particulate_organic_matter_dry_aerosol_particles_due_to_net_chemical_production", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "chemical production of dry aerosol secondary organic matter", - "comment": "If model lumps SOA emissions with POA, then the sum of POA and SOA emissions is reported as OA emissions. ''mass'' refers to the mass of primary organic matter, not mass of organic carbon alone.", + "long_name": "Chemical Production of Dry Aerosol Secondary Organic Matter", + "comment": "If model lumps secondary organic aerosol (SOA) emissions with primary organic aerosol (POA), then the sum of POA and SOA emissions is reported as OA emissions. Here, mass refers to the mass of primary organic matter, not mass of organic carbon alone.", "dimensions": "longitude latitude time", "out_name": "chepsoa", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -321,16 +303,17 @@ "ok_max_mean_abs": "" }, "cltc": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "convective_cloud_area_fraction", "units": "%", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Convective Cloud Area Fraction", - "comment": "Convective cloud area fraction for the whole atmospheric column, as seen from the surface or the top of the atmosphere. Includes only convective cloud.", + "long_name": "Convective Cloud Cover Percentage", + "comment": "Convective cloud area fraction (reported as a percentage) for the whole atmospheric column, as seen from the surface or the top of the atmosphere. Includes only convective cloud.", "dimensions": "longitude latitude time", "out_name": "cltc", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -338,16 +321,17 @@ "ok_max_mean_abs": "" }, "co": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "mole_fraction_of_carbon_monoxide_in_air", "units": "mol mol-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "CO volume mixing ratio", - "comment": "", + "long_name": "CO Volume Mixing Ratio", + "comment": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", "dimensions": "longitude latitude alevel time", "out_name": "co", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -355,16 +339,17 @@ "ok_max_mean_abs": "" }, "co2": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "mole_fraction_of_carbon_dioxide_in_air", "units": "mol mol-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "CO2 volume mixing ratio", - "comment": "", + "long_name": "Mole Fraction of CO2", + "comment": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", "dimensions": "longitude latitude alevel time", "out_name": "co2", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -372,16 +357,17 @@ "ok_max_mean_abs": "" }, "cod": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "atmosphere_optical_thickness_due_to_cloud", - "units": "1.0", + "units": "1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "cloud optical depth", - "comment": "", + "long_name": "Cloud Optical Depth", + "comment": "The optical thickness is the integral along the path of radiation of a volume scattering/absorption/attenuation coefficient. The radiative flux is reduced by a factor exp(-optical_thickness) on traversing the path. A coordinate variable of radiation_wavelength or radiation_frequency can be specified to indicate that the optical thickness applies at specific wavelengths or frequencies. The atmosphere optical thickness applies to radiation passing through the entire atmosphere. 'Cloud' means the component of extinction owing to the presence of liquid or ice water particles. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", "dimensions": "longitude latitude time", "out_name": "cod", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -389,16 +375,17 @@ "ok_max_mean_abs": "" }, "dms": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "mole_fraction_of_dimethyl_sulfide_in_air", "units": "mol mol-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "DMS volume mixing ratio", - "comment": "", + "long_name": "Dimethyl Sulphide (DMS) Mole Fraction", + "comment": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", "dimensions": "longitude latitude alevel time", "out_name": "dms", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -406,16 +393,17 @@ "ok_max_mean_abs": "" }, "drybc": { + "frequency": "mon", "modeling_realm": "aerosol", - "standard_name": "tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_dry_deposition", + "standard_name": "minus_tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_dry_deposition", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "dry deposition rate of black carbon aerosol mass", + "long_name": "Dry Deposition Rate of Black Carbon Aerosol Mass", "comment": "Dry deposition includes gravitational settling, impact scavenging, and turbulent deposition.", "dimensions": "longitude latitude time", "out_name": "drybc", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -423,16 +411,17 @@ "ok_max_mean_abs": "" }, "drydust": { + "frequency": "mon", "modeling_realm": "aerosol", - "standard_name": "tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_dry_deposition", + "standard_name": "minus_tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_dry_deposition", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "dry deposition rate of dust", + "long_name": "Dry Deposition Rate of Dust", "comment": "Dry deposition includes gravitational settling, impact scavenging, and turbulent deposition.", "dimensions": "longitude latitude time", "out_name": "drydust", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -440,16 +429,17 @@ "ok_max_mean_abs": "" }, "drynh3": { + "frequency": "mon", "modeling_realm": "aerosol", - "standard_name": "tendency_of_atmosphere_mass_content_of_ammonia_due_to_dry_deposition", + "standard_name": "minus_tendency_of_atmosphere_mass_content_of_ammonia_due_to_dry_deposition", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "dry deposition rate of nh3", + "long_name": "Dry Deposition Rate of NH3", "comment": "dry deposition includes gravitational settling, impact scavenging, and turbulent deposition", "dimensions": "longitude latitude time", "out_name": "drynh3", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -457,16 +447,17 @@ "ok_max_mean_abs": "" }, "drynh4": { + "frequency": "mon", "modeling_realm": "aerosol", - "standard_name": "tendency_of_atmosphere_mass_content_of_ammonium_dry_aerosol_particles_due_to_dry_deposition", + "standard_name": "minus_tendency_of_atmosphere_mass_content_of_ammonium_dry_aerosol_particles_due_to_dry_deposition", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "dry deposition rate of nh4", + "long_name": "Dry Deposition Rate of NH4", "comment": "dry deposition includes gravitational settling, impact scavenging, and turbulent deposition", "dimensions": "longitude latitude time", "out_name": "drynh4", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -474,16 +465,17 @@ "ok_max_mean_abs": "" }, "drynoy": { + "frequency": "mon", "modeling_realm": "aerosol", - "standard_name": "tendency_of_atmosphere_mass_content_of_noy_expressed_as_nitrogen_due_to_dry_deposition", + "standard_name": "minus_tendency_of_atmosphere_mass_content_of_noy_expressed_as_nitrogen_due_to_dry_deposition", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "dry deposition rate of noy", - "comment": "NOy is the sum of all simulated oxidized nitrogen species out of NO, NO2, HNO3, HNO4, NO3aerosol, NO3(radical), N2O5, PAN, other organic nitrates. Dry deposition includes gravitational settling, impact scavenging, and turbulent deposition.", + "long_name": "Dry Deposition Rate of NOy", + "comment": "NOy is the sum of all simulated oxidized nitrogen species out of NO, NO2, HNO3, HNO4, NO3 aerosol, NO3(radical), N2O5, PAN, other organic nitrates. Dry deposition includes gravitational settling, impact scavenging, and turbulent deposition.", "dimensions": "longitude latitude time", "out_name": "drynoy", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -491,16 +483,17 @@ "ok_max_mean_abs": "" }, "dryo3": { + "frequency": "mon", "modeling_realm": "aerosol", - "standard_name": "tendency_of_atmosphere_mass_content_of_ozone_due_to_dry_deposition", + "standard_name": "minus_tendency_of_atmosphere_mass_content_of_ozone_due_to_dry_deposition", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "dry deposition rate of o3", + "long_name": "Dry Deposition Rate of O3", "comment": "dry deposition includes gravitational settling, impact scavenging, and turbulent deposition.", "dimensions": "longitude latitude time", "out_name": "dryo3", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -508,16 +501,17 @@ "ok_max_mean_abs": "" }, "dryoa": { + "frequency": "mon", "modeling_realm": "aerosol", - "standard_name": "tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_dry_deposition", + "standard_name": "minus_tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_dry_deposition", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "dry deposition rate of dry aerosol total organic matter", - "comment": "Tendency of atmosphere mass content of organic dry aerosol due to dry deposition: This is the sum of dry deposition of POA and dry deposition of SOA (see next two entries). 'Mass' refers to the mass of organic matter, not mass of organic carbon alone. We recommend a scale factor of POM=1.4*OC, unless your model has more detailed info available. Was called dry_pom in old ACCMIP Excel table. Dry deposition includes gravitational settling, impact scavenging, and turbulent deposition.", + "long_name": "Dry Deposition Rate of Dry Aerosol Total Organic Matter", + "comment": "Tendency of atmosphere mass content of organic dry aerosol due to dry deposition: This is the sum of dry deposition of primary organic aerosol (POA) and dry deposition of secondary organic aerosol (SOA). Here, mass refers to the mass of organic matter, not mass of organic carbon alone. We recommend a scale factor of POM=1.4*OC, unless your model has more detailed info available. Was called dry_pom in old ACCMIP Excel table. Dry deposition includes gravitational settling, impact scavenging, and turbulent deposition.", "dimensions": "longitude latitude time", "out_name": "dryoa", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -525,16 +519,17 @@ "ok_max_mean_abs": "" }, "dryso2": { + "frequency": "mon", "modeling_realm": "aerosol", - "standard_name": "tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_dry_deposition", + "standard_name": "minus_tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_dry_deposition", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "dry deposition rate of so2", + "long_name": "Dry Deposition Rate of SO2", "comment": "dry deposition includes gravitational settling, impact scavenging, and turbulent deposition", "dimensions": "longitude latitude time", "out_name": "dryso2", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -542,16 +537,17 @@ "ok_max_mean_abs": "" }, "dryso4": { + "frequency": "mon", "modeling_realm": "aerosol", - "standard_name": "tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_dry_deposition", + "standard_name": "minus_tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_dry_deposition", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "dry deposition rate of so4", + "long_name": "Dry Deposition Rate of SO4", "comment": "dry deposition includes gravitational settling, impact scavenging, and turbulent deposition", "dimensions": "longitude latitude time", "out_name": "dryso4", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -559,16 +555,17 @@ "ok_max_mean_abs": "" }, "dryss": { + "frequency": "mon", "modeling_realm": "aerosol", - "standard_name": "tendency_of_atmosphere_mass_content_of_seasalt_dry_aerosol_particles_due_to_dry_deposition", + "standard_name": "minus_tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_dry_deposition", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "dry deposition rate of seasalt", + "long_name": "Dry Deposition Rate of Sea-Salt Aerosol", "comment": "Dry deposition includes gravitational settling, impact scavenging, and turbulent deposition.", "dimensions": "longitude latitude time", "out_name": "dryss", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -576,16 +573,17 @@ "ok_max_mean_abs": "" }, "emiaco": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "total emission rate of anthropogenic co", - "comment": "anthrophogenic emission of CO", + "long_name": "Total Emission Rate of Anthropogenic CO", + "comment": "Anthropogenic emission of CO.", "dimensions": "longitude latitude time", "out_name": "emiaco", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -593,16 +591,17 @@ "ok_max_mean_abs": "" }, "emianox": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_due_to_emission", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "anthropogenic emission rate of nox", + "long_name": "Total Emission Rate of Anthropogenic NOx", "comment": "Store flux as Nitrogen. Anthropogenic fraction. NOx=NO+NO2, Includes agricultural waste burning but no other biomass burning. Integrate 3D emission field vertically to 2d field.", "dimensions": "longitude latitude time", "out_name": "emianox", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -610,16 +609,17 @@ "ok_max_mean_abs": "" }, "emiaoa": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_net_chemical_production_and_emission", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "total emission of anthropogenic organic aerosol", + "long_name": "Total Emission Rate of Anthropogenic Organic Aerosol", "comment": "anthropogenic part of emioa", "dimensions": "longitude latitude time", "out_name": "emiaoa", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -627,16 +627,17 @@ "ok_max_mean_abs": "" }, "emibc": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_emission", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "emission rate of black carbon aerosol mass", + "long_name": "Total Emission Rate of Black Carbon Aerosol Mass", "comment": "Integrate 3D emission field vertically to 2d field.", "dimensions": "longitude latitude time", "out_name": "emibc", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -644,16 +645,17 @@ "ok_max_mean_abs": "" }, "emibvoc": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "tendency_of_atmosphere_mass_content_of_biogenic_nmvoc_expressed_as_carbon_due_to_emission", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "total emission rate of biogenic nmvoc", + "long_name": "Total Emission Rate of Biogenic NMVOC", "comment": "Integrate 3D emission field vertically to 2d field._If_ fixed molecular weight of NMVOC is not available in model, please provide in units of kilomole m-2 s-1 (i.e. kg m-2 s-1 as if model NMVOC had molecular weight of 1) and add a comment to your file.", "dimensions": "longitude latitude time", "out_name": "emibvoc", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -661,16 +663,17 @@ "ok_max_mean_abs": "" }, "emico": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "total emission rate of co", + "long_name": "Total Emission Rate of CO", "comment": "Integrate 3D emission field vertically to 2d field.", "dimensions": "longitude latitude time", "out_name": "emico", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -678,16 +681,17 @@ "ok_max_mean_abs": "" }, "emidms": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "tendency_of_atmosphere_mass_content_of_dimethyl_sulfide_due_to_emission", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "total emission rate of dms", + "long_name": "Total Emission Rate of DMS", "comment": "Integrate 3D emission field vertically to 2d field.", "dimensions": "longitude latitude time", "out_name": "emidms", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -695,16 +699,17 @@ "ok_max_mean_abs": "" }, "emidust": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_emission", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "total emission rate of dust", + "long_name": "Total Emission Rate of Dust", "comment": "Integrate 3D emission field vertically to 2d field.", "dimensions": "longitude latitude time", "out_name": "emidust", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -712,16 +717,17 @@ "ok_max_mean_abs": "" }, "emiisop": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "tendency_of_atmosphere_mass_content_of_isoprene_due_to_emission", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "total emission rate of isoprene", + "long_name": "Total Emission Rate of Isoprene", "comment": "Integrate 3D emission field vertically to 2d field", "dimensions": "longitude latitude time", "out_name": "emiisop", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -729,16 +735,17 @@ "ok_max_mean_abs": "" }, "emilnox": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "tendency_of_atmosphere_moles_of_nox_expressed_as_nitrogen", "units": "mol s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "layer-integrated lightning production of NOx", + "long_name": "Layer-Integrated Lightning Production of NOx", "comment": "Integrate the NOx production for lightning over model layer. proposed name: tendency_of_atmosphere_mass_content_of_nox_from_lightning", "dimensions": "longitude latitude alevel time", "out_name": "emilnox", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -746,16 +753,17 @@ "ok_max_mean_abs": "" }, "eminh3": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "total emission rate of nh3", + "long_name": "Total Emission Rate of NH3", "comment": "Integrate 3D emission field vertically to 2d field.", "dimensions": "longitude latitude time", "out_name": "eminh3", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -763,16 +771,17 @@ "ok_max_mean_abs": "" }, "eminox": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_due_to_emission", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "total emission rate of nox", + "long_name": "Total Emission Rate of NOx", "comment": "NOx=NO+NO2. Integrate 3D emission field vertically to 2d field.", "dimensions": "longitude latitude time", "out_name": "eminox", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -780,16 +789,17 @@ "ok_max_mean_abs": "" }, "emioa": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_net_chemical_production_and_emission", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "primary emission and chemical production of dry aerosol organic matter", - "comment": "This is the sum of total emission of POA and total production of SOA (emipoa+chepsoa). ''Mass'' refers to the mass of organic matter, not mass of organic carbon alone. We recommend a scale factor of POM=1.4*OC, unless your model has more detailed info available. Integrate 3D chemical production and emission field vertically to 2d field.", + "long_name": "Primary Emission and Chemical Production of Dry Aerosol Organic Matter", + "comment": "This is the sum of total emission of primary organic aerosol (POA) and total production of secondary organic aerosol (SOA) (emipoa+chepsoa). Here, mass refers to the mass of organic matter, not mass of organic carbon alone. We recommend a scale factor of POM=1.4*OC, unless your model has more detailed info available. Integrate 3D chemical production and emission field vertically to 2d field.", "dimensions": "longitude latitude time", "out_name": "emioa", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -797,16 +807,17 @@ "ok_max_mean_abs": "" }, "emiso2": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "total emission rate of so2", + "long_name": "Total Emission Rate of SO2", "comment": "Integrate 3D emission field vertically to 2d field.", "dimensions": "longitude latitude time", "out_name": "emiso2", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -814,16 +825,17 @@ "ok_max_mean_abs": "" }, "emiso4": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_emission", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "total direct emission rate of so4", + "long_name": "Total Direct Emission Rate of SO4", "comment": "Direct primary emission does not include secondary sulfate production. Integrate 3D emission field vertically to 2d field.", "dimensions": "longitude latitude time", "out_name": "emiso4", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -831,16 +843,17 @@ "ok_max_mean_abs": "" }, "emiss": { + "frequency": "mon", "modeling_realm": "aerosol", - "standard_name": "tendency_of_atmosphere_mass_content_of_seasalt_dry_aerosol_particles_due_to_emission", + "standard_name": "tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_emission", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "total emission rate of seasalt", + "long_name": "Total Emission Rate of Sea-Salt Aerosol", "comment": "Integrate 3D emission field vertically to 2d field.", "dimensions": "longitude latitude time", "out_name": "emiss", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -848,16 +861,17 @@ "ok_max_mean_abs": "" }, "emivoc": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "tendency_of_atmosphere_mass_content_of_nmvoc_due_to_emission", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "total emission rate of nmvoc", + "long_name": "Total Emission Rate of NMVOC", "comment": "Integrate 3D emission field vertically to 2d field. _If_ fixed molecular weight of NMVOC is not available in model, please provide in units of kilomole m-2 s-1 (i.e. kg m-2 s-1 as if model NMVOC had molecular weight of 1) and add a comment to your file.", "dimensions": "longitude latitude time", "out_name": "emivoc", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -865,16 +879,17 @@ "ok_max_mean_abs": "" }, "h2o": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "mass_fraction_of_water_in_air", - "units": "1.0", + "units": "1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Water vapour volume mixing ratio", + "long_name": "Mass Fraction of Water", "comment": "includes all phases of water", "dimensions": "longitude latitude alevel time", "out_name": "h2o", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -882,16 +897,17 @@ "ok_max_mean_abs": "" }, "hcho": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "mole_fraction_of_formaldehyde_in_air", "units": "mol mol-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Formaldehyde volume mixing ratio", - "comment": "", + "long_name": "Formaldehyde Volume Mixing Ratio", + "comment": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", "dimensions": "longitude latitude alevel time", "out_name": "hcho", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -899,16 +915,17 @@ "ok_max_mean_abs": "" }, "hcl": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "mole_fraction_of_hydrogen_chloride_in_air", "units": "mol mol-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "HCl volume mixing ratio", - "comment": "", + "long_name": "HCl Volume Mixing Ratio", + "comment": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. The chemical formula of hydrogen chloride is HCl.", "dimensions": "longitude latitude alevel time", "out_name": "hcl", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -916,16 +933,17 @@ "ok_max_mean_abs": "" }, "hno3": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "mole_fraction_of_nitric_acid_in_air", "units": "mol mol-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "HNO3 volume mixing ratio", - "comment": "", + "long_name": "HNO3 Volume Mixing Ratio", + "comment": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", "dimensions": "longitude latitude alevel time", "out_name": "hno3", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -933,16 +951,17 @@ "ok_max_mean_abs": "" }, "isop": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "mole_fraction_of_isoprene_in_air", "units": "mol mol-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Isoprene volume mixing ratio", - "comment": "", + "long_name": "Isoprene Volume Mixing Ratio", + "comment": "Mole fraction of isoprene in air.", "dimensions": "longitude latitude alevel time", "out_name": "isop", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -950,16 +969,17 @@ "ok_max_mean_abs": "" }, "jno2": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "photolysis_rate_of_nitrogen_dioxide", "units": "s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "photolysis rate of NO2", - "comment": "", + "long_name": "Photolysis Rate of NO2", + "comment": "Photolysis rate of nitrogen dioxide (NO2)", "dimensions": "longitude latitude alevel time", "out_name": "jno2", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -967,16 +987,17 @@ "ok_max_mean_abs": "" }, "lossch4": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "tendency_of_atmosphere_mole_concentration_of_methane_due_to_chemical_destruction", "units": "mol m-3 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Monthly Loss of atmospheric Methane", + "long_name": "Monthly Loss of Atmospheric Methane", "comment": "monthly averaged atmospheric loss", "dimensions": "longitude latitude alevel time", "out_name": "lossch4", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -984,16 +1005,17 @@ "ok_max_mean_abs": "" }, "lossco": { + "frequency": "mon", "modeling_realm": "aerosol", - "standard_name": "tendency_of_atmosphere_of_mole_concentration_of_carbon_monoxide_due_to_chemical_destruction", + "standard_name": "tendency_of_atmosphere_mole_concentration_of_carbon_monoxide_due_to_chemical_destruction", "units": "mol m-3 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Monthly Loss of atmospheric Carbon Monoxide", + "long_name": "Monthly Loss of Atmospheric Carbon Monoxide", "comment": "monthly averaged atmospheric loss", "dimensions": "longitude latitude alevel time", "out_name": "lossco", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1001,16 +1023,17 @@ "ok_max_mean_abs": "" }, "lossn2o": { + "frequency": "mon", "modeling_realm": "aerosol", - "standard_name": "tendency_of_atmosphere_of_mole_concentration_of_nitrous_oxide_due_to_chemical_destruction", + "standard_name": "tendency_of_atmosphere_mole_concentration_of_nitrous_oxide_due_to_chemical_destruction", "units": "mol m-3 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Monthly Loss of atmospheric Nitrous Oxide", + "long_name": "Monthly Loss of Atmospheric Nitrous Oxide", "comment": "monthly averaged atmospheric loss", "dimensions": "longitude latitude alevel time", "out_name": "lossn2o", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1018,16 +1041,17 @@ "ok_max_mean_abs": "" }, "lwp": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "atmosphere_mass_content_of_cloud_liquid_water", "units": "kg m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "liquid water path", - "comment": "", + "long_name": "Liquid Water Path", + "comment": "The total mass of liquid water in cloud per unit area.", "dimensions": "longitude latitude time", "out_name": "lwp", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1035,16 +1059,17 @@ "ok_max_mean_abs": "" }, "mmraerh2o": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "mass_fraction_of_water_in_ambient_aerosol_particles_in_air", "units": "kg kg-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Aerosol water mass mixing ratio", - "comment": "", + "long_name": "Aerosol Water Mass Mixing Ratio", + "comment": "Mass fraction is used in the construction mass_fraction_of_X_in_Y, where X is a material constituent of Y. It means the ratio of the mass of X to the mass of Y (including X). 'Aerosol' means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. 'Ambient_aerosol' means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. 'Ambient aerosol particles' are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles.", "dimensions": "longitude latitude alevel time", "out_name": "mmraerh2o", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1052,16 +1077,17 @@ "ok_max_mean_abs": "" }, "mmrbc": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "mass_fraction_of_elemental_carbon_dry_aerosol_particles_in_air", "units": "kg kg-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Elemental carbon mass mixing ratio", - "comment": "", + "long_name": "Elemental Carbon Mass Mixing Ratio", + "comment": "Dry mass fraction of black carbon aerosol particles in air.", "dimensions": "longitude latitude alevel time", "out_name": "mmrbc", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1069,16 +1095,17 @@ "ok_max_mean_abs": "" }, "mmrdust": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "mass_fraction_of_dust_dry_aerosol_particles_in_air", "units": "kg kg-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Dust aerosol mass mixing ratio", - "comment": "", + "long_name": "Dust Aerosol Mass Mixing Ratio", + "comment": "Dry mass fraction of dust aerosol particles in air.", "dimensions": "longitude latitude alevel time", "out_name": "mmrdust", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1086,16 +1113,17 @@ "ok_max_mean_abs": "" }, "mmrnh4": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "mass_fraction_of_ammonium_dry_aerosol_particles_in_air", "units": "kg kg-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "NH4 mass mixing ratio", - "comment": "", + "long_name": "NH4 Mass Mixing Ratio", + "comment": "Dry mass fraction of ammonium aerosol particles in air.", "dimensions": "longitude latitude alevel time", "out_name": "mmrnh4", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1103,16 +1131,17 @@ "ok_max_mean_abs": "" }, "mmrno3": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "mass_fraction_of_nitrate_dry_aerosol_particles_in_air", "units": "kg kg-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "NO3 aerosol mass mixing ratio", - "comment": "", + "long_name": "NO3 Aerosol Mass Mixing Ratio", + "comment": "Dry mass fraction of nitrate aerosol particles in air.", "dimensions": "longitude latitude alevel time", "out_name": "mmrno3", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1120,16 +1149,17 @@ "ok_max_mean_abs": "" }, "mmroa": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "mass_fraction_of_particulate_organic_matter_dry_aerosol_particles_in_air", "units": "kg kg-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Total organic aerosol mass mixing ratio", + "long_name": "Total Organic Aerosol Mass Mixing Ratio", "comment": "We recommend a scale factor of POM=1.4*OC, unless your model has more detailed info available.", "dimensions": "longitude latitude alevel time", "out_name": "mmroa", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1137,16 +1167,17 @@ "ok_max_mean_abs": "" }, "mmrpm1": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "mass_fraction_of_pm1_dry_aerosol_particles_in_air", "units": "kg kg-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "PM1.0 mass mixing ratio", - "comment": "E.g. mass_fraction_of_pm1_aerosol_at_50_percent_relative_humidity_in_air. proposed name: mass_fraction_of_pm1_dry_aerosol_in_air", + "long_name": "PM1.0 Mass Mixing Ratio", + "comment": "Mass fraction atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 1 micrometers", "dimensions": "longitude latitude alevel time", "out_name": "mmrpm1", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1154,16 +1185,17 @@ "ok_max_mean_abs": "" }, "mmrpm10": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "mass_fraction_of_pm10_ambient_aerosol_particles_in_air", "units": "kg kg-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "PM10 mass mixing ratio", - "comment": "E.g. mass_fraction_of_pm10_aerosol_at_50_percent_relative_humidity_in_air, proposed name: mass_fraction_of_pm10_dry_aerosol_in_air", + "long_name": "PM10 Mass Mixing Ratio", + "comment": "Mass fraction atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 10 micrometers", "dimensions": "longitude latitude alevel time", "out_name": "mmrpm10", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1171,16 +1203,17 @@ "ok_max_mean_abs": "" }, "mmrpm2p5": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "mass_fraction_of_pm2p5_dry_aerosol_particles_in_air", "units": "kg kg-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "PM2.5 mass mixing ratio", - "comment": "E.g. mass_fraction_of_pm2p5_aerosol_at_50_percent_relative_humidity_in_air, proposed_name: mass_fraction_of_pm2p5_dry_aerosol_in_air", + "long_name": "PM2.5 Mass Mixing Ratio", + "comment": "Mass fraction atmospheric particulate compounds with an aerodynamic diameter of less than or equal to 2.5 micrometers", "dimensions": "longitude latitude alevel time", "out_name": "mmrpm2p5", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1188,16 +1221,17 @@ "ok_max_mean_abs": "" }, "mmrso4": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "mass_fraction_of_sulfate_dry_aerosol_particles_in_air", "units": "kg kg-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Aerosol sulfate mass mixing ratio", - "comment": "", + "long_name": "Aerosol Sulfate Mass Mixing Ratio", + "comment": "Dry mass of sulfate (SO4) in aerosol particles as a fraction of air mass.", "dimensions": "longitude latitude alevel time", "out_name": "mmrso4", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1205,16 +1239,17 @@ "ok_max_mean_abs": "" }, "mmrsoa": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "mass_fraction_of_secondary_particulate_organic_matter_dry_aerosol_particles_in_air", "units": "kg kg-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Secondary organic aerosol mass mixing ratio", - "comment": "", + "long_name": "Secondary Organic Aerosol Mass Mixing Ratio", + "comment": "Mass fraction in the atmosphere of secondary organic aerosols (particulate organic matter formed within the atmosphere from gaseous precursors; dry mass).", "dimensions": "longitude latitude alevel time", "out_name": "mmrsoa", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1222,16 +1257,17 @@ "ok_max_mean_abs": "" }, "mmrss": { + "frequency": "mon", "modeling_realm": "aerosol", - "standard_name": "mass_fraction_of_seasalt_dry_aerosol_particles_in_air", + "standard_name": "mass_fraction_of_sea_salt_dry_aerosol_particles_in_air", "units": "kg kg-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Sea Salt mass mixing ratio", - "comment": "", + "long_name": "Sea-Salt Aerosol Mass Mixing Ratio", + "comment": "Mass fraction in the atmosphere of sea salt aerosol (dry mass).", "dimensions": "longitude latitude alevel time", "out_name": "mmrss", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1239,16 +1275,17 @@ "ok_max_mean_abs": "" }, "n2o": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "mole_fraction_of_nitrous_oxide_in_air", "units": "mol mol-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "N2O volume mixing ratio", - "comment": "", + "long_name": "Mole Fraction of N2O", + "comment": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. The chemical formula of nitrous oxide is N2O.", "dimensions": "longitude latitude alevel time", "out_name": "n2o", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1256,16 +1293,17 @@ "ok_max_mean_abs": "" }, "nh50": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "mole_fraction_of_artificial_tracer_with_fixed_lifetime_in_air", "units": "mol mol-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Artificial tracer with 50 day lifetime", - "comment": "", + "long_name": "Artificial Tracer with 50 Day Lifetime", + "comment": "Fixed surface layer mixing ratio over 30o-50oN (100ppbv), uniform fixed 50-day exponential decay.", "dimensions": "longitude latitude alevel time", "out_name": "nh50", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1273,16 +1311,17 @@ "ok_max_mean_abs": "" }, "no": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "mole_fraction_of_nitrogen_monoxide_in_air", "units": "mol mol-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "NO volume mixing ratio", - "comment": "", + "long_name": "NO Volume Mixing Ratio", + "comment": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", "dimensions": "longitude latitude alevel time", "out_name": "no", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1290,16 +1329,17 @@ "ok_max_mean_abs": "" }, "no2": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "mole_fraction_of_nitrogen_dioxide_in_air", "units": "mol mol-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "NO2 volume mixing ratio", - "comment": "", + "long_name": "NO2 Volume Mixing Ratio", + "comment": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", "dimensions": "longitude latitude alevel time", "out_name": "no2", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1307,16 +1347,17 @@ "ok_max_mean_abs": "" }, "o3": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "mole_fraction_of_ozone_in_air", "units": "mol mol-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Ozone volume mixing ratio", - "comment": "", + "long_name": "Mole Fraction of O3", + "comment": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", "dimensions": "longitude latitude alevel time", "out_name": "o3", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1324,16 +1365,17 @@ "ok_max_mean_abs": "" }, "o3loss": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "tendency_of_atmosphere_mole_concentration_of_ozone_due_to_chemical_destruction", "units": "mol m-3 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "O3 destruction rate", + "long_name": "O3 Destruction Rate", "comment": "ONLY provide the sum of the following reactions: (i) O(1D)+H2O; (ii) O3+HO2; (iii) O3+OH; (iv) O3+alkenes (isoprene, ethene,...)", "dimensions": "longitude latitude alevel time", "out_name": "o3loss", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1341,16 +1383,17 @@ "ok_max_mean_abs": "" }, "o3prod": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "tendency_of_atmosphere_mole_concentration_of_ozone_due_to_chemical_production", "units": "mol m-3 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "O3 production rate", + "long_name": "O3 Production Rate", "comment": "ONLY provide the sum of all the HO2/RO2 + NO reactions (as k*[HO2]*[NO])", "dimensions": "longitude latitude alevel time", "out_name": "o3prod", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1358,16 +1401,17 @@ "ok_max_mean_abs": "" }, "o3ste": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "mole_fraction_of_ozone_in_air", "units": "mol mol-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Ozone volume mixing ratio", - "comment": "Ozone tracer intended to map out strat-trop exchange (STE) of ozone.", + "long_name": "Stratospheric Ozone Tracer Volume Mixing Ratio", + "comment": "Ozone tracer intended to map out strat-trop exchange (STE) of ozone. Set to ozone in the stratosphere, then destroyed in the troposphere using the ozone chemical loss rate. Please specify the tropopause definition used", "dimensions": "longitude latitude alevel time", "out_name": "o3ste", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1375,16 +1419,17 @@ "ok_max_mean_abs": "" }, "od440aer": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "atmosphere_optical_thickness_due_to_ambient_aerosol_particles", - "units": "1.0", + "units": "1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "ambient aerosol optical thickness at 440 nm", - "comment": "AOD from the ambient aerosls (i.e., includes aerosol water). Does not include AOD from stratospheric aerosols if these are prescribed but includes other possible background aerosol types. Needs a comment attribute 'wavelength: 440 nm'", + "long_name": "Ambient Aerosol Optical Thickness at 440nm", + "comment": "AOD from the ambient aerosols (i.e., includes aerosol water). Does not include AOD from stratospheric aerosols if these are prescribed but includes other possible background aerosol types. Needs a comment attribute 'wavelength: 440nm'", "dimensions": "longitude latitude time", "out_name": "od440aer", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1392,16 +1437,17 @@ "ok_max_mean_abs": "" }, "od550aer": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "atmosphere_optical_thickness_due_to_ambient_aerosol_particles", - "units": "1.0", + "units": "1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "ambient aerosol optical thickness at 550 nm", - "comment": "AOD from the ambient aerosls (i.e., includes aerosol water). Does not include AOD from stratospheric aerosols if these are prescribed but includes other possible background aerosol types. Needs a comment attribute 'wavelength: 550 nm'", - "dimensions": "longitude latitude time", + "long_name": "Ambient Aerosol Optical Thickness at 550nm", + "comment": "AOD from the ambient aerosols (i.e., includes aerosol water). Does not include AOD from stratospheric aerosols if these are prescribed but includes other possible background aerosol types. Needs a comment attribute 'wavelength: 550nm'", + "dimensions": "longitude latitude time lambda550nm", "out_name": "od550aer", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1409,16 +1455,17 @@ "ok_max_mean_abs": "" }, "od550aerh2o": { + "frequency": "mon", "modeling_realm": "aerosol", - "standard_name": "atmosphere_optical_thickness_due_to_water_in_ambient_aerosol", - "units": "1.0", + "standard_name": "atmosphere_optical_thickness_due_to_water_in_ambient_aerosol_particles", + "units": "1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "aerosol water aod@550nm", + "long_name": "Aerosol Water Optical Thickness at 550nm", "comment": "proposed name: atmosphere_optical_thickness_due_to_water_ambient_aerosol", - "dimensions": "longitude latitude time", + "dimensions": "longitude latitude time lambda550nm", "out_name": "od550aerh2o", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1426,16 +1473,17 @@ "ok_max_mean_abs": "" }, "od550bb": { + "frequency": "mon", "modeling_realm": "aerosol", - "standard_name": "atmosphere_optical_thickness_due_to_particulate_organic_matter_ambient_aerosol", - "units": "1.0", + "standard_name": "atmosphere_optical_thickness_due_to_particulate_organic_matter_ambient_aerosol_particles", + "units": "1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "bb aod@550nm", + "long_name": "Aerosol Optical Depth at 550nm Due to Biomass Burning", "comment": "total organic aerosol AOD due to biomass burning (excluding so4, nitrate BB components)", - "dimensions": "longitude latitude time", + "dimensions": "longitude latitude time lambda550nm", "out_name": "od550bb", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1443,16 +1491,17 @@ "ok_max_mean_abs": "" }, "od550bc": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "atmosphere_optical_thickness_due_to_black_carbon_ambient_aerosol", - "units": "1.0", + "units": "1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "black carbon aod@550nm", - "comment": "", - "dimensions": "longitude latitude time", + "long_name": "Black Carbon Optical Thickness at 550nm", + "comment": "Total aerosol AOD due to black carbon aerosol at a wavelength of 550 nanometres.", + "dimensions": "longitude latitude time lambda550nm", "out_name": "od550bc", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1460,16 +1509,17 @@ "ok_max_mean_abs": "" }, "od550csaer": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "atmosphere_optical_thickness_due_to_ambient_aerosol_particles", - "units": "1.0", + "units": "1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "ambient aerosol optical thickness at 550 nm", - "comment": "AOD from the ambient aerosols in clear skies if od550aer is for all-sky (i.e., includes aerosol water). Does not include AOD from stratospheric aerosols if these are prescribed but includes other possible background aerosol types. Needs a comment attribute 'wavelength: 550 nm'", - "dimensions": "longitude latitude time", + "long_name": "Ambient Aerosol Optical Thickness at 550nm", + "comment": "AOD from the ambient aerosols in clear skies if od550aer is for all-sky (i.e., includes aerosol water). Does not include AOD from stratospheric aerosols if these are prescribed but includes other possible background aerosol types. Needs a comment attribute 'wavelength: 550nm'", + "dimensions": "longitude latitude time lambda550nm", "out_name": "od550csaer", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1477,16 +1527,17 @@ "ok_max_mean_abs": "" }, "od550dust": { + "frequency": "mon", "modeling_realm": "aerosol", - "standard_name": "atmosphere_optical_thickness_due_to_dust_ambient_aerosol", - "units": "1.0", + "standard_name": "atmosphere_optical_thickness_due_to_dust_ambient_aerosol_particles", + "units": "1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "dust aod@550nm", - "comment": "", - "dimensions": "longitude latitude time", + "long_name": "Dust Optical Thickness at 550nm", + "comment": "Total aerosol AOD due to dust aerosol at a wavelength of 550 nanometres.", + "dimensions": "longitude latitude time lambda550nm", "out_name": "od550dust", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1494,16 +1545,17 @@ "ok_max_mean_abs": "" }, "od550lt1aer": { + "frequency": "mon", "modeling_realm": "aerosol", - "standard_name": "atmosphere_optical_thickness_due_to_pm1_ambient_aerosol", - "units": "1.0", + "standard_name": "atmosphere_optical_thickness_due_to_pm1_ambient_aerosol_particles", + "units": "1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "ambient fine mode aerosol optical thickness at 550 nm", + "long_name": "Ambient Fine Aerosol Optical Depth at 550nm", "comment": "od550 due to particles with wet diameter less than 1 um (ambient here means wetted). When models do not include explicit size information, it can be assumed that all anthropogenic aerosols and natural secondary aerosols have diameter less than 1 um.", - "dimensions": "longitude latitude time", + "dimensions": "longitude latitude time lambda550nm", "out_name": "od550lt1aer", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1511,16 +1563,17 @@ "ok_max_mean_abs": "" }, "od550no3": { + "frequency": "mon", "modeling_realm": "aerosol", - "standard_name": "atmosphere_optical_thickness_due_to_nitrate_ambient_aerosol", - "units": "1.0", + "standard_name": "atmosphere_optical_thickness_due_to_nitrate_ambient_aerosol_particles", + "units": "1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "nitrate aod@550nm", - "comment": "proposed name: atmosphere_optical_thickness_due_to_nitrate_ambient_aerosol", - "dimensions": "longitude latitude time", + "long_name": "Nitrate Aerosol Optical Depth at 550nm", + "comment": "Total aerosol AOD due to nitrate aerosol at a wavelength of 550 nanometres.", + "dimensions": "longitude latitude time lambda550nm", "out_name": "od550no3", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1528,16 +1581,17 @@ "ok_max_mean_abs": "" }, "od550oa": { + "frequency": "mon", "modeling_realm": "aerosol", - "standard_name": "atmosphere_optical_thickness_due_to_particulate_organic_matter_ambient_aerosol", - "units": "1.0", + "standard_name": "atmosphere_optical_thickness_due_to_particulate_organic_matter_ambient_aerosol_particles", + "units": "1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "total organic aerosol aod@550nm", - "comment": "", - "dimensions": "longitude latitude time", + "long_name": "Total Organic Aerosol Optical Depth at 550nm", + "comment": "Total aerosol AOD due to organic aerosol at a wavelength of 550 nanometres.", + "dimensions": "longitude latitude time lambda550nm", "out_name": "od550oa", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1545,16 +1599,17 @@ "ok_max_mean_abs": "" }, "od550so4": { + "frequency": "mon", "modeling_realm": "aerosol", - "standard_name": "atmosphere_optical_thickness_due_to_sulfate_ambient_aerosol", - "units": "1.0", + "standard_name": "atmosphere_optical_thickness_due_to_sulfate_ambient_aerosol_particles", + "units": "1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "sulfate aod@550nm", - "comment": "proposed name: atmosphere_optical_thickness_due_to_sulfate_ambient_aerosol", - "dimensions": "longitude latitude time", + "long_name": "Sulfate Aerosol Optical Depth at 550nm", + "comment": "Total aerosol AOD due to sulfate aerosol at a wavelength of 550 nanometres.", + "dimensions": "longitude latitude time lambda550nm", "out_name": "od550so4", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1562,16 +1617,17 @@ "ok_max_mean_abs": "" }, "od550soa": { + "frequency": "mon", "modeling_realm": "aerosol", - "standard_name": "atmosphere_optical_thickness_due_to_particulate_organic_matter_ambient_aerosol", - "units": "1.0", + "standard_name": "atmosphere_optical_thickness_due_to_particulate_organic_matter_ambient_aerosol_particles", + "units": "1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "soa aod@550nm", - "comment": "total organic aerosol AOD due to secondary aerosol formation", - "dimensions": "longitude latitude time", + "long_name": "Particulate Organic Aerosol Optical Depth at 550nm", + "comment": "Total organic aerosol AOD due to secondary aerosol at a wavelength of 550 nanometres.", + "dimensions": "longitude latitude time lambda550nm", "out_name": "od550soa", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1579,16 +1635,17 @@ "ok_max_mean_abs": "" }, "od550ss": { + "frequency": "mon", "modeling_realm": "aerosol", - "standard_name": "atmosphere_optical_thickness_due_to_seasalt_ambient_aerosol", - "units": "1.0", + "standard_name": "atmosphere_optical_thickness_due_to_sea_salt_ambient_aerosol_particles", + "units": "1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "sea salt aod@550nm", - "comment": "", - "dimensions": "longitude latitude time", + "long_name": "Sea-Salt Aerosol Optical Depth at 550nm", + "comment": "Total aerosol AOD due to sea salt aerosol at a wavelength of 550 nanometres.", + "dimensions": "longitude latitude time lambda550nm", "out_name": "od550ss", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1596,16 +1653,17 @@ "ok_max_mean_abs": "" }, "od870aer": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "atmosphere_optical_thickness_due_to_ambient_aerosol_particles", - "units": "1.0", + "units": "1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "ambient aerosol optical thickness at 870 nm", - "comment": "AOD from the ambient aerosls (i.e., includes aerosol water). Does not include AOD from stratospheric aerosols if these are prescribed but includes other possible background aerosol types. Needs a comment attribute 'wavelength: 870 nm'", + "long_name": "Ambient Aerosol Optical Depth at 870nm", + "comment": "AOD from the ambient aerosols (i.e., includes aerosol water). Does not include AOD from stratospheric aerosols if these are prescribed but includes other possible background aerosol types. Needs a comment attribute 'wavelength: 870nm'", "dimensions": "longitude latitude time", "out_name": "od870aer", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1613,16 +1671,17 @@ "ok_max_mean_abs": "" }, "oh": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "mole_fraction_of_hydroxyl_radical_in_air", "units": "mol mol-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "OH volume mixing ratio", - "comment": "", + "long_name": "OH Volume Mixing Ratio", + "comment": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", "dimensions": "longitude latitude alevel time", "out_name": "oh", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1630,16 +1689,17 @@ "ok_max_mean_abs": "" }, "pan": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "mole_fraction_of_peroxyacetyl_nitrate_in_air", "units": "mol mol-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "PAN volume mixing ratio", - "comment": "", + "long_name": "PAN Volume Mixing Ratio", + "comment": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", "dimensions": "longitude latitude alevel time", "out_name": "pan", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1647,16 +1707,17 @@ "ok_max_mean_abs": "" }, "pfull": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "air_pressure", "units": "Pa", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Air Pressure", + "long_name": "Pressure at Model Full-Levels", "comment": "Air pressure on model levels", "dimensions": "longitude latitude alevel time", "out_name": "pfull", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1664,16 +1725,17 @@ "ok_max_mean_abs": "" }, "phalf": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "air_pressure", "units": "Pa", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "air pressure at interfaces", + "long_name": "Pressure on Model Half-Levels", "comment": "Air pressure on model half-levels", - "dimensions": "longitude latitude alevel time", + "dimensions": "longitude latitude alevhalf time", "out_name": "phalf", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1681,16 +1743,17 @@ "ok_max_mean_abs": "" }, "photo1d": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "photolysis_rate_of_ozone_to_1D_oxygen_atom", "units": "s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "photolysis rate of O3 to O1d", + "long_name": "Photolysis Rate of Ozone (O3) to Excited Atomic Oxygen (the Singlet D State, O1D)", "comment": "proposed name: photolysis_rate_of_ozone_to_O1D", "dimensions": "longitude latitude alevel time", "out_name": "photo1d", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1698,16 +1761,17 @@ "ok_max_mean_abs": "" }, "pod0": { + "frequency": "mon", "modeling_realm": "aerosol", - "standard_name": "pending_CF_name", - "units": "mol m-2 s-1", - "cell_methods": "area: time: mean", + "standard_name": "integral_wrt_time_of_mole_stomatal_uptake_of_ozone", + "units": "mol m-2", + "cell_methods": "area: mean time: sum", "cell_measures": "area: areacella", - "long_name": "Phytotoxic ozone dose", + "long_name": "Phytotoxic Ozone Dose", "comment": "Accumulated stomatal ozone flux over the threshold of 0 mol m-2 s-1; Computation: Time Integral of (hourly above canopy ozone concentration * stomatal conductance * Rc/(Rb+Rc) )", "dimensions": "longitude latitude time", "out_name": "pod0", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1715,16 +1779,17 @@ "ok_max_mean_abs": "" }, "ps": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "surface_air_pressure", "units": "Pa", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Surface Pressure", + "long_name": "Surface Air Pressure", "comment": "surface pressure (not mean sea-level pressure), 2-D field to calculate the 3-D pressure field from hybrid coordinates", "dimensions": "longitude latitude time", "out_name": "ps", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1732,6 +1797,7 @@ "ok_max_mean_abs": "" }, "ptp": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "tropopause_air_pressure", "units": "Pa", @@ -1741,7 +1807,7 @@ "comment": "2D monthly mean thermal tropopause calculated using WMO tropopause definition on 3d temperature", "dimensions": "longitude latitude time", "out_name": "ptp", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1749,16 +1815,17 @@ "ok_max_mean_abs": "" }, "reffclwtop": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "effective_radius_of_cloud_liquid_water_particle_at_liquid_water_cloud_top", "units": "m", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "cloud-top effective droplet radius", - "comment": "Droplets are liquid only. This is the effective radius as seen from space over liquid cloudy portion of grid cell. This is the value from uppermost model layer with liquid cloud or, if available, or for some models it is the sum over all liquid cloud tops, no matter where they occur, as long as they are seen from the top of the atmosphere.TOA) each time sample when computing monthly mean. Reported values are weighted by total liquid cloud top fraction of (as seen from", + "long_name": "Cloud-Top Effective Droplet Radius", + "comment": "Droplets are liquid only. This is the effective radius as seen from space over liquid cloudy portion of grid cell. This is the value from uppermost model layer with liquid cloud or, if available, or for some models it is the sum over all liquid cloud tops, no matter where they occur, as long as they are seen from the top of the atmosphere (TOA) each time sample when computing monthly mean. Reported values are weighted by total liquid cloud top fraction of (as seen from TOA) each time sample when computing monthly mean.", "dimensions": "longitude latitude time", "out_name": "reffclwtop", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1766,84 +1833,89 @@ "ok_max_mean_abs": "" }, "rlutaf": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "toa_outgoing_longwave_flux", "units": "W m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "toa outgoing longwave radiation", - "comment": "Flux corresponding to rlut resulting fom aerosol-free call to radiation, follwing Ghan (ACP, 2013)", + "long_name": "TOA Outgoing Aerosol-Free Longwave Radiation", + "comment": "Flux corresponding to rlut resulting from aerosol-free call to radiation, following Ghan (ACP, 2013)", "dimensions": "longitude latitude time", "out_name": "rlutaf", - "type": "float", - "positive": "", + "type": "real", + "positive": "up", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "rlutcsaf": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "toa_outgoing_longwave_flux_assuming_clear_sky", "units": "W m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "toa outgoing clear-sky longwave radiation", - "comment": "Flux corresponding to rlutcs resulting fom aerosol-free call to radiation, follwing Ghan (ACP, 2013)", + "long_name": "TOA Outgoing Clear-Sky, Aerosol-Free Longwave Radiation", + "comment": "Flux corresponding to rlutcs resulting from aerosol-free call to radiation, following Ghan (ACP, 2013)", "dimensions": "longitude latitude time", "out_name": "rlutcsaf", - "type": "float", - "positive": "", + "type": "real", + "positive": "up", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "rsutaf": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "toa_outgoing_shortwave_flux", "units": "W m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "toa outgoing shortwave radiation", - "comment": "Flux corresponding to rsut resulting fom aerosol-free call to radiation, following Ghan (ACP, 2013)", + "long_name": "TOA Outgoing Aerosol-Free Shortwave Radiation", + "comment": "Flux corresponding to rsut resulting from aerosol-free call to radiation, following Ghan (ACP, 2013)", "dimensions": "longitude latitude time", "out_name": "rsutaf", - "type": "float", - "positive": "", + "type": "real", + "positive": "up", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "rsutcsaf": { + "frequency": "mon", "modeling_realm": "aerosol", - "standard_name": "toa_outgoing_shortwave_flux_assuming_clear_sky", + "standard_name": "toa_outgoing_shortwave_flux_assuming_clear_sky_and_no_aerosol", "units": "W m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "toa outgoing clear-sky shortwave radiation", - "comment": "Flux corresponding to rsutcs resulting fom aerosol-free call to radiation, following Ghan (ACP, 2013)", + "long_name": "TOA Outgoing Clear-Sky, Aerosol-Free Shortwave Radiation", + "comment": "Flux corresponding to rsutcs resulting from aerosol-free call to radiation, following Ghan (ACP, 2013)", "dimensions": "longitude latitude time", "out_name": "rsutcsaf", - "type": "float", - "positive": "", + "type": "real", + "positive": "up", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "so2": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "mole_fraction_of_sulfur_dioxide_in_air", "units": "mol mol-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "SO2 volume mixing ratio", - "comment": "", + "long_name": "SO2 Volume Mixing Ratio", + "comment": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", "dimensions": "longitude latitude alevel time", "out_name": "so2", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1851,6 +1923,7 @@ "ok_max_mean_abs": "" }, "tatp": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "tropopause_air_temperature", "units": "K", @@ -1860,7 +1933,7 @@ "comment": "2D monthly mean thermal tropopause calculated using WMO tropopause definition on 3d temperature", "dimensions": "longitude latitude time", "out_name": "tatp", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1868,16 +1941,17 @@ "ok_max_mean_abs": "" }, "tntrl": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "tendency_of_air_temperature_due_to_longwave_heating", "units": "K s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Longwave heating rate", + "long_name": "Tendency of Air Temperature Due to Longwave Radiative Heating", "comment": "Tendency of air temperature due to longwave radiative heating", "dimensions": "longitude latitude alevel time", "out_name": "tntrl", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1885,16 +1959,17 @@ "ok_max_mean_abs": "" }, "tntrs": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "tendency_of_air_temperature_due_to_shortwave_heating", "units": "K s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Shortwave heating rate", + "long_name": "Tendency of Air Temperature Due to Shortwave Radiative Heating", "comment": "Tendency of air temperature due to shortwave radiative heating", "dimensions": "longitude latitude alevel time", "out_name": "tntrs", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1902,16 +1977,17 @@ "ok_max_mean_abs": "" }, "toz": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "equivalent_thickness_at_stp_of_atmosphere_ozone_content", "units": "m", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Total Ozone Column", - "comment": "total ozone column in DU", + "long_name": "Total Column Ozone", + "comment": "Total ozone column calculated at 0 degrees C and 1 bar, such that 1m = 1e5 DU.", "dimensions": "longitude latitude time", "out_name": "toz", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1919,16 +1995,17 @@ "ok_max_mean_abs": "" }, "tropoz": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "equivalent_thickness_at_stp_of_atmosphere_ozone_content", "units": "m", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "tropospheric ozone column", - "comment": "tropospheric ozone column in DU, should be consistent with ptp definition of tropopause", + "long_name": "Tropospheric Ozone Column", + "comment": "Tropospheric ozone column, should be consistent with definition of tropopause used to calculate the pressure of the tropopause (ptp). Calculated at 0 degrees C and 1 bar, such that 1m = 1e5 DU.", "dimensions": "longitude latitude time", "out_name": "tropoz", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1936,16 +2013,17 @@ "ok_max_mean_abs": "" }, "ttop": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "air_temperature_at_cloud_top", "units": "K", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "air temperature at cloud top", - "comment": "", + "long_name": "Air Temperature at Cloud Top", + "comment": "cloud_top refers to the top of the highest cloud. Air temperature is the bulk temperature of the air, not the surface (skin) temperature.", "dimensions": "longitude latitude time", "out_name": "ttop", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1953,16 +2031,17 @@ "ok_max_mean_abs": "" }, "ua": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "eastward_wind", "units": "m s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Eastward Wind", - "comment": "", + "comment": "Zonal wind (positive in a eastward direction).", "dimensions": "longitude latitude alevel time", "out_name": "ua", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1970,16 +2049,17 @@ "ok_max_mean_abs": "" }, "va": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "northward_wind", "units": "m s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Northward Wind", - "comment": "", + "comment": "Meridional wind (positive in a northward direction).", "dimensions": "longitude latitude alevel time", "out_name": "va", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1987,16 +2067,17 @@ "ok_max_mean_abs": "" }, "wa": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "upward_air_velocity", "units": "m s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Upward Air Velocity", - "comment": "", + "comment": "A velocity is a vector quantity. 'Upward' indicates a vector component which is positive when directed upward (negative downward). Upward air velocity is the vertical component of the 3D air velocity vector. The standard name downward_air_velocity may be used for a vector component with the opposite sign convention.", "dimensions": "longitude latitude alevel time", "out_name": "wa", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2004,16 +2085,17 @@ "ok_max_mean_abs": "" }, "wetbc": { + "frequency": "mon", "modeling_realm": "aerosol", - "standard_name": "tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_wet_deposition", + "standard_name": "minus_tendency_of_atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles_due_to_wet_deposition", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "wet deposition rate of black carbon aerosol mass", - "comment": "", + "long_name": "Wet Deposition Rate of Black Carbon Aerosol Mass", + "comment": "Surface deposition rate of black carbon (dry mass) due to wet processes", "dimensions": "longitude latitude time", "out_name": "wetbc", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2021,16 +2103,17 @@ "ok_max_mean_abs": "" }, "wetdust": { + "frequency": "mon", "modeling_realm": "aerosol", - "standard_name": "tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_wet_deposition", + "standard_name": "minus_tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_wet_deposition", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "wet deposition rate of dust", - "comment": "", + "long_name": "Wet Deposition Rate of Dust", + "comment": "Surface deposition rate of dust (dry mass) due to wet processes", "dimensions": "longitude latitude time", "out_name": "wetdust", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2038,16 +2121,17 @@ "ok_max_mean_abs": "" }, "wetnh3": { + "frequency": "mon", "modeling_realm": "aerosol", - "standard_name": "tendency_of_atmosphere_mass_content_of_ammonia_due_to_wet_deposition", + "standard_name": "minus_tendency_of_atmosphere_mass_content_of_ammonia_due_to_wet_deposition", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "wet deposition rate of nh3", - "comment": "", + "long_name": "Wet Deposition Rate of NH3", + "comment": "Surface deposition rate of ammonia (NH3) due to wet processes", "dimensions": "longitude latitude time", "out_name": "wetnh3", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2055,16 +2139,17 @@ "ok_max_mean_abs": "" }, "wetnh4": { + "frequency": "mon", "modeling_realm": "aerosol", - "standard_name": "tendency_of_atmosphere_mass_content_of_ammonium_dry_aerosol_particles_due_to_wet_deposition", + "standard_name": "minus_tendency_of_atmosphere_mass_content_of_ammonium_dry_aerosol_particles_due_to_wet_deposition", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "wet deposition rate of nh4", - "comment": "", + "long_name": "Wet Deposition Rate of NH4", + "comment": "Surface deposition rate of ammonium (NH4) due to wet processes", "dimensions": "longitude latitude time", "out_name": "wetnh4", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2072,16 +2157,17 @@ "ok_max_mean_abs": "" }, "wetnoy": { + "frequency": "mon", "modeling_realm": "aerosol", - "standard_name": "tendency_of_atmosphere_mass_content_of_noy_expressed_as_nitrogen_due_to_wet_deposition", + "standard_name": "minus_tendency_of_atmosphere_mass_content_of_noy_expressed_as_nitrogen_due_to_wet_deposition", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "wet deposition of noy incl aerosol nitrate", - "comment": "NOy is the sum of all simulated oxidized nitrogen species, out of NO, NO2, HNO3, HNO4, NO3aerosol, NO3(radical), N2O5, PAN, other organic nitrates.", + "long_name": "Wet Deposition Rate of NOy Including Aerosol Nitrate", + "comment": "NOy is the sum of all simulated oxidized nitrogen species, out of NO, NO2, HNO3, HNO4, NO3 aerosol, NO3 (radical), N2O5, PAN, other organic nitrates.", "dimensions": "longitude latitude time", "out_name": "wetnoy", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2089,16 +2175,17 @@ "ok_max_mean_abs": "" }, "wetoa": { + "frequency": "mon", "modeling_realm": "aerosol", - "standard_name": "tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_wet_deposition", + "standard_name": "minus_tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles_due_to_wet_deposition", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "wet deposition rate of dry aerosol total organic matter", - "comment": "tendency of atmosphere mass content of organic matter dry aerosols due to wet deposition: This is the sum of wet deposition of POA and wet deposition of SOA (see next two entries). Mass here refers to the mass of organic matter, not mass of organic carbon alone. We recommend a scale factor of POM=1.4*OC, unless your model has more detailed info available. Was called wet_pom in old ACCMIP Excel spreadsheet.", + "long_name": "Wet Deposition Rate of Dry Aerosol Total Organic Matter", + "comment": "Deposition rate of organic matter in aerosols (measured by the dry mass) due to wet processes", "dimensions": "longitude latitude time", "out_name": "wetoa", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2106,16 +2193,17 @@ "ok_max_mean_abs": "" }, "wetso2": { + "frequency": "mon", "modeling_realm": "aerosol", - "standard_name": "tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_wet_deposition", + "standard_name": "minus_tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_wet_deposition", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "wet deposition rate of so2", - "comment": "", + "long_name": "Wet Deposition Rate of SO2", + "comment": "Deposition rate of sulfur dioxide due to wet processes", "dimensions": "longitude latitude time", "out_name": "wetso2", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2123,16 +2211,17 @@ "ok_max_mean_abs": "" }, "wetso4": { + "frequency": "mon", "modeling_realm": "aerosol", - "standard_name": "tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_wet_deposition", + "standard_name": "minus_tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_particles_due_to_wet_deposition", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "wet deposition rate of so4", - "comment": "proposed name: tendency_of_atmosphere_mass_content_of_sulfate_dry_aerosol_due_to_wet_deposition", + "long_name": "Wet Deposition Rate of SO4", + "comment": "Deposition rate of sulfate aerosols (measured by the dry mass) due to wet processes", "dimensions": "longitude latitude time", "out_name": "wetso4", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2140,16 +2229,17 @@ "ok_max_mean_abs": "" }, "wetss": { + "frequency": "mon", "modeling_realm": "aerosol", - "standard_name": "tendency_of_atmosphere_mass_content_of_seasalt_dry_aerosol_particles_due_to_wet_deposition", + "standard_name": "minus_tendency_of_atmosphere_mass_content_of_sea_salt_dry_aerosol_particles_due_to_wet_deposition", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "wet deposition rate of seasalt", - "comment": "", + "long_name": "Wet Deposition Rate of Sea-Salt Aerosol", + "comment": "Deposition rate of sea salt aerosols (measured by the dry mass) due to wet processes", "dimensions": "longitude latitude time", "out_name": "wetss", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2157,16 +2247,17 @@ "ok_max_mean_abs": "" }, "zg": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "geopotential_height", "units": "m", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Geopotential Height", - "comment": "", + "comment": "Geopotential is the sum of the specific gravitational potential energy relative to the geoid and the specific centripetal potential energy. Geopotential height is the geopotential divided by the standard acceleration due to gravity. It is numerically similar to the altitude (or geometric height) and not to the quantity with standard name height, which is relative to the surface.", "dimensions": "longitude latitude alevel time", "out_name": "zg", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2174,16 +2265,17 @@ "ok_max_mean_abs": "" }, "ztp": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "tropopause_altitude", "units": "m", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Tropopause Altitude", + "long_name": "Tropopause Altitude Above Geoid", "comment": "2D monthly mean thermal tropopause calculated using WMO tropopause definition on 3d temperature", "dimensions": "longitude latitude time", "out_name": "ztp", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_AERmonZ.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_AERmonZ.json index 72d3136c20..e10901f3b2 100644 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_AERmonZ.json +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_AERmonZ.json @@ -1,30 +1,31 @@ { "Header": { - "data_specs_version": "01.00.10", + "data_specs_version": "01.00.30", + "cmor_version": "3.4", "table_id": "Table AERmonZ", "realm": "aerosol", - "frequency": "mon", - "cmor_version": "3.2", - "table_date": "10 May 2017", + "table_date": "11 March 2019", "missing_value": "1e20", + "int_missing_value": "-999", "product": "model-output", - "approx_interval": "", - "generic_levels": "", + "approx_interval": "30.00000", + "generic_levels": "alevel alevhalf", "mip_era": "CMIP6", - "Conventions": "CF-1.7 CMIP-6.0" + "Conventions": "CF-1.7 CMIP-6.2" }, "variable_entry": { "bry": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "mole_fraction_of_inorganic_bromine_in_air", "units": "mol mol-1", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", - "long_name": "Total inorganic bromine volume mixing ratio", - "comment": "Total family (the sum of all appropriate species in the model) ; list the species in the netCDF header, e.g. Bry = Br + BrO + HOBr + HBr + BrONO2 + BrCl Definition: Total inorganic bromine (e.g., HBr and inorganic bromine oxides and radicals (e.g., BrO, atomic bromine (Br), bromine nitrate (BrONO2)) resulting from degradation of bromine-containing organicsource gases (halons, methyl bromide, VSLS), and natural inorganic bromine sources (e.g., volcanoes, sea salt, and other aerosols) add comment attribute with detailed description about how the model calculates these fields", + "cell_measures": "", + "long_name": "Total Inorganic Bromine Volume Mixing Ratio", + "comment": "Total family (the sum of all appropriate species in the model) ; list the species in the netCDF header, e.g. Bry = Br + BrO + HOBr + HBr + BrONO2 + BrCl Definition: Total inorganic bromine (e.g., HBr and inorganic bromine oxides and radicals (e.g., BrO, atomic bromine (Br), bromine nitrate (BrONO2)) resulting from degradation of bromine-containing organic source gases (halons, methyl bromide, VSLS), and natural inorganic bromine sources (e.g., volcanoes, sea salt, and other aerosols) add comment attribute with detailed description about how the model calculates these fields", "dimensions": "latitude plev39 time", "out_name": "bry", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -32,16 +33,17 @@ "ok_max_mean_abs": "" }, "ch4": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "mole_fraction_of_methane_in_air", "units": "mol mol-1", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", - "long_name": "CH4 volume mixing ratio", - "comment": "", + "cell_measures": "", + "long_name": "Mole Fraction of CH4", + "comment": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", "dimensions": "latitude plev39 time", "out_name": "ch4", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -49,16 +51,17 @@ "ok_max_mean_abs": "" }, "cly": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "mole_fraction_of_inorganic_chlorine_in_air", "units": "mol mol-1", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", - "long_name": "Total inorganic chlorine volume mixing ratio", + "cell_measures": "", + "long_name": "Total Inorganic Chlorine Volume Mixing Ratio", "comment": "Total family (the sum of all appropriate species in the model) ; list the species in the netCDF header, e.g. Cly = HCl + ClONO2 + HOCl + ClO + Cl + 2*Cl2O2 +2Cl2 + OClO + BrCl Definition: Total inorganic stratospheric chlorine (e.g., HCl, ClO) resulting from degradation of chlorine-containing source gases (CFCs, HCFCs, VSLS), and natural inorganic chlorine sources (e.g., sea salt and other aerosols) add comment attribute with detailed description about how the model calculates these fields", "dimensions": "latitude plev39 time", "out_name": "cly", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -66,16 +69,17 @@ "ok_max_mean_abs": "" }, "h2o": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "mass_fraction_of_water_in_air", - "units": "1.0", + "units": "1", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", - "long_name": "H2O volume mixing ratio", + "cell_measures": "", + "long_name": "Mass Fraction of Water", "comment": "includes all phases of water", "dimensions": "latitude plev39 time", "out_name": "h2o", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -83,16 +87,17 @@ "ok_max_mean_abs": "" }, "hcl": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "mole_fraction_of_hydrogen_chloride_in_air", "units": "mol mol-1", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", - "long_name": "HCl volume mixing ratio", - "comment": "", + "cell_measures": "", + "long_name": "HCl Volume Mixing Ratio", + "comment": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. The chemical formula of hydrogen chloride is HCl.", "dimensions": "latitude plev39 time", "out_name": "hcl", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -100,16 +105,17 @@ "ok_max_mean_abs": "" }, "hno3": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "mole_fraction_of_nitric_acid_in_air", "units": "mol mol-1", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", - "long_name": "HNO3 volume mixing ratio", - "comment": "", + "cell_measures": "", + "long_name": "HNO3 Volume Mixing Ratio", + "comment": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", "dimensions": "latitude plev39 time", "out_name": "hno3", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -117,16 +123,17 @@ "ok_max_mean_abs": "" }, "ho2": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "mole_fraction_of_hydroperoxyl_radical_in_air", "units": "mol mol-1", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", - "long_name": "HO2 volume mixing ratio", - "comment": "", + "cell_measures": "", + "long_name": "HO2 Volume Mixing Ratio", + "comment": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. The chemical formula of hydroperoxyl radical is HO2.", "dimensions": "latitude plev39 time", "out_name": "ho2", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -134,16 +141,17 @@ "ok_max_mean_abs": "" }, "meanage": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "age_of_stratospheric_air", "units": "yr", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", + "cell_measures": "", "long_name": "Mean Age of Stratospheric Air", "comment": "The mean age of air is defined as the mean time that a stratospheric air mass has been out of contact with the well-mixed troposphere.", "dimensions": "latitude plev39 time", "out_name": "meanage", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -151,16 +159,17 @@ "ok_max_mean_abs": "" }, "n2o": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "mole_fraction_of_nitrous_oxide_in_air", "units": "mol mol-1", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", - "long_name": "N2O volume mixing ratio", - "comment": "", + "cell_measures": "", + "long_name": "Mole Fraction of N2O", + "comment": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. The chemical formula of nitrous oxide is N2O.", "dimensions": "latitude plev39 time", "out_name": "n2o", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -168,16 +177,17 @@ "ok_max_mean_abs": "" }, "noy": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "mole_fraction_of_noy_expressed_as_nitrogen_in_air", "units": "mol mol-1", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", - "long_name": "Total reactive nitrogen volume mixing ratio", + "cell_measures": "", + "long_name": "Total Reactive Nitrogen Volume Mixing Ratio", "comment": "Total family (the sum of all appropriate species in the model); list the species in the netCDF header, e.g. NOy = N + NO + NO2 + NO3 + HNO3 + 2N2O5 + HNO4 + ClONO2 + BrONO2 Definition: Total reactive nitrogen; usually includes atomic nitrogen (N), nitric oxide (NO), NO2, nitrogen trioxide (NO3), dinitrogen radical (N2O5), nitric acid (HNO3), peroxynitric acid (HNO4), BrONO2, ClONO2 add comment attribute with detailed description about how the model calculates these fields", "dimensions": "latitude plev39 time", "out_name": "noy", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -185,16 +195,17 @@ "ok_max_mean_abs": "" }, "o3": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "mole_fraction_of_ozone_in_air", "units": "mol mol-1", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", - "long_name": "Ozone volume mixing ratio", - "comment": "", + "cell_measures": "", + "long_name": "Mole Fraction of O3", + "comment": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", "dimensions": "latitude plev39 time", "out_name": "o3", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -202,16 +213,17 @@ "ok_max_mean_abs": "" }, "oh": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "mole_fraction_of_hydroxyl_radical_in_air", "units": "mol mol-1", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", - "long_name": "OH volume mixing ratio", - "comment": "", + "cell_measures": "", + "long_name": "OH Volume Mixing Ratio", + "comment": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", "dimensions": "latitude plev39 time", "out_name": "oh", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -219,16 +231,17 @@ "ok_max_mean_abs": "" }, "ta": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "air_temperature", "units": "K", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", + "cell_measures": "", "long_name": "Air Temperature", "comment": "Air Temperature", "dimensions": "latitude plev39 time", "out_name": "ta", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -236,16 +249,17 @@ "ok_max_mean_abs": "" }, "ua": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "eastward_wind", "units": "m s-1", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", + "cell_measures": "", "long_name": "Eastward Wind", - "comment": "", + "comment": "Zonal wind (positive in a eastward direction).", "dimensions": "latitude plev39 time", "out_name": "ua", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -253,16 +267,17 @@ "ok_max_mean_abs": "" }, "va": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "northward_wind", "units": "m s-1", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", + "cell_measures": "", "long_name": "Northward Wind", - "comment": "", + "comment": "Meridional wind (positive in a northward direction).", "dimensions": "latitude plev39 time", "out_name": "va", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -270,16 +285,17 @@ "ok_max_mean_abs": "" }, "vt100": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "northward_heat_flux_in_air_due_to_eddy_advection", "units": "W m-2", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", - "long_name": "Northward heat flux due to eddies", - "comment": "Zonally averaged meridional heat flux at 100 hPa as monthly means derived from daily (or higher frequency) fields.", + "cell_measures": "", + "long_name": "Northward Heat Flux Due to Eddies", + "comment": "Zonally averaged meridional heat flux at 100hPa as monthly means derived from daily (or higher frequency) fields.", "dimensions": "latitude time p100", "out_name": "vt100", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -287,16 +303,17 @@ "ok_max_mean_abs": "" }, "zg": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "geopotential_height", "units": "m", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", + "cell_measures": "", "long_name": "Geopotential Height", - "comment": "", + "comment": "Geopotential is the sum of the specific gravitational potential energy relative to the geoid and the specific centripetal potential energy. Geopotential height is the geopotential divided by the standard acceleration due to gravity. It is numerically similar to the altitude (or geometric height) and not to the quantity with standard name height, which is relative to the surface.", "dimensions": "latitude plev39 time", "out_name": "zg", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Amon.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Amon.json index 8d1eb4181b..9ea67aa6b9 100644 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Amon.json +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Amon.json @@ -1,20 +1,21 @@ { "Header": { - "data_specs_version": "01.00.10", + "data_specs_version": "01.00.30", + "cmor_version": "3.4", "table_id": "Table Amon", "realm": "atmos atmosChem", - "frequency": "mon", - "cmor_version": "3.2", - "table_date": "10 May 2017", + "table_date": "11 March 2019", "missing_value": "1e20", + "int_missing_value": "-999", "product": "model-output", "approx_interval": "30.00000", "generic_levels": "alevel alevhalf", "mip_era": "CMIP6", - "Conventions": "CF-1.7 CMIP-6.0" + "Conventions": "CF-1.7 CMIP-6.2" }, "variable_entry": { "ccb": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "air_pressure_at_convective_cloud_base", "units": "Pa", @@ -32,6 +33,7 @@ "ok_max_mean_abs": "" }, "cct": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "air_pressure_at_convective_cloud_top", "units": "Pa", @@ -49,13 +51,14 @@ "ok_max_mean_abs": "" }, "cfc113global": { + "frequency": "mon", "modeling_realm": "atmos atmosChem", "standard_name": "mole_fraction_of_cfc113_in_air", "units": "1e-12", "cell_methods": "area: time: mean", "cell_measures": "", "long_name": "Global Mean Mole Fraction of CFC113", - "comment": "", + "comment": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. The chemical formula of CFC113 is CCl2FCClF2. The IUPAC name for CFC113 is 1,1,2-trichloro-1,2,2-trifluoro-ethane.", "dimensions": "time", "out_name": "cfc113global", "type": "real", @@ -66,13 +69,14 @@ "ok_max_mean_abs": "" }, "cfc11global": { + "frequency": "mon", "modeling_realm": "atmos atmosChem", "standard_name": "mole_fraction_of_cfc11_in_air", "units": "1e-12", "cell_methods": "area: time: mean", "cell_measures": "", "long_name": "Global Mean Mole Fraction of CFC11", - "comment": "", + "comment": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. The chemical formula of CFC11 is CFCl3. The IUPAC name for CFC11 is trichloro-fluoro-methane.", "dimensions": "time", "out_name": "cfc11global", "type": "real", @@ -83,13 +87,14 @@ "ok_max_mean_abs": "" }, "cfc12global": { + "frequency": "mon", "modeling_realm": "atmos atmosChem", "standard_name": "mole_fraction_of_cfc12_in_air", "units": "1e-12", "cell_methods": "area: time: mean", "cell_measures": "", "long_name": "Global Mean Mole Fraction of CFC12", - "comment": "", + "comment": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. The chemical formula of CFC12 is CF2Cl2. The IUPAC name for CFC12 is dichloro-difluoro-methane.", "dimensions": "time", "out_name": "cfc12global", "type": "real", @@ -100,13 +105,14 @@ "ok_max_mean_abs": "" }, "ch4": { + "frequency": "mon", "modeling_realm": "atmos atmosChem", "standard_name": "mole_fraction_of_methane_in_air", "units": "mol mol-1", "cell_methods": "time: mean", "cell_measures": "area: areacella", "long_name": "Mole Fraction of CH4", - "comment": "", + "comment": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", "dimensions": "longitude latitude plev19 time", "out_name": "ch4", "type": "real", @@ -117,13 +123,14 @@ "ok_max_mean_abs": "" }, "ch4Clim": { + "frequency": "monC", "modeling_realm": "atmos atmosChem", "standard_name": "mole_fraction_of_methane_in_air", "units": "mol mol-1", "cell_methods": "area: mean time: mean within years time: mean over years", "cell_measures": "area: areacella", "long_name": "Mole Fraction of CH4", - "comment": "", + "comment": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", "dimensions": "longitude latitude plev19 time2", "out_name": "ch4", "type": "real", @@ -134,6 +141,7 @@ "ok_max_mean_abs": "" }, "ch4global": { + "frequency": "mon", "modeling_realm": "atmos atmosChem", "standard_name": "mole_fraction_of_methane_in_air", "units": "1e-09", @@ -151,6 +159,7 @@ "ok_max_mean_abs": "" }, "ch4globalClim": { + "frequency": "monC", "modeling_realm": "atmos atmosChem", "standard_name": "mole_fraction_of_methane_in_air", "units": "1e-09", @@ -168,12 +177,13 @@ "ok_max_mean_abs": "" }, "ci": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "convection_time_fraction", - "units": "1.0", + "units": "1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Fraction of Time Convection Occurs", + "long_name": "Fraction of Time Convection Occurs in Cell", "comment": "Fraction of time that convection occurs in the grid cell.", "dimensions": "longitude latitude time", "out_name": "ci", @@ -185,12 +195,13 @@ "ok_max_mean_abs": "" }, "cl": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "cloud_area_fraction_in_atmosphere_layer", "units": "%", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Cloud Area Fraction", + "long_name": "Percentage Cloud Cover", "comment": "Percentage cloud cover, including both large-scale and convective cloud.", "dimensions": "longitude latitude alevel time", "out_name": "cl", @@ -202,6 +213,7 @@ "ok_max_mean_abs": "" }, "cli": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "mass_fraction_of_cloud_ice_in_air", "units": "kg kg-1", @@ -219,8 +231,9 @@ "ok_max_mean_abs": "" }, "clivi": { + "frequency": "mon", "modeling_realm": "atmos", - "standard_name": "atmosphere_cloud_ice_content", + "standard_name": "atmosphere_mass_content_of_cloud_ice", "units": "kg m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", @@ -236,13 +249,14 @@ "ok_max_mean_abs": "" }, "clt": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "cloud_area_fraction", "units": "%", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Total Cloud Fraction", - "comment": "Total cloud area fraction for the whole atmospheric column, as seen from the surface or the top of the atmosphere. Includes both large-scale and convective cloud.", + "long_name": "Total Cloud Cover Percentage", + "comment": "Total cloud area fraction (reported as a percentage) for the whole atmospheric column, as seen from the surface or the top of the atmosphere. Includes both large-scale and convective cloud.", "dimensions": "longitude latitude time", "out_name": "clt", "type": "real", @@ -253,6 +267,7 @@ "ok_max_mean_abs": "" }, "clw": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "mass_fraction_of_cloud_liquid_water_in_air", "units": "kg kg-1", @@ -270,8 +285,9 @@ "ok_max_mean_abs": "" }, "clwvi": { + "frequency": "mon", "modeling_realm": "atmos", - "standard_name": "atmosphere_cloud_condensed_water_content", + "standard_name": "atmosphere_mass_content_of_cloud_condensed_water", "units": "kg m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", @@ -287,13 +303,14 @@ "ok_max_mean_abs": "" }, "co2": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "mole_fraction_of_carbon_dioxide_in_air", "units": "mol mol-1", "cell_methods": "time: mean", "cell_measures": "area: areacella", "long_name": "Mole Fraction of CO2", - "comment": "", + "comment": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", "dimensions": "longitude latitude plev19 time", "out_name": "co2", "type": "real", @@ -304,13 +321,14 @@ "ok_max_mean_abs": "" }, "co2Clim": { + "frequency": "monC", "modeling_realm": "atmos", "standard_name": "mole_fraction_of_carbon_dioxide_in_air", "units": "mol mol-1", "cell_methods": "area: mean time: mean within years time: mean over years", "cell_measures": "area: areacella", "long_name": "Mole Fraction of CO2", - "comment": "", + "comment": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", "dimensions": "longitude latitude plev19 time2", "out_name": "co2", "type": "real", @@ -321,6 +339,7 @@ "ok_max_mean_abs": "" }, "co2mass": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "atmosphere_mass_of_carbon_dioxide", "units": "kg", @@ -338,6 +357,7 @@ "ok_max_mean_abs": "" }, "co2massClim": { + "frequency": "monC", "modeling_realm": "atmos", "standard_name": "atmosphere_mass_of_carbon_dioxide", "units": "kg", @@ -355,13 +375,14 @@ "ok_max_mean_abs": "" }, "evspsbl": { + "frequency": "mon", "modeling_realm": "atmos", - "standard_name": "water_evaporation_flux", + "standard_name": "water_evapotranspiration_flux", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Evaporation", - "comment": "Evaporation at surface: flux of water into the atmosphere due to conversion of both liquid and solid phases to vapor (from underlying surface and vegetation)", + "long_name": "Evaporation Including Sublimation and Transpiration", + "comment": "Evaporation at surface (also known as evapotranspiration): flux of water into the atmosphere due to conversion of both liquid and solid phases to vapor (from underlying surface and vegetation)", "dimensions": "longitude latitude time", "out_name": "evspsbl", "type": "real", @@ -372,6 +393,7 @@ "ok_max_mean_abs": "" }, "fco2antt": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "tendency_of_atmosphere_mass_content_of_carbon_dioxide_expressed_as_carbon_due_to_anthropogenic_emission", "units": "kg m-2 s-1", @@ -382,13 +404,14 @@ "dimensions": "longitude latitude time", "out_name": "fco2antt", "type": "real", - "positive": "up", + "positive": "", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "fco2fos": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "tendency_of_atmosphere_mass_content_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_fossil_fuel_combustion", "units": "kg m-2 s-1", @@ -399,13 +422,14 @@ "dimensions": "longitude latitude time", "out_name": "fco2fos", "type": "real", - "positive": "up", + "positive": "", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "fco2nat": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_natural_sources", "units": "kg m-2 s-1", @@ -416,20 +440,21 @@ "dimensions": "longitude latitude time", "out_name": "fco2nat", "type": "real", - "positive": "up", + "positive": "", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "hcfc22global": { + "frequency": "mon", "modeling_realm": "atmos atmosChem", "standard_name": "mole_fraction_of_hcfc22_in_air", "units": "1e-12", "cell_methods": "area: time: mean", "cell_measures": "", "long_name": "Global Mean Mole Fraction of HCFC22", - "comment": "", + "comment": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for HCFC22 is CHClF2. The IUPAC name for HCFC22 is chloro-difluoro-methane.", "dimensions": "time", "out_name": "hcfc22global", "type": "real", @@ -440,13 +465,14 @@ "ok_max_mean_abs": "" }, "hfls": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "surface_upward_latent_heat_flux", "units": "W m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Surface Upward Latent Heat Flux", - "comment": "", + "comment": "The surface called 'surface' means the lower boundary of the atmosphere. 'Upward' indicates a vector component which is positive when directed upward (negative downward). The surface latent heat flux is the exchange of heat between the surface and the air on account of evaporation (including sublimation). In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions": "longitude latitude time", "out_name": "hfls", "type": "real", @@ -457,13 +483,14 @@ "ok_max_mean_abs": "" }, "hfss": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "surface_upward_sensible_heat_flux", "units": "W m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Surface Upward Sensible Heat Flux", - "comment": "", + "comment": "The surface sensible heat flux, also called turbulent heat flux, is the exchange of heat between the surface and the air by motion of air.", "dimensions": "longitude latitude time", "out_name": "hfss", "type": "real", @@ -474,6 +501,7 @@ "ok_max_mean_abs": "" }, "hur": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "relative_humidity", "units": "%", @@ -491,6 +519,7 @@ "ok_max_mean_abs": "" }, "hurs": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "relative_humidity", "units": "%", @@ -508,13 +537,14 @@ "ok_max_mean_abs": "" }, "hus": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "specific_humidity", - "units": "1.0", + "units": "1", "cell_methods": "time: mean", "cell_measures": "area: areacella", "long_name": "Specific Humidity", - "comment": "", + "comment": "Specific humidity is the mass fraction of water vapor in (moist) air.", "dimensions": "longitude latitude plev19 time", "out_name": "hus", "type": "real", @@ -525,9 +555,10 @@ "ok_max_mean_abs": "" }, "huss": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "specific_humidity", - "units": "1.0", + "units": "1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Near-Surface Specific Humidity", @@ -542,6 +573,7 @@ "ok_max_mean_abs": "" }, "mc": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "atmosphere_net_upward_convective_mass_flux", "units": "kg m-2 s-1", @@ -559,13 +591,14 @@ "ok_max_mean_abs": "" }, "n2o": { + "frequency": "mon", "modeling_realm": "atmos atmosChem", "standard_name": "mole_fraction_of_nitrous_oxide_in_air", "units": "mol mol-1", "cell_methods": "time: mean", "cell_measures": "area: areacella", "long_name": "Mole Fraction of N2O", - "comment": "", + "comment": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. The chemical formula of nitrous oxide is N2O.", "dimensions": "longitude latitude plev19 time", "out_name": "n2o", "type": "real", @@ -576,13 +609,14 @@ "ok_max_mean_abs": "" }, "n2oClim": { + "frequency": "monC", "modeling_realm": "atmos atmosChem", "standard_name": "mole_fraction_of_nitrous_oxide_in_air", "units": "mol mol-1", "cell_methods": "area: mean time: mean within years time: mean over years", "cell_measures": "area: areacella", "long_name": "Mole Fraction of N2O", - "comment": "", + "comment": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. The chemical formula of nitrous oxide is N2O.", "dimensions": "longitude latitude plev19 time2", "out_name": "n2o", "type": "real", @@ -593,6 +627,7 @@ "ok_max_mean_abs": "" }, "n2oglobal": { + "frequency": "mon", "modeling_realm": "atmos atmosChem", "standard_name": "mole_fraction_of_nitrous_oxide_in_air", "units": "1e-09", @@ -610,6 +645,7 @@ "ok_max_mean_abs": "" }, "n2oglobalClim": { + "frequency": "monC", "modeling_realm": "atmos atmosChem", "standard_name": "mole_fraction_of_nitrous_oxide_in_air", "units": "1e-09", @@ -627,13 +663,14 @@ "ok_max_mean_abs": "" }, "o3": { + "frequency": "mon", "modeling_realm": "atmos atmosChem", "standard_name": "mole_fraction_of_ozone_in_air", "units": "mol mol-1", "cell_methods": "time: mean", "cell_measures": "area: areacella", "long_name": "Mole Fraction of O3", - "comment": "", + "comment": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", "dimensions": "longitude latitude plev19 time", "out_name": "o3", "type": "real", @@ -644,13 +681,14 @@ "ok_max_mean_abs": "" }, "o3Clim": { + "frequency": "monC", "modeling_realm": "atmos atmosChem", "standard_name": "mole_fraction_of_ozone_in_air", "units": "mol mol-1", "cell_methods": "area: mean time: mean within years time: mean over years", "cell_measures": "area: areacella", "long_name": "Mole Fraction of O3", - "comment": "", + "comment": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", "dimensions": "longitude latitude plev19 time2", "out_name": "o3", "type": "real", @@ -661,12 +699,13 @@ "ok_max_mean_abs": "" }, "pfull": { + "frequency": "monC", "modeling_realm": "atmos", "standard_name": "air_pressure", "units": "Pa", "cell_methods": "area: mean time: mean within years time: mean over years", "cell_measures": "area: areacella", - "long_name": "Pressure on Model Levels", + "long_name": "Pressure at Model Full-Levels", "comment": "Air pressure on model levels", "dimensions": "longitude latitude alevel time2", "out_name": "pfull", @@ -678,6 +717,7 @@ "ok_max_mean_abs": "" }, "phalf": { + "frequency": "monC", "modeling_realm": "atmos", "standard_name": "air_pressure", "units": "Pa", @@ -695,6 +735,7 @@ "ok_max_mean_abs": "" }, "pr": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "precipitation_flux", "units": "kg m-2 s-1", @@ -712,6 +753,7 @@ "ok_max_mean_abs": "" }, "prc": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "convective_precipitation_flux", "units": "kg m-2 s-1", @@ -729,13 +771,14 @@ "ok_max_mean_abs": "" }, "prsn": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "snowfall_flux", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Snowfall Flux", - "comment": "at surface; includes precipitation of all forms of water in the solid phase", + "comment": "At surface; includes precipitation of all forms of water in the solid phase", "dimensions": "longitude latitude time", "out_name": "prsn", "type": "real", @@ -746,8 +789,9 @@ "ok_max_mean_abs": "" }, "prw": { + "frequency": "mon", "modeling_realm": "atmos", - "standard_name": "atmosphere_water_vapor_content", + "standard_name": "atmosphere_mass_content_of_water_vapor", "units": "kg m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", @@ -763,6 +807,7 @@ "ok_max_mean_abs": "" }, "ps": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "surface_air_pressure", "units": "Pa", @@ -780,8 +825,9 @@ "ok_max_mean_abs": "" }, "psl": { + "frequency": "mon", "modeling_realm": "atmos", - "standard_name": "air_pressure_at_sea_level", + "standard_name": "air_pressure_at_mean_sea_level", "units": "Pa", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", @@ -797,13 +843,14 @@ "ok_max_mean_abs": "" }, "rlds": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "surface_downwelling_longwave_flux_in_air", "units": "W m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Surface Downwelling Longwave Radiation", - "comment": "", + "comment": "The surface called 'surface' means the lower boundary of the atmosphere. 'longwave' means longwave radiation. Downwelling radiation is radiation from above. It does not mean 'net downward'. When thought of as being incident on a surface, a radiative flux is sometimes called 'irradiance'. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called 'vector irradiance'. In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions": "longitude latitude time", "out_name": "rlds", "type": "real", @@ -814,6 +861,7 @@ "ok_max_mean_abs": "" }, "rldscs": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "surface_downwelling_longwave_flux_in_air_assuming_clear_sky", "units": "W m-2", @@ -831,13 +879,14 @@ "ok_max_mean_abs": "" }, "rlus": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "surface_upwelling_longwave_flux_in_air", "units": "W m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Surface Upwelling Longwave Radiation", - "comment": "", + "comment": "The surface called 'surface' means the lower boundary of the atmosphere. 'longwave' means longwave radiation. Upwelling radiation is radiation from below. It does not mean 'net upward'. When thought of as being incident on a surface, a radiative flux is sometimes called 'irradiance'. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called 'vector irradiance'. In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions": "longitude latitude time", "out_name": "rlus", "type": "real", @@ -848,6 +897,7 @@ "ok_max_mean_abs": "" }, "rlut": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "toa_outgoing_longwave_flux", "units": "W m-2", @@ -865,13 +915,14 @@ "ok_max_mean_abs": "" }, "rlutcs": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "toa_outgoing_longwave_flux_assuming_clear_sky", "units": "W m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "TOA Outgoing Clear-Sky Longwave Radiation", - "comment": "", + "comment": "Upwelling clear-sky longwave radiation at top of atmosphere", "dimensions": "longitude latitude time", "out_name": "rlutcs", "type": "real", @@ -882,13 +933,14 @@ "ok_max_mean_abs": "" }, "rsds": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "surface_downwelling_shortwave_flux_in_air", "units": "W m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Surface Downwelling Shortwave Radiation", - "comment": "surface solar irradiance for UV calculations", + "comment": "Surface solar irradiance for UV calculations.", "dimensions": "longitude latitude time", "out_name": "rsds", "type": "real", @@ -899,13 +951,14 @@ "ok_max_mean_abs": "" }, "rsdscs": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "surface_downwelling_shortwave_flux_in_air_assuming_clear_sky", "units": "W m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Surface Downwelling Clear-Sky Shortwave Radiation", - "comment": "surface solar irradiance clear sky for UV calculations", + "comment": "Surface solar irradiance clear sky for UV calculations", "dimensions": "longitude latitude time", "out_name": "rsdscs", "type": "real", @@ -916,6 +969,7 @@ "ok_max_mean_abs": "" }, "rsdt": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "toa_incoming_shortwave_flux", "units": "W m-2", @@ -933,13 +987,14 @@ "ok_max_mean_abs": "" }, "rsus": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "surface_upwelling_shortwave_flux_in_air", "units": "W m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Surface Upwelling Shortwave Radiation", - "comment": "", + "comment": "The surface called 'surface' means the lower boundary of the atmosphere. 'shortwave' means shortwave radiation. Upwelling radiation is radiation from below. It does not mean 'net upward'. When thought of as being incident on a surface, a radiative flux is sometimes called 'irradiance'. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called 'vector irradiance'. In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions": "longitude latitude time", "out_name": "rsus", "type": "real", @@ -950,6 +1005,7 @@ "ok_max_mean_abs": "" }, "rsuscs": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "surface_upwelling_shortwave_flux_in_air_assuming_clear_sky", "units": "W m-2", @@ -967,6 +1023,7 @@ "ok_max_mean_abs": "" }, "rsut": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "toa_outgoing_shortwave_flux", "units": "W m-2", @@ -984,6 +1041,7 @@ "ok_max_mean_abs": "" }, "rsutcs": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "toa_outgoing_shortwave_flux_assuming_clear_sky", "units": "W m-2", @@ -1001,12 +1059,13 @@ "ok_max_mean_abs": "" }, "rtmt": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "net_downward_radiative_flux_at_top_of_atmosphere_model", "units": "W m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Net Downward Flux at Top of Model", + "long_name": "Net Downward Radiative Flux at Top of Model", "comment": "Net Downward Radiative Flux at Top of Model : I.e., at the top of that portion of the atmosphere where dynamics are explicitly treated by the model. This is reported only if it differs from the net downward radiative flux at the top of the atmosphere.", "dimensions": "longitude latitude time", "out_name": "rtmt", @@ -1018,8 +1077,9 @@ "ok_max_mean_abs": "" }, "sbl": { + "frequency": "mon", "modeling_realm": "landIce", - "standard_name": "surface_snow_and_ice_sublimation_flux", + "standard_name": "tendency_of_atmosphere_mass_content_of_water_vapor_due_to_sublimation_of_surface_snow_and_ice", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", @@ -1035,9 +1095,10 @@ "ok_max_mean_abs": "" }, "sci": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "shallow_convection_time_fraction", - "units": "1.0", + "units": "1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Fraction of Time Shallow Convection Occurs", @@ -1052,6 +1113,7 @@ "ok_max_mean_abs": "" }, "sfcWind": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "wind_speed", "units": "m s-1", @@ -1069,6 +1131,7 @@ "ok_max_mean_abs": "" }, "ta": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "air_temperature", "units": "K", @@ -1086,6 +1149,7 @@ "ok_max_mean_abs": "" }, "tas": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "air_temperature", "units": "K", @@ -1103,6 +1167,7 @@ "ok_max_mean_abs": "" }, "tasmax": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "air_temperature", "units": "K", @@ -1120,6 +1185,7 @@ "ok_max_mean_abs": "" }, "tasmin": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "air_temperature", "units": "K", @@ -1137,6 +1203,7 @@ "ok_max_mean_abs": "" }, "tauu": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "surface_downward_eastward_stress", "units": "Pa", @@ -1154,6 +1221,7 @@ "ok_max_mean_abs": "" }, "tauv": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "surface_downward_northward_stress", "units": "Pa", @@ -1171,6 +1239,7 @@ "ok_max_mean_abs": "" }, "ts": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "surface_temperature", "units": "K", @@ -1188,13 +1257,14 @@ "ok_max_mean_abs": "" }, "ua": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "eastward_wind", "units": "m s-1", "cell_methods": "time: mean", "cell_measures": "area: areacella", "long_name": "Eastward Wind", - "comment": "", + "comment": "Zonal wind (positive in a eastward direction).", "dimensions": "longitude latitude plev19 time", "out_name": "ua", "type": "real", @@ -1205,6 +1275,7 @@ "ok_max_mean_abs": "" }, "uas": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "eastward_wind", "units": "m s-1", @@ -1222,13 +1293,14 @@ "ok_max_mean_abs": "" }, "va": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "northward_wind", "units": "m s-1", "cell_methods": "time: mean", "cell_measures": "area: areacella", "long_name": "Northward Wind", - "comment": "", + "comment": "Meridional wind (positive in a northward direction).", "dimensions": "longitude latitude plev19 time", "out_name": "va", "type": "real", @@ -1239,6 +1311,7 @@ "ok_max_mean_abs": "" }, "vas": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "northward_wind", "units": "m s-1", @@ -1256,12 +1329,13 @@ "ok_max_mean_abs": "" }, "wap": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "lagrangian_tendency_of_air_pressure", "units": "Pa s-1", "cell_methods": "time: mean", "cell_measures": "area: areacella", - "long_name": "omega (=dp/dt)", + "long_name": "Omega (=dp/dt)", "comment": "Omega (vertical velocity in pressure coordinates, positive downwards)", "dimensions": "longitude latitude plev19 time", "out_name": "wap", @@ -1273,13 +1347,14 @@ "ok_max_mean_abs": "" }, "zg": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "geopotential_height", "units": "m", "cell_methods": "time: mean", "cell_measures": "area: areacella", "long_name": "Geopotential Height", - "comment": "", + "comment": "Geopotential is the sum of the specific gravitational potential energy relative to the geoid and the specific centripetal potential energy. Geopotential height is the geopotential divided by the standard acceleration due to gravity. It is numerically similar to the altitude (or geometric height) and not to the quantity with standard name height, which is relative to the surface.", "dimensions": "longitude latitude plev19 time", "out_name": "zg", "type": "real", diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_CF3hr.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_CF3hr.json index 21cc30a7d5..0be174a34b 100644 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_CF3hr.json +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_CF3hr.json @@ -1,26 +1,45 @@ { "Header": { - "data_specs_version": "01.00.10", + "data_specs_version": "01.00.30", + "cmor_version": "3.4", "table_id": "Table CF3hr", "realm": "atmos", - "frequency": "3hr", - "cmor_version": "3.2", - "table_date": "10 May 2017", + "table_date": "11 March 2019", "missing_value": "1e20", + "int_missing_value": "-999", "product": "model-output", "approx_interval": "0.125000", "generic_levels": "alevel alevhalf", "mip_era": "CMIP6", - "Conventions": "CF-1.7 CMIP-6.0" + "Conventions": "CF-1.7 CMIP-6.2" }, "variable_entry": { + "ci": { + "frequency": "3hrPt", + "modeling_realm": "atmos", + "standard_name": "convection_time_fraction", + "units": "1", + "cell_methods": "area: mean time: point", + "cell_measures": "area: areacella", + "long_name": "Fraction of Time Convection Occurs in Cell", + "comment": "Fraction of time that convection occurs in the grid cell.", + "dimensions": "longitude latitude time1", + "out_name": "ci", + "type": "real", + "positive": "", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, "clc": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "convective_cloud_area_fraction_in_atmosphere_layer", "units": "%", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "Convective Cloud Area Fraction", + "long_name": "Convective Cloud Area Percentage", "comment": "Include only convective cloud.", "dimensions": "longitude latitude alevel time1", "out_name": "clc", @@ -32,9 +51,10 @@ "ok_max_mean_abs": "" }, "clic": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "mass_fraction_of_convective_cloud_ice_in_air", - "units": "1.0", + "units": "1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", "long_name": "Mass Fraction of Convective Cloud Ice", @@ -49,9 +69,10 @@ "ok_max_mean_abs": "" }, "clis": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "mass_fraction_of_stratiform_cloud_ice_in_air", - "units": "1.0", + "units": "1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", "long_name": "Mass Fraction of Stratiform Cloud Ice", @@ -65,14 +86,33 @@ "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, + "clivi": { + "frequency": "3hrPt", + "modeling_realm": "atmos", + "standard_name": "atmosphere_mass_content_of_cloud_ice", + "units": "kg m-2", + "cell_methods": "area: mean time: point", + "cell_measures": "area: areacella", + "long_name": "Ice Water Path", + "comment": "mass of ice water in the column divided by the area of the column (not just the area of the cloudy portion of the column). Includes precipitating frozen hydrometeors ONLY if the precipitating hydrometeor affects the calculation of radiative transfer in model.", + "dimensions": "longitude latitude time1", + "out_name": "clivi", + "type": "real", + "positive": "", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, "cls": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "stratiform_cloud_area_fraction_in_atmosphere_layer", "units": "%", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "Stratiform Cloud Area Fraction", - "comment": "", + "long_name": "Percentage Cover of Stratiform Cloud", + "comment": "Cloud area fraction (reported as a percentage) for the whole atmospheric column due to stratiform clouds, as seen from the surface or the top of the atmosphere. Includes both large-scale and convective cloud.", "dimensions": "longitude latitude alevel time1", "out_name": "cls", "type": "real", @@ -82,14 +122,33 @@ "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, + "clt": { + "frequency": "3hrPt", + "modeling_realm": "atmos", + "standard_name": "cloud_area_fraction", + "units": "%", + "cell_methods": "area: mean time: point", + "cell_measures": "area: areacella", + "long_name": "Total Cloud Cover Percentage", + "comment": "Total cloud area fraction (reported as a percentage) for the whole atmospheric column, as seen from the surface or the top of the atmosphere. Includes both large-scale and convective cloud.", + "dimensions": "longitude latitude time1", + "out_name": "clt", + "type": "real", + "positive": "", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, "cltc": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "convective_cloud_area_fraction", "units": "%", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "Convective Cloud Fraction", - "comment": "Convective cloud area fraction for the whole atmospheric column, as seen from the surface or the top of the atmosphere. Includes only convective cloud.", + "long_name": "Convective Cloud Cover Percentage", + "comment": "Convective cloud area fraction (reported as a percentage) for the whole atmospheric column, as seen from the surface or the top of the atmosphere. Includes only convective cloud.", "dimensions": "longitude latitude time1", "out_name": "cltc", "type": "real", @@ -100,9 +159,10 @@ "ok_max_mean_abs": "" }, "clwc": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "mass_fraction_of_convective_cloud_liquid_water_in_air", - "units": "1.0", + "units": "1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", "long_name": "Mass Fraction of Convective Cloud Liquid Water", @@ -117,9 +177,10 @@ "ok_max_mean_abs": "" }, "clws": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "mass_fraction_of_stratiform_cloud_liquid_water_in_air", - "units": "1.0", + "units": "1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", "long_name": "Mass Fraction of Stratiform Cloud Liquid Water", @@ -133,10 +194,29 @@ "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, + "clwvi": { + "frequency": "3hrPt", + "modeling_realm": "atmos", + "standard_name": "atmosphere_mass_content_of_cloud_condensed_water", + "units": "kg m-2", + "cell_methods": "area: mean time: point", + "cell_measures": "area: areacella", + "long_name": "Condensed Water Path", + "comment": "Mass of condensed (liquid + ice) water in the column divided by the area of the column (not just the area of the cloudy portion of the column). Includes precipitating hydrometeors ONLY if the precipitating hydrometeors affect the calculation of radiative transfer in model.", + "dimensions": "longitude latitude time1", + "out_name": "clwvi", + "type": "real", + "positive": "", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, "demc": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "convective_cloud_longwave_emissivity", - "units": "1.0", + "units": "1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", "long_name": "Convective Cloud Emissivity", @@ -151,9 +231,10 @@ "ok_max_mean_abs": "" }, "dems": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "stratiform_cloud_longwave_emissivity", - "units": "1.0", + "units": "1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", "long_name": "Stratiform Cloud Emissivity", @@ -168,9 +249,10 @@ "ok_max_mean_abs": "" }, "dtauc": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "atmosphere_optical_thickness_due_to_convective_cloud", - "units": "1.0", + "units": "1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", "long_name": "Convective Cloud Optical Depth", @@ -185,9 +267,10 @@ "ok_max_mean_abs": "" }, "dtaus": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "atmosphere_optical_thickness_due_to_stratiform_cloud", - "units": "1.0", + "units": "1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", "long_name": "Stratiform Cloud Optical Depth", @@ -201,14 +284,33 @@ "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, + "evspsbl": { + "frequency": "3hrPt", + "modeling_realm": "atmos", + "standard_name": "water_evapotranspiration_flux", + "units": "kg m-2 s-1", + "cell_methods": "area: mean time: point", + "cell_measures": "area: areacella", + "long_name": "Evaporation Including Sublimation and Transpiration", + "comment": "Evaporation at surface (also known as evapotranspiration): flux of water into the atmosphere due to conversion of both liquid and solid phases to vapor (from underlying surface and vegetation)", + "dimensions": "longitude latitude time1", + "out_name": "evspsbl", + "type": "real", + "positive": "", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, "grpllsprof": { + "frequency": "3hrPt", "modeling_realm": "atmos", - "standard_name": "large_scale_graupel_flux", + "standard_name": "stratiform_graupel_flux", "units": "kg m-2 s-1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", "long_name": "Stratiform Graupel Flux", - "comment": "", + "comment": "In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. Stratiform precipitation, whether liquid or frozen, is precipitation that formed in stratiform cloud. Graupel consists of heavily rimed snow particles, often called snow pellets; often indistinguishable from very small soft hail except when the size convention that hail must have a diameter greater than 5 mm is adopted. Reference: American Meteorological Society Glossary http://glossary.ametsoc.org/wiki/Graupel. There are also separate standard names for hail. Standard names for 'graupel_and_hail' should be used to describe data produced by models that do not distinguish between hail and graupel.", "dimensions": "longitude latitude alevhalf time1", "out_name": "grpllsprof", "type": "real", @@ -219,9 +321,10 @@ "ok_max_mean_abs": "" }, "h2o": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "mass_fraction_of_water_in_air", - "units": "1.0", + "units": "1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", "long_name": "Mass Fraction of Water", @@ -235,7 +338,62 @@ "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, + "hfls": { + "frequency": "3hrPt", + "modeling_realm": "atmos", + "standard_name": "surface_upward_latent_heat_flux", + "units": "W m-2", + "cell_methods": "area: mean time: point", + "cell_measures": "area: areacella", + "long_name": "Surface Upward Latent Heat Flux", + "comment": "The surface called 'surface' means the lower boundary of the atmosphere. 'Upward' indicates a vector component which is positive when directed upward (negative downward). The surface latent heat flux is the exchange of heat between the surface and the air on account of evaporation (including sublimation). In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", + "dimensions": "longitude latitude time1", + "out_name": "hfls", + "type": "real", + "positive": "up", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, + "hfss": { + "frequency": "3hrPt", + "modeling_realm": "atmos", + "standard_name": "surface_upward_sensible_heat_flux", + "units": "W m-2", + "cell_methods": "area: mean time: point", + "cell_measures": "area: areacella", + "long_name": "Surface Upward Sensible Heat Flux", + "comment": "The surface sensible heat flux, also called turbulent heat flux, is the exchange of heat between the surface and the air by motion of air.", + "dimensions": "longitude latitude time1", + "out_name": "hfss", + "type": "real", + "positive": "up", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, + "hurs": { + "frequency": "3hrPt", + "modeling_realm": "atmos", + "standard_name": "relative_humidity", + "units": "%", + "cell_methods": "area: mean time: point", + "cell_measures": "area: areacella", + "long_name": "Near-Surface Relative Humidity", + "comment": "The relative humidity with respect to liquid water for T> 0 C, and with respect to ice for T<0 C.", + "dimensions": "longitude latitude time1 height2m", + "out_name": "hurs", + "type": "real", + "positive": "", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, "pfull": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "air_pressure", "units": "Pa", @@ -253,12 +411,13 @@ "ok_max_mean_abs": "" }, "phalf": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "air_pressure", "units": "Pa", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "Pressure at Model Half-Levels", + "long_name": "Pressure on Model Half-Levels", "comment": "Air pressure on model half-levels", "dimensions": "longitude latitude alevhalf time1", "out_name": "phalf", @@ -269,14 +428,51 @@ "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, + "pr": { + "frequency": "3hrPt", + "modeling_realm": "atmos", + "standard_name": "precipitation_flux", + "units": "kg m-2 s-1", + "cell_methods": "area: mean time: point", + "cell_measures": "area: areacella", + "long_name": "Precipitation", + "comment": "includes both liquid and solid phases", + "dimensions": "longitude latitude time1", + "out_name": "pr", + "type": "real", + "positive": "", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, + "prc": { + "frequency": "3hrPt", + "modeling_realm": "atmos", + "standard_name": "convective_precipitation_flux", + "units": "kg m-2 s-1", + "cell_methods": "area: mean time: point", + "cell_measures": "area: areacella", + "long_name": "Convective Precipitation", + "comment": "Convective precipitation at surface; includes both liquid and solid phases.", + "dimensions": "longitude latitude time1", + "out_name": "prc", + "type": "real", + "positive": "", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, "prcprof": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "convective_rainfall_flux", "units": "kg m-2 s-1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", "long_name": "Convective Rainfall Flux", - "comment": "", + "comment": "In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions": "longitude latitude alevhalf time1", "out_name": "prcprof", "type": "real", @@ -287,8 +483,9 @@ "ok_max_mean_abs": "" }, "prlsns": { + "frequency": "3hrPt", "modeling_realm": "atmos", - "standard_name": "large_scale_snowfall_flux", + "standard_name": "stratiform_snowfall_flux", "units": "kg m-2 s-1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", @@ -304,13 +501,14 @@ "ok_max_mean_abs": "" }, "prlsprof": { + "frequency": "3hrPt", "modeling_realm": "atmos", - "standard_name": "large_scale_rainfall_flux", + "standard_name": "stratiform_rainfall_flux", "units": "kg m-2 s-1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", "long_name": "Stratiform Rainfall Flux", - "comment": "", + "comment": "In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. Stratiform precipitation, whether liquid or frozen, is precipitation that formed in stratiform cloud.", "dimensions": "longitude latitude alevhalf time1", "out_name": "prlsprof", "type": "real", @@ -320,7 +518,26 @@ "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, + "prsn": { + "frequency": "3hrPt", + "modeling_realm": "atmos", + "standard_name": "snowfall_flux", + "units": "kg m-2 s-1", + "cell_methods": "area: mean time: point", + "cell_measures": "area: areacella", + "long_name": "Snowfall Flux", + "comment": "At surface; includes precipitation of all forms of water in the solid phase", + "dimensions": "longitude latitude time1", + "out_name": "prsn", + "type": "real", + "positive": "", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, "prsnc": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "convective_snowfall_flux", "units": "kg m-2 s-1", @@ -337,17 +554,54 @@ "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, + "prw": { + "frequency": "3hrPt", + "modeling_realm": "atmos", + "standard_name": "atmosphere_mass_content_of_water_vapor", + "units": "kg m-2", + "cell_methods": "area: mean time: point", + "cell_measures": "area: areacella", + "long_name": "Water Vapor Path", + "comment": "vertically integrated through the atmospheric column", + "dimensions": "longitude latitude time1", + "out_name": "prw", + "type": "real", + "positive": "", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, "ps": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "surface_air_pressure", "units": "Pa", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "Surface Pressure", + "long_name": "Surface Air Pressure", "comment": "surface pressure (not mean sea-level pressure), 2-D field to calculate the 3-D pressure field from hybrid coordinates", "dimensions": "longitude latitude time1", "out_name": "ps", - "type": "float", + "type": "real", + "positive": "", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, + "psl": { + "frequency": "3hrPt", + "modeling_realm": "atmos", + "standard_name": "air_pressure_at_mean_sea_level", + "units": "Pa", + "cell_methods": "area: mean time: point", + "cell_measures": "area: areacella", + "long_name": "Sea Level Pressure", + "comment": "Sea Level Pressure", + "dimensions": "longitude latitude time1", + "out_name": "psl", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -355,6 +609,7 @@ "ok_max_mean_abs": "" }, "reffclic": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "effective_radius_of_convective_cloud_ice_particle", "units": "m", @@ -372,6 +627,7 @@ "ok_max_mean_abs": "" }, "reffclis": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "effective_radius_of_stratiform_cloud_ice_particle", "units": "m", @@ -389,12 +645,13 @@ "ok_max_mean_abs": "" }, "reffclwc": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "effective_radius_of_convective_cloud_liquid_water_particle", "units": "m", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "Hydrometeor Effective Radius of Convective Cloud Liquid Water", + "long_name": "Convective Cloud Liquid Droplet Effective Radius", "comment": "Droplets are liquid. The effective radius is defined as the ratio of the third moment over the second moment of the particle size distribution and the time-mean should be calculated, weighting the individual samples by the cloudy fraction of the grid cell.", "dimensions": "longitude latitude alevel time1", "out_name": "reffclwc", @@ -406,12 +663,13 @@ "ok_max_mean_abs": "" }, "reffclws": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "effective_radius_of_stratiform_cloud_liquid_water_particle", "units": "m", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "Hydrometeor Effective Radius of Stratiform Cloud Liquid Water", + "long_name": "Stratiform Cloud Liquid Droplet Effective Radius", "comment": "Droplets are liquid. The effective radius is defined as the ratio of the third moment over the second moment of the particle size distribution and the time-mean should be calculated, weighting the individual samples by the cloudy fraction of the grid cell.", "dimensions": "longitude latitude alevel time1", "out_name": "reffclws", @@ -423,6 +681,7 @@ "ok_max_mean_abs": "" }, "reffgrpls": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "effective_radius_of_stratiform_cloud_graupel_particle", "units": "m", @@ -440,6 +699,7 @@ "ok_max_mean_abs": "" }, "reffrainc": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "effective_radius_of_convective_cloud_rain_particle", "units": "m", @@ -457,6 +717,7 @@ "ok_max_mean_abs": "" }, "reffrains": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "effective_radius_of_stratiform_cloud_rain_particle", "units": "m", @@ -474,6 +735,7 @@ "ok_max_mean_abs": "" }, "reffsnowc": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "effective_radius_of_convective_cloud_snow_particle", "units": "m", @@ -491,6 +753,7 @@ "ok_max_mean_abs": "" }, "reffsnows": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "effective_radius_of_stratiform_cloud_snow_particle", "units": "m", @@ -507,7 +770,296 @@ "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, + "rlds": { + "frequency": "3hrPt", + "modeling_realm": "atmos", + "standard_name": "surface_downwelling_longwave_flux_in_air", + "units": "W m-2", + "cell_methods": "area: mean time: point", + "cell_measures": "area: areacella", + "long_name": "Surface Downwelling Longwave Radiation", + "comment": "The surface called 'surface' means the lower boundary of the atmosphere. 'longwave' means longwave radiation. Downwelling radiation is radiation from above. It does not mean 'net downward'. When thought of as being incident on a surface, a radiative flux is sometimes called 'irradiance'. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called 'vector irradiance'. In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", + "dimensions": "longitude latitude time1", + "out_name": "rlds", + "type": "real", + "positive": "down", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, + "rldscs": { + "frequency": "3hrPt", + "modeling_realm": "atmos", + "standard_name": "surface_downwelling_longwave_flux_in_air_assuming_clear_sky", + "units": "W m-2", + "cell_methods": "area: mean time: point", + "cell_measures": "area: areacella", + "long_name": "Surface Downwelling Clear-Sky Longwave Radiation", + "comment": "Surface downwelling clear-sky longwave radiation", + "dimensions": "longitude latitude time1", + "out_name": "rldscs", + "type": "real", + "positive": "down", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, + "rlus": { + "frequency": "3hrPt", + "modeling_realm": "atmos", + "standard_name": "surface_upwelling_longwave_flux_in_air", + "units": "W m-2", + "cell_methods": "area: mean time: point", + "cell_measures": "area: areacella", + "long_name": "Surface Upwelling Longwave Radiation", + "comment": "The surface called 'surface' means the lower boundary of the atmosphere. 'longwave' means longwave radiation. Upwelling radiation is radiation from below. It does not mean 'net upward'. When thought of as being incident on a surface, a radiative flux is sometimes called 'irradiance'. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called 'vector irradiance'. In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", + "dimensions": "longitude latitude time1", + "out_name": "rlus", + "type": "real", + "positive": "up", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, + "rlut": { + "frequency": "3hrPt", + "modeling_realm": "atmos", + "standard_name": "toa_outgoing_longwave_flux", + "units": "W m-2", + "cell_methods": "area: mean time: point", + "cell_measures": "area: areacella", + "long_name": "TOA Outgoing Longwave Radiation", + "comment": "at the top of the atmosphere (to be compared with satellite measurements)", + "dimensions": "longitude latitude time1", + "out_name": "rlut", + "type": "real", + "positive": "up", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, + "rlutcs": { + "frequency": "3hrPt", + "modeling_realm": "atmos", + "standard_name": "toa_outgoing_longwave_flux_assuming_clear_sky", + "units": "W m-2", + "cell_methods": "area: mean time: point", + "cell_measures": "area: areacella", + "long_name": "TOA Outgoing Clear-Sky Longwave Radiation", + "comment": "Upwelling clear-sky longwave radiation at top of atmosphere", + "dimensions": "longitude latitude time1", + "out_name": "rlutcs", + "type": "real", + "positive": "up", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, + "rsds": { + "frequency": "3hrPt", + "modeling_realm": "atmos", + "standard_name": "surface_downwelling_shortwave_flux_in_air", + "units": "W m-2", + "cell_methods": "area: mean time: point", + "cell_measures": "area: areacella", + "long_name": "Surface Downwelling Shortwave Radiation", + "comment": "Surface solar irradiance for UV calculations.", + "dimensions": "longitude latitude time1", + "out_name": "rsds", + "type": "real", + "positive": "down", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, + "rsdscs": { + "frequency": "3hrPt", + "modeling_realm": "atmos", + "standard_name": "surface_downwelling_shortwave_flux_in_air_assuming_clear_sky", + "units": "W m-2", + "cell_methods": "area: mean time: point", + "cell_measures": "area: areacella", + "long_name": "Surface Downwelling Clear-Sky Shortwave Radiation", + "comment": "Surface solar irradiance clear sky for UV calculations", + "dimensions": "longitude latitude time1", + "out_name": "rsdscs", + "type": "real", + "positive": "down", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, + "rsdt": { + "frequency": "3hrPt", + "modeling_realm": "atmos", + "standard_name": "toa_incoming_shortwave_flux", + "units": "W m-2", + "cell_methods": "area: mean time: point", + "cell_measures": "area: areacella", + "long_name": "TOA Incident Shortwave Radiation", + "comment": "Shortwave radiation incident at the top of the atmosphere", + "dimensions": "longitude latitude time1", + "out_name": "rsdt", + "type": "real", + "positive": "down", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, + "rsus": { + "frequency": "3hrPt", + "modeling_realm": "atmos", + "standard_name": "surface_upwelling_shortwave_flux_in_air", + "units": "W m-2", + "cell_methods": "area: mean time: point", + "cell_measures": "area: areacella", + "long_name": "Surface Upwelling Shortwave Radiation", + "comment": "The surface called 'surface' means the lower boundary of the atmosphere. 'shortwave' means shortwave radiation. Upwelling radiation is radiation from below. It does not mean 'net upward'. When thought of as being incident on a surface, a radiative flux is sometimes called 'irradiance'. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called 'vector irradiance'. In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", + "dimensions": "longitude latitude time1", + "out_name": "rsus", + "type": "real", + "positive": "up", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, + "rsuscs": { + "frequency": "3hrPt", + "modeling_realm": "atmos", + "standard_name": "surface_upwelling_shortwave_flux_in_air_assuming_clear_sky", + "units": "W m-2", + "cell_methods": "area: mean time: point", + "cell_measures": "area: areacella", + "long_name": "Surface Upwelling Clear-Sky Shortwave Radiation", + "comment": "Surface Upwelling Clear-sky Shortwave Radiation", + "dimensions": "longitude latitude time1", + "out_name": "rsuscs", + "type": "real", + "positive": "up", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, + "rsut": { + "frequency": "3hrPt", + "modeling_realm": "atmos", + "standard_name": "toa_outgoing_shortwave_flux", + "units": "W m-2", + "cell_methods": "area: mean time: point", + "cell_measures": "area: areacella", + "long_name": "TOA Outgoing Shortwave Radiation", + "comment": "at the top of the atmosphere", + "dimensions": "longitude latitude time1", + "out_name": "rsut", + "type": "real", + "positive": "up", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, + "rsutcs": { + "frequency": "3hrPt", + "modeling_realm": "atmos", + "standard_name": "toa_outgoing_shortwave_flux_assuming_clear_sky", + "units": "W m-2", + "cell_methods": "area: mean time: point", + "cell_measures": "area: areacella", + "long_name": "TOA Outgoing Clear-Sky Shortwave Radiation", + "comment": "Calculated in the absence of clouds.", + "dimensions": "longitude latitude time1", + "out_name": "rsutcs", + "type": "real", + "positive": "up", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, + "rtmt": { + "frequency": "3hrPt", + "modeling_realm": "atmos", + "standard_name": "net_downward_radiative_flux_at_top_of_atmosphere_model", + "units": "W m-2", + "cell_methods": "area: mean time: point", + "cell_measures": "area: areacella", + "long_name": "Net Downward Radiative Flux at Top of Model", + "comment": "Net Downward Radiative Flux at Top of Model : I.e., at the top of that portion of the atmosphere where dynamics are explicitly treated by the model. This is reported only if it differs from the net downward radiative flux at the top of the atmosphere.", + "dimensions": "longitude latitude time1", + "out_name": "rtmt", + "type": "real", + "positive": "down", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, + "sbl": { + "frequency": "3hrPt", + "modeling_realm": "landIce", + "standard_name": "tendency_of_atmosphere_mass_content_of_water_vapor_due_to_sublimation_of_surface_snow_and_ice", + "units": "kg m-2 s-1", + "cell_methods": "area: mean time: point", + "cell_measures": "area: areacella", + "long_name": "Surface Snow and Ice Sublimation Flux", + "comment": "The snow and ice sublimation flux is the loss of snow and ice mass per unit area from the surface resulting from their direct conversion to water vapor that enters the atmosphere.", + "dimensions": "longitude latitude time1", + "out_name": "sbl", + "type": "real", + "positive": "", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, + "sci": { + "frequency": "3hrPt", + "modeling_realm": "atmos", + "standard_name": "shallow_convection_time_fraction", + "units": "1", + "cell_methods": "area: mean time: point", + "cell_measures": "area: areacella", + "long_name": "Fraction of Time Shallow Convection Occurs", + "comment": "Fraction of time that shallow convection occurs in the grid cell.", + "dimensions": "longitude latitude time1", + "out_name": "sci", + "type": "real", + "positive": "", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, + "sfcWind": { + "frequency": "3hrPt", + "modeling_realm": "atmos", + "standard_name": "wind_speed", + "units": "m s-1", + "cell_methods": "area: mean time: point", + "cell_measures": "area: areacella", + "long_name": "Near-Surface Wind Speed", + "comment": "near-surface (usually, 10 meters) wind speed.", + "dimensions": "longitude latitude time1 height10m", + "out_name": "sfcWind", + "type": "real", + "positive": "", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, "ta": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "air_temperature", "units": "K", @@ -524,14 +1076,69 @@ "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, + "tauu": { + "frequency": "3hrPt", + "modeling_realm": "atmos", + "standard_name": "surface_downward_eastward_stress", + "units": "Pa", + "cell_methods": "area: mean time: point", + "cell_measures": "area: areacella", + "long_name": "Surface Downward Eastward Wind Stress", + "comment": "Downward eastward wind stress at the surface", + "dimensions": "longitude latitude time1", + "out_name": "tauu", + "type": "real", + "positive": "down", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, + "tauv": { + "frequency": "3hrPt", + "modeling_realm": "atmos", + "standard_name": "surface_downward_northward_stress", + "units": "Pa", + "cell_methods": "area: mean time: point", + "cell_measures": "area: areacella", + "long_name": "Surface Downward Northward Wind Stress", + "comment": "Downward northward wind stress at the surface", + "dimensions": "longitude latitude time1", + "out_name": "tauv", + "type": "real", + "positive": "down", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, + "ts": { + "frequency": "3hrPt", + "modeling_realm": "atmos", + "standard_name": "surface_temperature", + "units": "K", + "cell_methods": "area: mean time: point", + "cell_measures": "area: areacella", + "long_name": "Surface Temperature", + "comment": "Temperature of the lower boundary of the atmosphere", + "dimensions": "longitude latitude time1", + "out_name": "ts", + "type": "real", + "positive": "", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, "zfull": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "height_above_reference_ellipsoid", "units": "m", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", "long_name": "Altitude of Model Full-Levels", - "comment": "", + "comment": "Height of full model levels above a reference ellipsoid. A reference ellipsoid is a mathematical figure that approximates the geoid. The geoid is a surface of constant geopotential with which mean sea level would coincide if the ocean were at rest. The ellipsoid is an approximation because the geoid is an irregular shape. A number of reference ellipsoids are defined for use in the field of geodesy. To specify which reference ellipsoid is being used, a grid_mapping variable should be attached to the data variable as described in Chapter 5.6 of the CF Convention.", "dimensions": "longitude latitude alevel time1", "out_name": "zfull", "type": "real", @@ -542,13 +1149,14 @@ "ok_max_mean_abs": "" }, "zhalf": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "height_above_reference_ellipsoid", "units": "m", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", "long_name": "Altitude of Model Half-Levels", - "comment": "", + "comment": "Height of model half-levels above a reference ellipsoid. A reference ellipsoid is a mathematical figure that approximates the geoid. The geoid is a surface of constant geopotential with which mean sea level would coincide if the ocean were at rest. The ellipsoid is an approximation because the geoid is an irregular shape. A number of reference ellipsoids are defined for use in the field of geodesy. To specify which reference ellipsoid is being used, a grid_mapping variable should be attached to the data variable as described in Chapter 5.6 of the CF Convention.", "dimensions": "longitude latitude alevhalf time1", "out_name": "zhalf", "type": "real", diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_CFday.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_CFday.json index 7c47abcca1..fb7512436f 100644 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_CFday.json +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_CFday.json @@ -1,23 +1,24 @@ { "Header": { - "data_specs_version": "01.00.10", + "data_specs_version": "01.00.30", + "cmor_version": "3.4", "table_id": "Table CFday", "realm": "atmos", - "frequency": "day", - "cmor_version": "3.2", - "table_date": "10 May 2017", + "table_date": "11 March 2019", "missing_value": "1e20", + "int_missing_value": "-999", "product": "model-output", "approx_interval": "1.00000", "generic_levels": "alevel alevhalf", "mip_era": "CMIP6", - "Conventions": "CF-1.7 CMIP-6.0" + "Conventions": "CF-1.7 CMIP-6.2" }, "variable_entry": { "albisccp": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "cloud_albedo", - "units": "1.0", + "units": "1", "cell_methods": "area: time: mean where cloud", "cell_measures": "area: areacella", "long_name": "ISCCP Mean Cloud Albedo", @@ -32,6 +33,7 @@ "ok_max_mean_abs": "" }, "ccb": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "air_pressure_at_convective_cloud_base", "units": "Pa", @@ -49,6 +51,7 @@ "ok_max_mean_abs": "" }, "cct": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "air_pressure_at_convective_cloud_top", "units": "Pa", @@ -66,12 +69,13 @@ "ok_max_mean_abs": "" }, "cl": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "cloud_area_fraction_in_atmosphere_layer", "units": "%", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Cloud Area Fraction in Atmosphere Layer", + "long_name": "Percentage Cloud Cover", "comment": "Percentage cloud cover, including both large-scale and convective cloud.", "dimensions": "longitude latitude alevel time", "out_name": "cl", @@ -83,13 +87,14 @@ "ok_max_mean_abs": "" }, "clcalipso": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "cloud_area_fraction_in_atmosphere_layer", "units": "%", "cell_methods": "time: mean", "cell_measures": "area: areacella", - "long_name": "CALIPSO Cloud Fraction", - "comment": "Percentage cloud cover at CALIPSO standard heights.", + "long_name": "CALIPSO Percentage Cloud Cover", + "comment": "Percentage cloud cover in CALIPSO standard atmospheric layers.", "dimensions": "longitude latitude alt40 time", "out_name": "clcalipso", "type": "real", @@ -100,12 +105,13 @@ "ok_max_mean_abs": "" }, "clhcalipso": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "cloud_area_fraction_in_atmosphere_layer", "units": "%", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "CALIPSO High Level Cloud Fraction", + "long_name": "CALIPSO High Level Cloud Area Percentage", "comment": "Percentage cloud cover in layer centred on 220hPa", "dimensions": "longitude latitude time p220", "out_name": "clhcalipso", @@ -117,6 +123,7 @@ "ok_max_mean_abs": "" }, "cli": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "mass_fraction_of_cloud_ice_in_air", "units": "kg kg-1", @@ -134,12 +141,13 @@ "ok_max_mean_abs": "" }, "clisccp": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "cloud_area_fraction_in_atmosphere_layer", "units": "%", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "ISCCP Cloud Area Fraction", + "long_name": "ISCCP Cloud Area Percentage", "comment": "Percentage cloud cover in optical depth categories.", "dimensions": "longitude latitude plev7c tau time", "out_name": "clisccp", @@ -151,8 +159,9 @@ "ok_max_mean_abs": "" }, "clivi": { + "frequency": "day", "modeling_realm": "atmos", - "standard_name": "atmosphere_cloud_ice_content", + "standard_name": "atmosphere_mass_content_of_cloud_ice", "units": "kg m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", @@ -168,12 +177,13 @@ "ok_max_mean_abs": "" }, "cllcalipso": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "cloud_area_fraction_in_atmosphere_layer", "units": "%", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "CALIPSO Low Level Cloud Fraction", + "long_name": "CALIPSO Low Level Cloud Cover Percentage", "comment": "Percentage cloud cover in layer centred on 840hPa", "dimensions": "longitude latitude time p840", "out_name": "cllcalipso", @@ -185,12 +195,13 @@ "ok_max_mean_abs": "" }, "clmcalipso": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "cloud_area_fraction_in_atmosphere_layer", "units": "%", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "CALIPSO Mid Level Cloud Fraction", + "long_name": "CALIPSO Mid Level Cloud Cover Percentage", "comment": "Percentage cloud cover in layer centred on 560hPa", "dimensions": "longitude latitude time p560", "out_name": "clmcalipso", @@ -202,13 +213,14 @@ "ok_max_mean_abs": "" }, "cltcalipso": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "cloud_area_fraction", "units": "%", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "CALIPSO Total Cloud Fraction", - "comment": "", + "long_name": "CALIPSO Total Cloud Cover Percentage", + "comment": "Total cloud area fraction (reported as a percentage) for the whole atmospheric column, as seen by the Cloud-Aerosol Lidar and Infrared Pathfinder Satellite Observation (CALIPSO) instrument. Includes both large-scale and convective cloud.", "dimensions": "longitude latitude time", "out_name": "cltcalipso", "type": "real", @@ -219,13 +231,14 @@ "ok_max_mean_abs": "" }, "cltisccp": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "cloud_area_fraction", "units": "%", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "ISCCP Total Total Cloud Fraction", - "comment": "Percentage total cloud cover, simulating ISCCP observations.", + "long_name": "ISCCP Total Cloud Cover Percentage", + "comment": "Total cloud area fraction (reported as a percentage) for the whole atmospheric column, as seen by the International Satellite Cloud Climatology Project (ISCCP) analysis. Includes both large-scale and convective cloud. (MODIS). Includes both large-scale and convective cloud.", "dimensions": "longitude latitude time", "out_name": "cltisccp", "type": "real", @@ -236,6 +249,7 @@ "ok_max_mean_abs": "" }, "clw": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "mass_fraction_of_cloud_liquid_water_in_air", "units": "kg kg-1", @@ -253,8 +267,9 @@ "ok_max_mean_abs": "" }, "clwvi": { + "frequency": "day", "modeling_realm": "atmos", - "standard_name": "atmosphere_cloud_condensed_water_content", + "standard_name": "atmosphere_mass_content_of_cloud_condensed_water", "units": "kg m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", @@ -270,6 +285,7 @@ "ok_max_mean_abs": "" }, "hur": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "relative_humidity", "units": "%", @@ -287,13 +303,14 @@ "ok_max_mean_abs": "" }, "hus": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "specific_humidity", - "units": "1.0", + "units": "1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Specific Humidity", - "comment": "", + "comment": "Specific humidity is the mass fraction of water vapor in (moist) air.", "dimensions": "longitude latitude alevel time", "out_name": "hus", "type": "real", @@ -304,6 +321,7 @@ "ok_max_mean_abs": "" }, "mc": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "atmosphere_net_upward_convective_mass_flux", "units": "kg m-2 s-1", @@ -321,6 +339,7 @@ "ok_max_mean_abs": "" }, "pctisccp": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "air_pressure_at_cloud_top", "units": "Pa", @@ -338,12 +357,13 @@ "ok_max_mean_abs": "" }, "pfull": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "air_pressure", "units": "Pa", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Pressure on Model Levels", + "long_name": "Pressure at Model Full-Levels", "comment": "Air pressure on model levels", "dimensions": "longitude latitude alevel time", "out_name": "pfull", @@ -355,6 +375,7 @@ "ok_max_mean_abs": "" }, "phalf": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "air_pressure", "units": "Pa", @@ -372,6 +393,7 @@ "ok_max_mean_abs": "" }, "ps": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "surface_air_pressure", "units": "Pa", @@ -389,6 +411,7 @@ "ok_max_mean_abs": "" }, "rldscs": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "surface_downwelling_longwave_flux_in_air_assuming_clear_sky", "units": "W m-2", @@ -406,13 +429,14 @@ "ok_max_mean_abs": "" }, "rlutcs": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "toa_outgoing_longwave_flux_assuming_clear_sky", "units": "W m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "TOA Outgoing Clear-Sky Longwave Radiation", - "comment": "", + "comment": "Upwelling clear-sky longwave radiation at top of atmosphere", "dimensions": "longitude latitude time", "out_name": "rlutcs", "type": "real", @@ -423,13 +447,14 @@ "ok_max_mean_abs": "" }, "rsdscs": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "surface_downwelling_shortwave_flux_in_air_assuming_clear_sky", "units": "W m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Surface Downwelling Clear-Sky Shortwave Radiation", - "comment": "surface solar irradiance clear sky for UV calculations", + "comment": "Surface solar irradiance clear sky for UV calculations", "dimensions": "longitude latitude time", "out_name": "rsdscs", "type": "real", @@ -440,6 +465,7 @@ "ok_max_mean_abs": "" }, "rsdt": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "toa_incoming_shortwave_flux", "units": "W m-2", @@ -457,6 +483,7 @@ "ok_max_mean_abs": "" }, "rsuscs": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "surface_upwelling_shortwave_flux_in_air_assuming_clear_sky", "units": "W m-2", @@ -474,6 +501,7 @@ "ok_max_mean_abs": "" }, "rsut": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "toa_outgoing_shortwave_flux", "units": "W m-2", @@ -491,6 +519,7 @@ "ok_max_mean_abs": "" }, "rsutcs": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "toa_outgoing_shortwave_flux_assuming_clear_sky", "units": "W m-2", @@ -508,6 +537,7 @@ "ok_max_mean_abs": "" }, "ta": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "air_temperature", "units": "K", @@ -525,6 +555,7 @@ "ok_max_mean_abs": "" }, "ta700": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "air_temperature", "units": "K", @@ -542,13 +573,14 @@ "ok_max_mean_abs": "" }, "ua": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "eastward_wind", "units": "m s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Eastward Wind", - "comment": "", + "comment": "Zonal wind (positive in a eastward direction).", "dimensions": "longitude latitude alevel time", "out_name": "ua", "type": "real", @@ -559,13 +591,14 @@ "ok_max_mean_abs": "" }, "va": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "northward_wind", "units": "m s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Northward Wind", - "comment": "", + "comment": "Meridional wind (positive in a northward direction).", "dimensions": "longitude latitude alevel time", "out_name": "va", "type": "real", @@ -576,12 +609,13 @@ "ok_max_mean_abs": "" }, "wap": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "lagrangian_tendency_of_air_pressure", "units": "Pa s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "omega (=dp/dt)", + "long_name": "Omega (=dp/dt)", "comment": "Omega (vertical velocity in pressure coordinates, positive downwards)", "dimensions": "longitude latitude alevel time", "out_name": "wap", @@ -593,13 +627,14 @@ "ok_max_mean_abs": "" }, "wap500": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "lagrangian_tendency_of_air_pressure", "units": "Pa s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "omega (=dp/dt)", - "comment": "Omega (vertical velocity in pressure coordinates, positive downwards) at 500 hPa level;", + "long_name": "Pressure Tendency", + "comment": "Omega (vertical velocity in pressure coordinates, positive downwards) at 500hPa level;", "dimensions": "longitude latitude time p500", "out_name": "wap500", "type": "real", @@ -610,13 +645,14 @@ "ok_max_mean_abs": "" }, "zg": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "geopotential_height", "units": "m", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Geopotential Height", - "comment": "", + "comment": "Geopotential is the sum of the specific gravitational potential energy relative to the geoid and the specific centripetal potential energy. Geopotential height is the geopotential divided by the standard acceleration due to gravity. It is numerically similar to the altitude (or geometric height) and not to the quantity with standard name height, which is relative to the surface.", "dimensions": "longitude latitude alevel time", "out_name": "zg", "type": "real", diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_CFmon.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_CFmon.json index 14a8f007ad..eeadc67d11 100644 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_CFmon.json +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_CFmon.json @@ -1,23 +1,24 @@ { "Header": { - "data_specs_version": "01.00.10", + "data_specs_version": "01.00.30", + "cmor_version": "3.4", "table_id": "Table CFmon", "realm": "atmos", - "frequency": "mon", - "cmor_version": "3.2", - "table_date": "10 May 2017", + "table_date": "11 March 2019", "missing_value": "1e20", + "int_missing_value": "-999", "product": "model-output", "approx_interval": "30.00000", "generic_levels": "alevel alevhalf", "mip_era": "CMIP6", - "Conventions": "CF-1.7 CMIP-6.0" + "Conventions": "CF-1.7 CMIP-6.2" }, "variable_entry": { "albisccp": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "cloud_albedo", - "units": "1.0", + "units": "1", "cell_methods": "area: time: mean where cloud", "cell_measures": "area: areacella", "long_name": "ISCCP Mean Cloud Albedo", @@ -32,12 +33,13 @@ "ok_max_mean_abs": "" }, "clc": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "convective_cloud_area_fraction_in_atmosphere_layer", "units": "%", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Convective Cloud Area Fraction", + "long_name": "Convective Cloud Area Percentage", "comment": "Include only convective cloud.", "dimensions": "longitude latitude alevel time", "out_name": "clc", @@ -49,13 +51,14 @@ "ok_max_mean_abs": "" }, "clcalipso": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "cloud_area_fraction_in_atmosphere_layer", "units": "%", "cell_methods": "time: mean", "cell_measures": "area: areacella", "long_name": "CALIPSO Percentage Cloud Cover", - "comment": "Percentage cloud cover at CALIPSO standard heights.", + "comment": "Percentage cloud cover in CALIPSO standard atmospheric layers.", "dimensions": "longitude latitude alt40 time", "out_name": "clcalipso", "type": "real", @@ -66,12 +69,13 @@ "ok_max_mean_abs": "" }, "clhcalipso": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "cloud_area_fraction_in_atmosphere_layer", "units": "%", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "CALIPSO Percentage High Level Cloud", + "long_name": "CALIPSO High Level Cloud Area Percentage", "comment": "Percentage cloud cover in layer centred on 220hPa", "dimensions": "longitude latitude time p220", "out_name": "clhcalipso", @@ -83,9 +87,10 @@ "ok_max_mean_abs": "" }, "clic": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "mass_fraction_of_convective_cloud_ice_in_air", - "units": "1.0", + "units": "1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Mass Fraction of Convective Cloud Ice", @@ -100,9 +105,10 @@ "ok_max_mean_abs": "" }, "clis": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "mass_fraction_of_stratiform_cloud_ice_in_air", - "units": "1.0", + "units": "1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Mass Fraction of Stratiform Cloud Ice", @@ -117,12 +123,13 @@ "ok_max_mean_abs": "" }, "clisccp": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "cloud_area_fraction_in_atmosphere_layer", "units": "%", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "ISCCP Percentage Cloud Area", + "long_name": "ISCCP Cloud Area Percentage", "comment": "Percentage cloud cover in optical depth categories.", "dimensions": "longitude latitude plev7c tau time", "out_name": "clisccp", @@ -134,12 +141,13 @@ "ok_max_mean_abs": "" }, "cllcalipso": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "cloud_area_fraction_in_atmosphere_layer", "units": "%", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "CALIPSO Percentage Low Level Cloud", + "long_name": "CALIPSO Low Level Cloud Cover Percentage", "comment": "Percentage cloud cover in layer centred on 840hPa", "dimensions": "longitude latitude time p840", "out_name": "cllcalipso", @@ -151,12 +159,13 @@ "ok_max_mean_abs": "" }, "clmcalipso": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "cloud_area_fraction_in_atmosphere_layer", "units": "%", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "CALIPSO Percentage Mid Level Cloud", + "long_name": "CALIPSO Mid Level Cloud Cover Percentage", "comment": "Percentage cloud cover in layer centred on 560hPa", "dimensions": "longitude latitude time p560", "out_name": "clmcalipso", @@ -168,13 +177,14 @@ "ok_max_mean_abs": "" }, "cls": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "stratiform_cloud_area_fraction_in_atmosphere_layer", "units": "%", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Stratiform Cloud Area Fraction", - "comment": "", + "long_name": "Percentage Cover of Stratiform Cloud", + "comment": "Cloud area fraction (reported as a percentage) for the whole atmospheric column due to stratiform clouds, as seen from the surface or the top of the atmosphere. Includes both large-scale and convective cloud.", "dimensions": "longitude latitude alevel time", "out_name": "cls", "type": "real", @@ -185,13 +195,14 @@ "ok_max_mean_abs": "" }, "cltcalipso": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "cloud_area_fraction", "units": "%", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "CALIPSO Percentage Total Cloud", - "comment": "", + "long_name": "CALIPSO Total Cloud Cover Percentage", + "comment": "Total cloud area fraction (reported as a percentage) for the whole atmospheric column, as seen by the Cloud-Aerosol Lidar and Infrared Pathfinder Satellite Observation (CALIPSO) instrument. Includes both large-scale and convective cloud.", "dimensions": "longitude latitude time", "out_name": "cltcalipso", "type": "real", @@ -202,13 +213,14 @@ "ok_max_mean_abs": "" }, "cltisccp": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "cloud_area_fraction", "units": "%", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "ISCCP Total Cloud Fraction", - "comment": "Percentage total cloud cover, simulating ISCCP observations.", + "long_name": "ISCCP Total Cloud Cover Percentage", + "comment": "Total cloud area fraction (reported as a percentage) for the whole atmospheric column, as seen by the International Satellite Cloud Climatology Project (ISCCP) analysis. Includes both large-scale and convective cloud. (MODIS). Includes both large-scale and convective cloud.", "dimensions": "longitude latitude time", "out_name": "cltisccp", "type": "real", @@ -219,9 +231,10 @@ "ok_max_mean_abs": "" }, "clwc": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "mass_fraction_of_convective_cloud_liquid_water_in_air", - "units": "1.0", + "units": "1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Mass Fraction of Convective Cloud Liquid Water", @@ -236,9 +249,10 @@ "ok_max_mean_abs": "" }, "clws": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "mass_fraction_of_stratiform_cloud_liquid_water_in_air", - "units": "1.0", + "units": "1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Mass Fraction of Stratiform Cloud Liquid Water", @@ -253,6 +267,7 @@ "ok_max_mean_abs": "" }, "dmc": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "atmosphere_net_upward_deep_convective_mass_flux", "units": "kg m-2 s-1", @@ -270,12 +285,13 @@ "ok_max_mean_abs": "" }, "edt": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "atmosphere_heat_diffusivity", "units": "m2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Eddy Diffusivity Coefficients for Temperature", + "long_name": "Eddy Diffusivity Coefficient for Temperature", "comment": "Vertical diffusion coefficient for temperature due to parametrised eddies", "dimensions": "longitude latitude alevel time", "out_name": "edt", @@ -287,12 +303,13 @@ "ok_max_mean_abs": "" }, "evu": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "atmosphere_momentum_diffusivity", "units": "m2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Eddy Viscosity Coefficients for Momentum", + "long_name": "Eddy Viscosity Coefficient for Momentum", "comment": "Vertical diffusion coefficient for momentum due to parametrised eddies", "dimensions": "longitude latitude alevel time", "out_name": "evu", @@ -304,6 +321,7 @@ "ok_max_mean_abs": "" }, "hur": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "relative_humidity", "units": "%", @@ -321,13 +339,14 @@ "ok_max_mean_abs": "" }, "hus": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "specific_humidity", - "units": "1.0", + "units": "1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Specific Humidity", - "comment": "", + "comment": "Specific humidity is the mass fraction of water vapor in (moist) air.", "dimensions": "longitude latitude alevel time", "out_name": "hus", "type": "real", @@ -338,6 +357,7 @@ "ok_max_mean_abs": "" }, "mcd": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "atmosphere_downdraft_convective_mass_flux", "units": "kg m-2 s-1", @@ -355,12 +375,13 @@ "ok_max_mean_abs": "" }, "mcu": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "atmosphere_updraft_convective_mass_flux", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Updraft Convective Mass Flux", + "long_name": "Convective Updraft Mass Flux", "comment": "In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. The atmosphere convective mass flux is the vertical transport of mass for a field of cumulus clouds or thermals, given by the product of air density and vertical velocity. For an area-average, cell_methods should specify whether the average is over all the area or the area of updrafts only.", "dimensions": "longitude latitude alevhalf time", "out_name": "mcu", @@ -372,6 +393,7 @@ "ok_max_mean_abs": "" }, "pctisccp": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "air_pressure_at_cloud_top", "units": "Pa", @@ -389,16 +411,17 @@ "ok_max_mean_abs": "" }, "ps": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "surface_air_pressure", "units": "Pa", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Surface Pressure", + "long_name": "Surface Air Pressure", "comment": "surface pressure (not mean sea-level pressure), 2-D field to calculate the 3-D pressure field from hybrid coordinates", "dimensions": "longitude latitude time", "out_name": "ps", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -406,6 +429,7 @@ "ok_max_mean_abs": "" }, "rld": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "downwelling_longwave_flux_in_air", "units": "W m-2", @@ -423,6 +447,7 @@ "ok_max_mean_abs": "" }, "rld4co2": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "downwelling_longwave_flux_in_air", "units": "W m-2", @@ -440,6 +465,7 @@ "ok_max_mean_abs": "" }, "rldcs": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "downwelling_longwave_flux_in_air_assuming_clear_sky", "units": "W m-2", @@ -457,6 +483,7 @@ "ok_max_mean_abs": "" }, "rldcs4co2": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "downwelling_longwave_flux_in_air_assuming_clear_sky", "units": "W m-2", @@ -474,6 +501,7 @@ "ok_max_mean_abs": "" }, "rlu": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "upwelling_longwave_flux_in_air", "units": "W m-2", @@ -491,6 +519,7 @@ "ok_max_mean_abs": "" }, "rlu4co2": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "upwelling_longwave_flux_in_air", "units": "W m-2", @@ -508,6 +537,7 @@ "ok_max_mean_abs": "" }, "rlucs": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "upwelling_longwave_flux_in_air_assuming_clear_sky", "units": "W m-2", @@ -525,6 +555,7 @@ "ok_max_mean_abs": "" }, "rlucs4co2": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "upwelling_longwave_flux_in_air_assuming_clear_sky", "units": "W m-2", @@ -542,6 +573,7 @@ "ok_max_mean_abs": "" }, "rlut4co2": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "toa_outgoing_longwave_flux", "units": "W m-2", @@ -559,6 +591,7 @@ "ok_max_mean_abs": "" }, "rlutcs4co2": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "toa_outgoing_longwave_flux_assuming_clear_sky", "units": "W m-2", @@ -576,6 +609,7 @@ "ok_max_mean_abs": "" }, "rsd": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "downwelling_shortwave_flux_in_air", "units": "W m-2", @@ -593,6 +627,7 @@ "ok_max_mean_abs": "" }, "rsd4co2": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "downwelling_shortwave_flux_in_air", "units": "W m-2", @@ -610,6 +645,7 @@ "ok_max_mean_abs": "" }, "rsdcs": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "downwelling_shortwave_flux_in_air_assuming_clear_sky", "units": "W m-2", @@ -627,6 +663,7 @@ "ok_max_mean_abs": "" }, "rsdcs4co2": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "downwelling_shortwave_flux_in_air_assuming_clear_sky", "units": "W m-2", @@ -644,6 +681,7 @@ "ok_max_mean_abs": "" }, "rsu": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "upwelling_shortwave_flux_in_air", "units": "W m-2", @@ -661,6 +699,7 @@ "ok_max_mean_abs": "" }, "rsu4co2": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "upwelling_shortwave_flux_in_air", "units": "W m-2", @@ -678,6 +717,7 @@ "ok_max_mean_abs": "" }, "rsucs": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "upwelling_shortwave_flux_in_air_assuming_clear_sky", "units": "W m-2", @@ -695,6 +735,7 @@ "ok_max_mean_abs": "" }, "rsucs4co2": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "upwelling_shortwave_flux_in_air_assuming_clear_sky", "units": "W m-2", @@ -712,6 +753,7 @@ "ok_max_mean_abs": "" }, "rsut4co2": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "toa_outgoing_shortwave_flux", "units": "W m-2", @@ -729,6 +771,7 @@ "ok_max_mean_abs": "" }, "rsutcs4co2": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "toa_outgoing_shortwave_flux_assuming_clear_sky", "units": "W m-2", @@ -746,6 +789,7 @@ "ok_max_mean_abs": "" }, "smc": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "atmosphere_net_upward_shallow_convective_mass_flux", "units": "kg m-2 s-1", @@ -763,6 +807,7 @@ "ok_max_mean_abs": "" }, "ta": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "air_temperature", "units": "K", @@ -780,6 +825,7 @@ "ok_max_mean_abs": "" }, "tnhus": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "tendency_of_specific_humidity", "units": "s-1", @@ -797,12 +843,13 @@ "ok_max_mean_abs": "" }, "tnhusa": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "tendency_of_specific_humidity_due_to_advection", "units": "s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Tendency of Specific Humidity due to Advection", + "long_name": "Tendency of Specific Humidity Due to Advection", "comment": "Tendency of Specific Humidity due to Advection", "dimensions": "longitude latitude alevel time", "out_name": "tnhusa", @@ -814,12 +861,13 @@ "ok_max_mean_abs": "" }, "tnhusc": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "tendency_of_specific_humidity_due_to_convection", "units": "s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Tendency of Specific Humidity due to Convection", + "long_name": "Tendency of Specific Humidity Due to Convection", "comment": "Tendencies from cumulus convection scheme.", "dimensions": "longitude latitude alevel time", "out_name": "tnhusc", @@ -831,12 +879,13 @@ "ok_max_mean_abs": "" }, "tnhusd": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "tendency_of_specific_humidity_due_to_diffusion", "units": "s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Tendency of Specific Humidity due to Numerical Diffusion", + "long_name": "Tendency of Specific Humidity Due to Numerical Diffusion", "comment": "Tendency of specific humidity due to numerical diffusion.This includes any horizontal or vertical numerical moisture diffusion not associated with the parametrized moist physics or the resolved dynamics. For example, any vertical diffusion which is part of the boundary layer mixing scheme should be excluded, as should any diffusion which is included in the terms from the resolved dynamics. This term is required to check the closure of the moisture budget.", "dimensions": "longitude latitude alevel time", "out_name": "tnhusd", @@ -848,13 +897,14 @@ "ok_max_mean_abs": "" }, "tnhusmp": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "tendency_of_specific_humidity_due_to_model_physics", "units": "s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Tendency of Specific Humidity due to Model Physics", - "comment": "Tendency of specific humidity due to model physics. This includes sources and sinks from parametrized moist physics (e.g. convection, boundary layer, stratiform condensation/evaporation, etc.) and excludes sources and sinks from resolved dynamics or from horizontal or vertical numerical diffusion not associated with model physicsl. For example any diffusive mixing by the boundary layer scheme would be included.", + "long_name": "Tendency of Specific Humidity Due to Model Physics", + "comment": "Tendency of specific humidity due to model physics. This includes sources and sinks from parametrized moist physics (e.g. convection, boundary layer, stratiform condensation/evaporation, etc.) and excludes sources and sinks from resolved dynamics or from horizontal or vertical numerical diffusion not associated with model physics. For example any diffusive mixing by the boundary layer scheme would be included.", "dimensions": "longitude latitude alevel time", "out_name": "tnhusmp", "type": "real", @@ -865,13 +915,14 @@ "ok_max_mean_abs": "" }, "tnhusscpbl": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "tendency_of_specific_humidity_due_to_stratiform_cloud_and_precipitation_and_boundary_layer_mixing", "units": "s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Tendency of Specific Humidity Due to Stratiform Cloud and Precipitation and Boundary Layer Mixing", - "comment": "Tendency of Specific Humidity Due to Stratiform Cloud and Precipitation and Boundary Layer Mixing (to be specified only in models which do not separate budget terms for stratiform cloud, precipitation and boundary layer schemes. Includes all bounday layer terms including and diffusive terms.)", + "comment": "Tendency of Specific Humidity Due to Stratiform Cloud and Precipitation and Boundary Layer Mixing (to be specified only in models which do not separate budget terms for stratiform cloud, precipitation and boundary layer schemes. Includes all boundary layer terms including and diffusive terms.)", "dimensions": "longitude latitude alevel time", "out_name": "tnhusscpbl", "type": "real", @@ -882,6 +933,7 @@ "ok_max_mean_abs": "" }, "tnt": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "tendency_of_air_temperature", "units": "K s-1", @@ -899,12 +951,13 @@ "ok_max_mean_abs": "" }, "tnta": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "tendency_of_air_temperature_due_to_advection", "units": "K s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Tendency of Air Temperature due to Advection", + "long_name": "Tendency of Air Temperature Due to Advection", "comment": "Tendency of Air Temperature due to Advection", "dimensions": "longitude latitude alevel time", "out_name": "tnta", @@ -916,12 +969,13 @@ "ok_max_mean_abs": "" }, "tntc": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "tendency_of_air_temperature_due_to_convection", "units": "K s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Tendency of Air Temperature due to Convection", + "long_name": "Tendency of Air Temperature Due to Convection", "comment": "Tendencies from cumulus convection scheme.", "dimensions": "longitude latitude alevel time", "out_name": "tntc", @@ -933,12 +987,13 @@ "ok_max_mean_abs": "" }, "tntmp": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "tendency_of_air_temperature_due_to_model_physics", "units": "K s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Tendency of Air Temperature due to Model Physics", + "long_name": "Tendency of Air Temperature Due to Model Physics", "comment": "Tendency of air temperature due to model physics. This includes sources and sinks from parametrized physics (e.g. radiation, convection, boundary layer, stratiform condensation/evaporation, etc.). It excludes sources and sinks from resolved dynamics and numerical diffusion not associated with parametrized physics. For example, any vertical diffusion which is part of the boundary layer mixing scheme should be included, while numerical diffusion applied in addition to physics or resolved dynamics should be excluded. This term is required to check the closure of the heat budget.", "dimensions": "longitude latitude alevel time", "out_name": "tntmp", @@ -950,12 +1005,13 @@ "ok_max_mean_abs": "" }, "tntr": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "tendency_of_air_temperature_due_to_radiative_heating", "units": "K s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Tendency of Air Temperature due to Radiative Heating", + "long_name": "Tendency of Air Temperature Due to Radiative Heating", "comment": "Tendency of Air Temperature due to Radiative Heating", "dimensions": "longitude latitude alevel time", "out_name": "tntr", @@ -967,6 +1023,7 @@ "ok_max_mean_abs": "" }, "tntscpbl": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "tendency_of_air_temperature_due_to_stratiform_cloud_and_precipitation_and_boundary_layer_mixing", "units": "K s-1", diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_CFsubhr.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_CFsubhr.json index fa2e1bed39..bf83db0813 100644 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_CFsubhr.json +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_CFsubhr.json @@ -1,20 +1,23 @@ { "Header": { - "data_specs_version": "01.00.10", + "data_specs_version": "01.00.30", + "cmor_version": "3.4", "table_id": "Table CFsubhr", "realm": "atmos", - "frequency": "subhr", - "cmor_version": "3.2", - "table_date": "10 May 2017", + "table_date": "11 March 2019", "missing_value": "1e20", + "int_missing_value": "-999", "product": "model-output", "approx_interval": "0.017361", + "approx_interval_error": "0.90", + "approx_interval_warning": "0.5", "generic_levels": "alevel alevhalf", "mip_era": "CMIP6", - "Conventions": "CF-1.7 CMIP-6.0" + "Conventions": "CF-1.7 CMIP-6.2" }, "variable_entry": { "ccb": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "air_pressure_at_convective_cloud_base", "units": "Pa", @@ -32,6 +35,7 @@ "ok_max_mean_abs": "" }, "cct": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "air_pressure_at_convective_cloud_top", "units": "Pa", @@ -49,12 +53,13 @@ "ok_max_mean_abs": "" }, "ci": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "convection_time_fraction", - "units": "1.0", + "units": "1", "cell_methods": "area: point time: point", "cell_measures": "", - "long_name": "Fraction of Time Convection Occurs", + "long_name": "Fraction of Time Convection Occurs in Cell", "comment": "Fraction of time that convection occurs in the grid cell.", "dimensions": "site time1", "out_name": "ci", @@ -66,12 +71,13 @@ "ok_max_mean_abs": "" }, "cl": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "cloud_area_fraction_in_atmosphere_layer", "units": "%", "cell_methods": "area: point time: point", "cell_measures": "", - "long_name": "Cloud Area Fraction", + "long_name": "Percentage Cloud Cover", "comment": "Percentage cloud cover, including both large-scale and convective cloud.", "dimensions": "alevel site time1", "out_name": "cl", @@ -83,6 +89,7 @@ "ok_max_mean_abs": "" }, "cli": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "mass_fraction_of_cloud_ice_in_air", "units": "kg kg-1", @@ -100,8 +107,9 @@ "ok_max_mean_abs": "" }, "clivi": { + "frequency": "subhrPt", "modeling_realm": "atmos", - "standard_name": "atmosphere_cloud_ice_content", + "standard_name": "atmosphere_mass_content_of_cloud_ice", "units": "kg m-2", "cell_methods": "area: point time: point", "cell_measures": "", @@ -117,13 +125,14 @@ "ok_max_mean_abs": "" }, "clt": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "cloud_area_fraction", "units": "%", "cell_methods": "area: point time: point", "cell_measures": "", - "long_name": "Total Cloud Fraction", - "comment": "Total cloud area fraction for the whole atmospheric column, as seen from the surface or the top of the atmosphere. Includes both large-scale and convective cloud.", + "long_name": "Total Cloud Cover Percentage", + "comment": "Total cloud area fraction (reported as a percentage) for the whole atmospheric column, as seen from the surface or the top of the atmosphere. Includes both large-scale and convective cloud.", "dimensions": "site time1", "out_name": "clt", "type": "real", @@ -134,6 +143,7 @@ "ok_max_mean_abs": "" }, "clw": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "mass_fraction_of_cloud_liquid_water_in_air", "units": "kg kg-1", @@ -151,8 +161,9 @@ "ok_max_mean_abs": "" }, "clwvi": { + "frequency": "subhrPt", "modeling_realm": "atmos", - "standard_name": "atmosphere_cloud_condensed_water_content", + "standard_name": "atmosphere_mass_content_of_cloud_condensed_water", "units": "kg m-2", "cell_methods": "area: point time: point", "cell_measures": "", @@ -168,12 +179,13 @@ "ok_max_mean_abs": "" }, "edt": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "atmosphere_heat_diffusivity", "units": "m2 s-1", "cell_methods": "area: point time: point", "cell_measures": "", - "long_name": "Eddy Diffusivity Coefficient for Temperature Variable", + "long_name": "Eddy Diffusivity Coefficient for Temperature", "comment": "Vertical diffusion coefficient for temperature due to parametrised eddies", "dimensions": "alevel site time1", "out_name": "edt", @@ -185,13 +197,14 @@ "ok_max_mean_abs": "" }, "evspsbl": { + "frequency": "subhrPt", "modeling_realm": "atmos", - "standard_name": "water_evaporation_flux", + "standard_name": "water_evapotranspiration_flux", "units": "kg m-2 s-1", "cell_methods": "area: point time: point", "cell_measures": "", - "long_name": "Evaporation", - "comment": "Evaporation at surface: flux of water into the atmosphere due to conversion of both liquid and solid phases to vapor (from underlying surface and vegetation)", + "long_name": "Evaporation Including Sublimation and Transpiration", + "comment": "Evaporation at surface (also known as evapotranspiration): flux of water into the atmosphere due to conversion of both liquid and solid phases to vapor (from underlying surface and vegetation)", "dimensions": "site time1", "out_name": "evspsbl", "type": "real", @@ -202,12 +215,13 @@ "ok_max_mean_abs": "" }, "evu": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "atmosphere_momentum_diffusivity", "units": "m2 s-1", "cell_methods": "area: point time: point", "cell_measures": "", - "long_name": "Eddy Viscosity Coefficient for Momentum Variables", + "long_name": "Eddy Viscosity Coefficient for Momentum", "comment": "Vertical diffusion coefficient for momentum due to parametrised eddies", "dimensions": "alevel site time1", "out_name": "evu", @@ -219,6 +233,7 @@ "ok_max_mean_abs": "" }, "fco2antt": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "tendency_of_atmosphere_mass_content_of_carbon_dioxide_expressed_as_carbon_due_to_anthropogenic_emission", "units": "kg m-2 s-1", @@ -229,13 +244,14 @@ "dimensions": "site time1", "out_name": "fco2antt", "type": "real", - "positive": "up", + "positive": "", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "fco2fos": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "tendency_of_atmosphere_mass_content_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_fossil_fuel_combustion", "units": "kg m-2 s-1", @@ -246,13 +262,14 @@ "dimensions": "site time1", "out_name": "fco2fos", "type": "real", - "positive": "up", + "positive": "", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "fco2nat": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_natural_sources", "units": "kg m-2 s-1", @@ -263,20 +280,21 @@ "dimensions": "site time1", "out_name": "fco2nat", "type": "real", - "positive": "up", + "positive": "", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "hfls": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "surface_upward_latent_heat_flux", "units": "W m-2", "cell_methods": "area: point time: point", "cell_measures": "", "long_name": "Surface Upward Latent Heat Flux", - "comment": "", + "comment": "The surface called 'surface' means the lower boundary of the atmosphere. 'Upward' indicates a vector component which is positive when directed upward (negative downward). The surface latent heat flux is the exchange of heat between the surface and the air on account of evaporation (including sublimation). In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions": "site time1", "out_name": "hfls", "type": "real", @@ -287,13 +305,14 @@ "ok_max_mean_abs": "" }, "hfss": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "surface_upward_sensible_heat_flux", "units": "W m-2", "cell_methods": "area: point time: point", "cell_measures": "", "long_name": "Surface Upward Sensible Heat Flux", - "comment": "", + "comment": "The surface sensible heat flux, also called turbulent heat flux, is the exchange of heat between the surface and the air by motion of air.", "dimensions": "site time1", "out_name": "hfss", "type": "real", @@ -304,6 +323,7 @@ "ok_max_mean_abs": "" }, "hur": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "relative_humidity", "units": "%", @@ -321,6 +341,7 @@ "ok_max_mean_abs": "" }, "hurs": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "relative_humidity", "units": "%", @@ -338,13 +359,14 @@ "ok_max_mean_abs": "" }, "hus": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "specific_humidity", - "units": "1.0", + "units": "1", "cell_methods": "area: point time: point", "cell_measures": "", "long_name": "Specific Humidity", - "comment": "", + "comment": "Specific humidity is the mass fraction of water vapor in (moist) air.", "dimensions": "alevel site time1", "out_name": "hus", "type": "real", @@ -355,9 +377,10 @@ "ok_max_mean_abs": "" }, "huss": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "specific_humidity", - "units": "1.0", + "units": "1", "cell_methods": "area: point time: point", "cell_measures": "", "long_name": "Near-Surface Specific Humidity", @@ -372,13 +395,14 @@ "ok_max_mean_abs": "" }, "latitude": { + "frequency": "fx", "modeling_realm": "atmos", "standard_name": "latitude", "units": "degrees_north", "cell_methods": "area: point", "cell_measures": "", "long_name": "Latitude", - "comment": "", + "comment": "Latitude is positive northward; its units of degree_north (or equivalent) indicate this explicitly. In a latitude-longitude system defined with respect to a rotated North Pole, the standard name of grid_latitude should be used instead of latitude. Grid latitude is positive in the grid-northward direction, but its units should be plain degree.", "dimensions": "site", "out_name": "lat", "type": "real", @@ -389,13 +413,14 @@ "ok_max_mean_abs": "" }, "longitude": { + "frequency": "fx", "modeling_realm": "atmos", "standard_name": "longitude", "units": "degrees_east", "cell_methods": "area: point", "cell_measures": "", "long_name": "Longitude", - "comment": "", + "comment": "Longitude is positive eastward; its units of degree_east (or equivalent) indicate this explicitly. In a latitude-longitude system defined with respect to a rotated North Pole, the standard name of grid_longitude should be used instead of longitude. Grid longitude is positive in the grid-eastward direction, but its units should be plain degree.", "dimensions": "site", "out_name": "lon", "type": "real", @@ -406,6 +431,7 @@ "ok_max_mean_abs": "" }, "mc": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "atmosphere_net_upward_convective_mass_flux", "units": "kg m-2 s-1", @@ -423,12 +449,13 @@ "ok_max_mean_abs": "" }, "pfull": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "air_pressure", "units": "Pa", "cell_methods": "area: point time: point", "cell_measures": "", - "long_name": "Pressure on Model Levels", + "long_name": "Pressure at Model Full-Levels", "comment": "Air pressure on model levels", "dimensions": "alevel site time1", "out_name": "pfull", @@ -440,6 +467,7 @@ "ok_max_mean_abs": "" }, "phalf": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "air_pressure", "units": "Pa", @@ -457,6 +485,7 @@ "ok_max_mean_abs": "" }, "pr": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "precipitation_flux", "units": "kg m-2 s-1", @@ -474,6 +503,7 @@ "ok_max_mean_abs": "" }, "prc": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "convective_precipitation_flux", "units": "kg m-2 s-1", @@ -491,13 +521,14 @@ "ok_max_mean_abs": "" }, "prsn": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "snowfall_flux", "units": "kg m-2 s-1", "cell_methods": "area: point time: point", "cell_measures": "", "long_name": "Snowfall Flux", - "comment": "at surface; includes precipitation of all forms of water in the solid phase", + "comment": "At surface; includes precipitation of all forms of water in the solid phase", "dimensions": "site time1", "out_name": "prsn", "type": "real", @@ -508,8 +539,9 @@ "ok_max_mean_abs": "" }, "prw": { + "frequency": "subhrPt", "modeling_realm": "atmos", - "standard_name": "atmosphere_water_vapor_content", + "standard_name": "atmosphere_mass_content_of_water_vapor", "units": "kg m-2", "cell_methods": "area: point time: point", "cell_measures": "", @@ -525,6 +557,7 @@ "ok_max_mean_abs": "" }, "ps": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "surface_air_pressure", "units": "Pa", @@ -542,8 +575,9 @@ "ok_max_mean_abs": "" }, "psl": { + "frequency": "subhrPt", "modeling_realm": "atmos", - "standard_name": "air_pressure_at_sea_level", + "standard_name": "air_pressure_at_mean_sea_level", "units": "Pa", "cell_methods": "area: point time: point", "cell_measures": "", @@ -559,6 +593,7 @@ "ok_max_mean_abs": "" }, "rld": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "downwelling_longwave_flux_in_air", "units": "W m-2", @@ -576,6 +611,7 @@ "ok_max_mean_abs": "" }, "rldcs": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "downwelling_longwave_flux_in_air_assuming_clear_sky", "units": "W m-2", @@ -593,13 +629,14 @@ "ok_max_mean_abs": "" }, "rlds": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "surface_downwelling_longwave_flux_in_air", "units": "W m-2", "cell_methods": "area: point time: point", "cell_measures": "", "long_name": "Surface Downwelling Longwave Radiation", - "comment": "", + "comment": "The surface called 'surface' means the lower boundary of the atmosphere. 'longwave' means longwave radiation. Downwelling radiation is radiation from above. It does not mean 'net downward'. When thought of as being incident on a surface, a radiative flux is sometimes called 'irradiance'. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called 'vector irradiance'. In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions": "site time1", "out_name": "rlds", "type": "real", @@ -610,6 +647,7 @@ "ok_max_mean_abs": "" }, "rldscs": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "surface_downwelling_longwave_flux_in_air_assuming_clear_sky", "units": "W m-2", @@ -627,6 +665,7 @@ "ok_max_mean_abs": "" }, "rlu": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "upwelling_longwave_flux_in_air", "units": "W m-2", @@ -644,6 +683,7 @@ "ok_max_mean_abs": "" }, "rlucs": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "upwelling_longwave_flux_in_air_assuming_clear_sky", "units": "W m-2", @@ -661,13 +701,14 @@ "ok_max_mean_abs": "" }, "rlus": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "surface_upwelling_longwave_flux_in_air", "units": "W m-2", "cell_methods": "area: point time: point", "cell_measures": "", "long_name": "Surface Upwelling Longwave Radiation", - "comment": "", + "comment": "The surface called 'surface' means the lower boundary of the atmosphere. 'longwave' means longwave radiation. Upwelling radiation is radiation from below. It does not mean 'net upward'. When thought of as being incident on a surface, a radiative flux is sometimes called 'irradiance'. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called 'vector irradiance'. In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions": "site time1", "out_name": "rlus", "type": "real", @@ -678,6 +719,7 @@ "ok_max_mean_abs": "" }, "rlut": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "toa_outgoing_longwave_flux", "units": "W m-2", @@ -695,13 +737,14 @@ "ok_max_mean_abs": "" }, "rlutcs": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "toa_outgoing_longwave_flux_assuming_clear_sky", "units": "W m-2", "cell_methods": "area: point time: point", "cell_measures": "", "long_name": "TOA Outgoing Clear-Sky Longwave Radiation", - "comment": "", + "comment": "Upwelling clear-sky longwave radiation at top of atmosphere", "dimensions": "site time1", "out_name": "rlutcs", "type": "real", @@ -712,6 +755,7 @@ "ok_max_mean_abs": "" }, "rsd": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "downwelling_shortwave_flux_in_air", "units": "W m-2", @@ -729,6 +773,7 @@ "ok_max_mean_abs": "" }, "rsdcs": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "downwelling_shortwave_flux_in_air_assuming_clear_sky", "units": "W m-2", @@ -746,13 +791,14 @@ "ok_max_mean_abs": "" }, "rsds": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "surface_downwelling_shortwave_flux_in_air", "units": "W m-2", "cell_methods": "area: point time: point", "cell_measures": "", "long_name": "Surface Downwelling Shortwave Radiation", - "comment": "surface solar irradiance for UV calculations", + "comment": "Surface solar irradiance for UV calculations.", "dimensions": "site time1", "out_name": "rsds", "type": "real", @@ -763,13 +809,14 @@ "ok_max_mean_abs": "" }, "rsdscs": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "surface_downwelling_shortwave_flux_in_air_assuming_clear_sky", "units": "W m-2", "cell_methods": "area: point time: point", "cell_measures": "", "long_name": "Surface Downwelling Clear-Sky Shortwave Radiation", - "comment": "surface solar irradiance clear sky for UV calculations", + "comment": "Surface solar irradiance clear sky for UV calculations", "dimensions": "site time1", "out_name": "rsdscs", "type": "real", @@ -780,6 +827,7 @@ "ok_max_mean_abs": "" }, "rsdt": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "toa_incoming_shortwave_flux", "units": "W m-2", @@ -797,6 +845,7 @@ "ok_max_mean_abs": "" }, "rsu": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "upwelling_shortwave_flux_in_air", "units": "W m-2", @@ -814,6 +863,7 @@ "ok_max_mean_abs": "" }, "rsucs": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "upwelling_shortwave_flux_in_air_assuming_clear_sky", "units": "W m-2", @@ -831,13 +881,14 @@ "ok_max_mean_abs": "" }, "rsus": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "surface_upwelling_shortwave_flux_in_air", "units": "W m-2", "cell_methods": "area: point time: point", "cell_measures": "", "long_name": "Surface Upwelling Shortwave Radiation", - "comment": "", + "comment": "The surface called 'surface' means the lower boundary of the atmosphere. 'shortwave' means shortwave radiation. Upwelling radiation is radiation from below. It does not mean 'net upward'. When thought of as being incident on a surface, a radiative flux is sometimes called 'irradiance'. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called 'vector irradiance'. In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions": "site time1", "out_name": "rsus", "type": "real", @@ -848,6 +899,7 @@ "ok_max_mean_abs": "" }, "rsuscs": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "surface_upwelling_shortwave_flux_in_air_assuming_clear_sky", "units": "W m-2", @@ -865,6 +917,7 @@ "ok_max_mean_abs": "" }, "rsut": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "toa_outgoing_shortwave_flux", "units": "W m-2", @@ -882,6 +935,7 @@ "ok_max_mean_abs": "" }, "rsutcs": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "toa_outgoing_shortwave_flux_assuming_clear_sky", "units": "W m-2", @@ -899,12 +953,13 @@ "ok_max_mean_abs": "" }, "rtmt": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "net_downward_radiative_flux_at_top_of_atmosphere_model", "units": "W m-2", "cell_methods": "area: point time: point", "cell_measures": "", - "long_name": "Net Downward Flux at Top of Model", + "long_name": "Net Downward Radiative Flux at Top of Model", "comment": "Net Downward Radiative Flux at Top of Model : I.e., at the top of that portion of the atmosphere where dynamics are explicitly treated by the model. This is reported only if it differs from the net downward radiative flux at the top of the atmosphere.", "dimensions": "site time1", "out_name": "rtmt", @@ -916,8 +971,9 @@ "ok_max_mean_abs": "" }, "sbl": { + "frequency": "subhrPt", "modeling_realm": "landIce", - "standard_name": "surface_snow_and_ice_sublimation_flux", + "standard_name": "tendency_of_atmosphere_mass_content_of_water_vapor_due_to_sublimation_of_surface_snow_and_ice", "units": "kg m-2 s-1", "cell_methods": "area: point time: point", "cell_measures": "", @@ -933,9 +989,10 @@ "ok_max_mean_abs": "" }, "sci": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "shallow_convection_time_fraction", - "units": "1.0", + "units": "1", "cell_methods": "area: point time: point", "cell_measures": "", "long_name": "Fraction of Time Shallow Convection Occurs", @@ -950,6 +1007,7 @@ "ok_max_mean_abs": "" }, "sfcWind": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "wind_speed", "units": "m s-1", @@ -967,6 +1025,7 @@ "ok_max_mean_abs": "" }, "ta": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "air_temperature", "units": "K", @@ -984,6 +1043,7 @@ "ok_max_mean_abs": "" }, "tas": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "air_temperature", "units": "K", @@ -1001,6 +1061,7 @@ "ok_max_mean_abs": "" }, "tauu": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "surface_downward_eastward_stress", "units": "Pa", @@ -1018,6 +1079,7 @@ "ok_max_mean_abs": "" }, "tauv": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "surface_downward_northward_stress", "units": "Pa", @@ -1035,6 +1097,7 @@ "ok_max_mean_abs": "" }, "tnhus": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "tendency_of_specific_humidity", "units": "s-1", @@ -1052,12 +1115,13 @@ "ok_max_mean_abs": "" }, "tnhusa": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "tendency_of_specific_humidity_due_to_advection", "units": "s-1", "cell_methods": "area: point time: point", "cell_measures": "", - "long_name": "Tendency of Specific Humidity due to Advection", + "long_name": "Tendency of Specific Humidity Due to Advection", "comment": "Tendency of Specific Humidity due to Advection", "dimensions": "alevel site time1", "out_name": "tnhusa", @@ -1069,12 +1133,13 @@ "ok_max_mean_abs": "" }, "tnhusc": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "tendency_of_specific_humidity_due_to_convection", "units": "s-1", "cell_methods": "area: point time: point", "cell_measures": "", - "long_name": "Tendency of Specific Humidity due to Convection", + "long_name": "Tendency of Specific Humidity Due to Convection", "comment": "Tendencies from cumulus convection scheme.", "dimensions": "alevel site time1", "out_name": "tnhusc", @@ -1086,12 +1151,13 @@ "ok_max_mean_abs": "" }, "tnhusd": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "tendency_of_specific_humidity_due_to_diffusion", "units": "s-1", "cell_methods": "area: point time: point", "cell_measures": "", - "long_name": "Tendency of Specific Humidity due to Numerical Diffusion", + "long_name": "Tendency of Specific Humidity Due to Numerical Diffusion", "comment": "Tendency of specific humidity due to numerical diffusion.This includes any horizontal or vertical numerical moisture diffusion not associated with the parametrized moist physics or the resolved dynamics. For example, any vertical diffusion which is part of the boundary layer mixing scheme should be excluded, as should any diffusion which is included in the terms from the resolved dynamics. This term is required to check the closure of the moisture budget.", "dimensions": "alevel site time1", "out_name": "tnhusd", @@ -1103,13 +1169,14 @@ "ok_max_mean_abs": "" }, "tnhusmp": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "tendency_of_specific_humidity_due_to_model_physics", "units": "s-1", "cell_methods": "area: point time: point", "cell_measures": "", - "long_name": "Tendency of Specific Humidity due to Model Physics", - "comment": "Tendency of specific humidity due to model physics. This includes sources and sinks from parametrized moist physics (e.g. convection, boundary layer, stratiform condensation/evaporation, etc.) and excludes sources and sinks from resolved dynamics or from horizontal or vertical numerical diffusion not associated with model physicsl. For example any diffusive mixing by the boundary layer scheme would be included.", + "long_name": "Tendency of Specific Humidity Due to Model Physics", + "comment": "Tendency of specific humidity due to model physics. This includes sources and sinks from parametrized moist physics (e.g. convection, boundary layer, stratiform condensation/evaporation, etc.) and excludes sources and sinks from resolved dynamics or from horizontal or vertical numerical diffusion not associated with model physics. For example any diffusive mixing by the boundary layer scheme would be included.", "dimensions": "alevel site time1", "out_name": "tnhusmp", "type": "real", @@ -1120,13 +1187,14 @@ "ok_max_mean_abs": "" }, "tnhusscpbl": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "tendency_of_specific_humidity_due_to_stratiform_cloud_and_precipitation_and_boundary_layer_mixing", "units": "s-1", "cell_methods": "area: point time: point", "cell_measures": "", "long_name": "Tendency of Specific Humidity Due to Stratiform Cloud and Precipitation and Boundary Layer Mixing", - "comment": "Tendency of Specific Humidity Due to Stratiform Cloud and Precipitation and Boundary Layer Mixing (to be specified only in models which do not separate budget terms for stratiform cloud, precipitation and boundary layer schemes. Includes all bounday layer terms including and diffusive terms.)", + "comment": "Tendency of Specific Humidity Due to Stratiform Cloud and Precipitation and Boundary Layer Mixing (to be specified only in models which do not separate budget terms for stratiform cloud, precipitation and boundary layer schemes. Includes all boundary layer terms including and diffusive terms.)", "dimensions": "alevel site time1", "out_name": "tnhusscpbl", "type": "real", @@ -1137,6 +1205,7 @@ "ok_max_mean_abs": "" }, "tnt": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "tendency_of_air_temperature", "units": "K s-1", @@ -1154,12 +1223,13 @@ "ok_max_mean_abs": "" }, "tnta": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "tendency_of_air_temperature_due_to_advection", "units": "K s-1", "cell_methods": "area: point time: point", "cell_measures": "", - "long_name": "Tendency of Air Temperature due to Advection", + "long_name": "Tendency of Air Temperature Due to Advection", "comment": "Tendency of Air Temperature due to Advection", "dimensions": "alevel site time1", "out_name": "tnta", @@ -1171,12 +1241,13 @@ "ok_max_mean_abs": "" }, "tntc": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "tendency_of_air_temperature_due_to_convection", "units": "K s-1", "cell_methods": "area: point time: point", "cell_measures": "", - "long_name": "Tendency of Air Temperature due to Convection", + "long_name": "Tendency of Air Temperature Due to Convection", "comment": "Tendencies from cumulus convection scheme.", "dimensions": "alevel site time1", "out_name": "tntc", @@ -1188,12 +1259,13 @@ "ok_max_mean_abs": "" }, "tntmp": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "tendency_of_air_temperature_due_to_model_physics", "units": "K s-1", "cell_methods": "area: point time: point", "cell_measures": "", - "long_name": "Tendency of Air Temperature due to Model Physics", + "long_name": "Tendency of Air Temperature Due to Model Physics", "comment": "Tendency of air temperature due to model physics. This includes sources and sinks from parametrized physics (e.g. radiation, convection, boundary layer, stratiform condensation/evaporation, etc.). It excludes sources and sinks from resolved dynamics and numerical diffusion not associated with parametrized physics. For example, any vertical diffusion which is part of the boundary layer mixing scheme should be included, while numerical diffusion applied in addition to physics or resolved dynamics should be excluded. This term is required to check the closure of the heat budget.", "dimensions": "alevel site time1", "out_name": "tntmp", @@ -1205,12 +1277,13 @@ "ok_max_mean_abs": "" }, "tntr": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "tendency_of_air_temperature_due_to_radiative_heating", "units": "K s-1", "cell_methods": "area: point time: point", "cell_measures": "", - "long_name": "Tendency of Air Temperature due to Radiative Heating", + "long_name": "Tendency of Air Temperature Due to Radiative Heating", "comment": "Tendency of Air Temperature due to Radiative Heating", "dimensions": "alevel site time1", "out_name": "tntr", @@ -1222,6 +1295,7 @@ "ok_max_mean_abs": "" }, "tntscpbl": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "tendency_of_air_temperature_due_to_stratiform_cloud_and_precipitation_and_boundary_layer_mixing", "units": "K s-1", @@ -1239,6 +1313,7 @@ "ok_max_mean_abs": "" }, "ts": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "surface_temperature", "units": "K", @@ -1256,13 +1331,14 @@ "ok_max_mean_abs": "" }, "ua": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "eastward_wind", "units": "m s-1", "cell_methods": "area: point time: point", "cell_measures": "", "long_name": "Eastward Wind", - "comment": "", + "comment": "Zonal wind (positive in a eastward direction).", "dimensions": "alevel site time1", "out_name": "ua", "type": "real", @@ -1273,6 +1349,7 @@ "ok_max_mean_abs": "" }, "uas": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "eastward_wind", "units": "m s-1", @@ -1290,13 +1367,14 @@ "ok_max_mean_abs": "" }, "va": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "northward_wind", "units": "m s-1", "cell_methods": "area: point time: point", "cell_measures": "", "long_name": "Northward Wind", - "comment": "", + "comment": "Meridional wind (positive in a northward direction).", "dimensions": "alevel site time1", "out_name": "va", "type": "real", @@ -1307,6 +1385,7 @@ "ok_max_mean_abs": "" }, "vas": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "northward_wind", "units": "m s-1", @@ -1324,12 +1403,13 @@ "ok_max_mean_abs": "" }, "wap": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "lagrangian_tendency_of_air_pressure", "units": "Pa s-1", "cell_methods": "area: point time: point", "cell_measures": "", - "long_name": "omega (=dp/dt)", + "long_name": "Omega (=dp/dt)", "comment": "Omega (vertical velocity in pressure coordinates, positive downwards)", "dimensions": "alevel site time1", "out_name": "wap", @@ -1341,13 +1421,14 @@ "ok_max_mean_abs": "" }, "zg": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "geopotential_height", "units": "m", "cell_methods": "area: point time: point", "cell_measures": "", "long_name": "Geopotential Height", - "comment": "", + "comment": "Geopotential is the sum of the specific gravitational potential energy relative to the geoid and the specific centripetal potential energy. Geopotential height is the geopotential divided by the standard acceleration due to gravity. It is numerically similar to the altitude (or geometric height) and not to the quantity with standard name height, which is relative to the surface.", "dimensions": "alevel site time1", "out_name": "zg", "type": "real", diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_CFsubhrOff.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_CFsubhrOff.json deleted file mode 100644 index 92ad59e513..0000000000 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_CFsubhrOff.json +++ /dev/null @@ -1,171 +0,0 @@ -{ - "Header": { - "data_specs_version": "01.00.10", - "table_id": "Table CFsubhrOff", - "realm": "atmos", - "frequency": "subhr", - "cmor_version": "3.2", - "table_date": "10 May 2017", - "missing_value": "1e20", - "product": "model-output", - "approx_interval": "", - "generic_levels": "", - "mip_era": "CMIP6", - "Conventions": "CF-1.7 CMIP-6.0" - }, - "variable_entry": { - "cfadDbze94": { - "modeling_realm": "atmos", - "standard_name": "histogram_of_equivalent_reflectivity_factor_over_height_above_reference_ellipsoid", - "units": "1.0", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "CloudSat Radar Reflectivity", - "comment": "CFAD (Cloud Frequency Altitude Diagrams) are frequency distributions of radar reflectivity (or lidar scattering ratio) as a function of altitude. The variable cfadDbze94 is defined as the simulated relative frequency of occurrence of radar reflectivity in sampling volumes defined by altitude bins. The radar is observing at a frequency of 94GHz.", - "dimensions": "longitude latitude alt40 dbze time", - "out_name": "cfadDbze94", - "type": "real", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "cfadLidarsr532": { - "modeling_realm": "atmos", - "standard_name": "histogram_of_backscattering_ratio_over_height_above_reference_ellipsoid", - "units": "1.0", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "CALIPSO Scattering Ratio", - "comment": "CFAD (Cloud Frequency Altitude Diagrams) are frequency distributions of radar reflectivity (or lidar scattering ratio) as a function of altitude. The variable cfadLidarsr532 is defined as the simulated relative frequency of lidar scattering ratio in sampling volumes defined by altitude bins. The lidar is observing at a wavelength of 532nm.", - "dimensions": "longitude latitude alt40 scatratio time", - "out_name": "cfadLidarsr532", - "type": "real", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "clcalipso": { - "modeling_realm": "atmos", - "standard_name": "cloud_area_fraction_in_atmosphere_layer", - "units": "%", - "cell_methods": "time: mean", - "cell_measures": "area: areacella", - "long_name": "CALIPSO Cloud Fraction", - "comment": "Percentage cloud cover at CALIPSO standard heights.", - "dimensions": "longitude latitude alt40 time", - "out_name": "clcalipso", - "type": "real", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "clcalipso2": { - "modeling_realm": "atmos", - "standard_name": "cloud_area_fraction_in_atmosphere_layer", - "units": "%", - "cell_methods": "time: mean", - "cell_measures": "area: areacella", - "long_name": "CALIPSO Cloud Fraction Undetected by CloudSat", - "comment": "Clouds detected by CALIPSO but below the detectability threshold of CloudSat", - "dimensions": "longitude latitude alt40 time", - "out_name": "clcalipso2", - "type": "real", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "clhcalipso": { - "modeling_realm": "atmos", - "standard_name": "cloud_area_fraction_in_atmosphere_layer", - "units": "%", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "CALIPSO High Level Cloud Fraction", - "comment": "Percentage cloud cover in layer centred on 220hPa", - "dimensions": "longitude latitude time p220", - "out_name": "clhcalipso", - "type": "real", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "cllcalipso": { - "modeling_realm": "atmos", - "standard_name": "cloud_area_fraction_in_atmosphere_layer", - "units": "%", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "CALIPSO Low Level Cloud Fraction", - "comment": "Percentage cloud cover in layer centred on 840hPa", - "dimensions": "longitude latitude time p840", - "out_name": "cllcalipso", - "type": "real", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "clmcalipso": { - "modeling_realm": "atmos", - "standard_name": "cloud_area_fraction_in_atmosphere_layer", - "units": "%", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "CALIPSO Mid Level Cloud Fraction", - "comment": "Percentage cloud cover in layer centred on 560hPa", - "dimensions": "longitude latitude time p560", - "out_name": "clmcalipso", - "type": "real", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "cltcalipso": { - "modeling_realm": "atmos", - "standard_name": "cloud_area_fraction", - "units": "%", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "CALIPSO Total Cloud Fraction", - "comment": "", - "dimensions": "longitude latitude time", - "out_name": "cltcalipso", - "type": "real", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "parasolRefl": { - "modeling_realm": "atmos", - "standard_name": "toa_bidirectional_reflectance", - "units": "1.0", - "cell_methods": "time: mean", - "cell_measures": "area: areacella", - "long_name": "PARASOL Reflectance", - "comment": "Simulated reflectance from PARASOL as seen at the top of the atmosphere for 5 solar zenith angles. Valid only over ocean and for one viewing direction (viewing zenith angle of 30 degrees and relative azimuth angle 320 degrees).", - "dimensions": "longitude latitude sza5 time", - "out_name": "parasolRefl", - "type": "real", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - } - } -} diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_CV.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_CV.json index a8050fc2e2..82b9c6a5e7 100644 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_CV.json +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_CV.json @@ -33,91 +33,180 @@ "variant_label" ], "version_metadata":{ + "CV_collection_modified":"Thu Mar 7 12:27:59 2019 -0800", + "CV_collection_version":"6.2.19.1", "author":"Paul J. Durack ", - "creation_date":"Wed Apr 26 09:19:24 2017 -0700", + "experiment_id_CV_modified":"Tue Mar 5 14:27:11 2019 -0800", + "experiment_id_CV_note":"Revise GeoMIP experiment_id values", "institution_id":"PCMDI", - "latest_tag_point":"3.2.3 (29; g9be7426)", - "note":"Revise source_id BESM-2-7", - "previous_commit":"66ea1f100a70977e3400c65e14f0c91fc6590ac6" + "previous_commit":"1689bc7f7ed25237ca771352a8b3b6014251c3a4", + "specs_doc":"v6.2.7 (10th September 2018; https://goo.gl/v1drZl)" + }, + "activity_id":{ + "AerChemMIP":"Aerosols and Chemistry Model Intercomparison Project", + "C4MIP":"Coupled Climate Carbon Cycle Model Intercomparison Project", + "CDRMIP":"Carbon Dioxide Removal Model Intercomparison Project", + "CFMIP":"Cloud Feedback Model Intercomparison Project", + "CMIP":"CMIP DECK: 1pctCO2, abrupt4xCO2, amip, esm-piControl, esm-historical, historical, and piControl experiments", + "CORDEX":"Coordinated Regional Climate Downscaling Experiment", + "DAMIP":"Detection and Attribution Model Intercomparison Project", + "DCPP":"Decadal Climate Prediction Project", + "DynVarMIP":"Dynamics and Variability Model Intercomparison Project", + "FAFMIP":"Flux-Anomaly-Forced Model Intercomparison Project", + "GMMIP":"Global Monsoons Model Intercomparison Project", + "GeoMIP":"Geoengineering Model Intercomparison Project", + "HighResMIP":"High-Resolution Model Intercomparison Project", + "ISMIP6":"Ice Sheet Model Intercomparison Project for CMIP6", + "LS3MIP":"Land Surface, Snow and Soil Moisture", + "LUMIP":"Land-Use Model Intercomparison Project", + "OMIP":"Ocean Model Intercomparison Project", + "PAMIP":"Polar Amplification Model Intercomparison Project", + "PMIP":"Palaeoclimate Modelling Intercomparison Project", + "RFMIP":"Radiative Forcing Model Intercomparison Project", + "SIMIP":"Sea Ice Model Intercomparison Project", + "ScenarioMIP":"Scenario Model Intercomparison Project", + "VIACSAB":"Vulnerability, Impacts, Adaptation and Climate Services Advisory Board", + "VolMIP":"Volcanic Forcings Model Intercomparison Project" }, - "activity_id":[ - "AerChemMIP", - "C4MIP", - "CFMIP", - "CMIP", - "CORDEX", - "DAMIP", - "DCPP", - "DynVarMIP", - "FAFMIP", - "GMMIP", - "GeoMIP", - "HighResMIP", - "ISMIP6", - "LS3MIP", - "LUMIP", - "OMIP", - "PMIP", - "RFMIP", - "SIMIP", - "ScenarioMIP", - "VIACSAB", - "VolMIP" - ], "institution_id":{ + "AER":"Research and Climate Group, Atmospheric and Environmental Research, 131 Hartwell Avenue, Lexington, MA 02421, USA", + "AS-RCEC":"Research Center for Environmental Changes, Academia Sinica, Nankang, Taipei 11529, Taiwan", "AWI":"Alfred Wegener Institute, Helmholtz Centre for Polar and Marine Research, Am Handelshafen 12, 27570 Bremerhaven, Germany", + "BCC":"Beijing Climate Center, Beijing 100081, China", "BNU":"Beijing Normal University, Beijing 100875, China", "CAMS":"Chinese Academy of Meteorological Sciences, Beijing 100081, China", + "CAS":"Chinese Academy of Sciences, Beijing 100029, China", "CCCR-IITM":"Centre for Climate Change Research, Indian Institute of Tropical Meteorology Pune, Maharashtra 411 008, India", - "CCCma":"Canadian Centre for Climate Modelling and Analysis, Victoria, BC V8P 5C2, Canada", + "CCCma":"Canadian Centre for Climate Modelling and Analysis, Environment and Climate Change Canada, Victoria, BC V8P 5C2, Canada", "CMCC":"Fondazione Centro Euro-Mediterraneo sui Cambiamenti Climatici, Lecce 73100, Italy", - "CNRM-CERFACS":"CNRM (Centre National de Recherches Meteorologiques, Toulouse 31057, France), CERFACS (Centre Europeen de Recherche et de Formation Avancee en Calcul Scientifique, Toulouse 31100, France)", - "COLA-CFS":"Center for Ocean-Land-Atmosphere Studies, Fairfax, VA 22030, USA", + "CNRM-CERFACS":"CNRM (Centre National de Recherches Meteorologiques, Toulouse 31057, France), CERFACS (Centre Europeen de Recherche et de Formation Avancee en Calcul Scientifique, Toulouse 31057, France)", "CSIR-CSIRO":"CSIR (Council for Scientific and Industrial Research - Natural Resources and the Environment, Pretoria, 0001, South Africa), CSIRO (Commonwealth Scientific and Industrial Research Organisation and Bureau of Meteorology, Melbourne, Victoria 3208, Australia)", - "CSIRO-BOM":"Commonwealth Scientific and Industrial Research Organisation and Bureau of Meteorology, Melbourne, Victoria 3208, Australia", - "EC-Earth-Consortium":"KNMI, The Netherlands; SMHI, Sweden; DMI, Denmark; AEMET, Spain; Met Eireann, Ireland; CNR-ISAC, Italy; Instituto de Meteorologia, Portugal; FMI, Finland; BSC, Spain; Centro de Geofisica, University of Lisbon, Portugal; ENEA, Italy; Geomar, Germany; Geophysical Institute, University of Bergen, Norway; ICHEC, Ireland; ICTP, Italy; IMAU, The Netherlands; IRV, Sweden; Lund University, Sweden; Meteorologiska Institutionen, Stockholms University, Sweden; Niels Bohr Institute, University of Copenhagen, Denmark; NTNU, Norway; SARA, The Netherlands; Unite ASTR, Belgium; Universiteit Utrecht, The Netherlands; Universiteit Wageningen, The Netherlands; University College Dublin, Ireland; Vrije Universiteit Amsterdam, the Netherlands; University of Helsinki, Finland; KIT, Karlsruhe, Germany; USC, University of Santiago de Compostela, Spain; Uppsala Universitet, Sweden; NLeSC, Netherlands eScience Center, The Netherlands", - "FIO-RONM":"FIO (First Institute of Oceanography, State Oceanic Administration, Qingdao 266061, China), RONM (Laboratory for Regional Oceanography and Numerical Modeling, Qingdao National Laboratory for Marine Science and Technology, Qingdao 266237, China)", - "INM":"Institute for Numerical Mathematics, Moscow 119991, Russia", + "CSIRO":"Commonwealth Scientific and Industrial Research Organisation, Aspendale, Victoria 3195, Australia", + "CSIRO-ARCCSS-BoM":"Commonwealth Scientific and Industrial Research Organisation, Australian Research Council Centre of Excellence for Climate System Science, and Bureau of Meteorology, Aspendale, Victoria 3195, Australia", + "DKRZ":"Deutsches Klimarechenzentrum, Hamburg 20146, Germany", + "DWD":"Deutscher Wetterdienst, Offenbach am Main 63067, Germany", + "E3SM-Project":"LLNL (Lawrence Livermore National Laboratory, Livermore, CA 94550, USA); ANL (Argonne National Laboratory, Argonne, IL 60439, USA); BNL (Brookhaven National Laboratory, Upton, NY 11973, USA); LANL (Los Alamos National Laboratory, Los Alamos, NM 87545, USA); LBNL (Lawrence Berkeley National Laboratory, Berkeley, CA 94720, USA); ORNL (Oak Ridge National Laboratory, Oak Ridge, TN 37831, USA); PNNL (Pacific Northwest National Laboratory, Richland, WA 99352, USA); SNL (Sandia National Laboratories, Albuquerque, NM 87185, USA). Mailing address: LLNL Climate Program, c/o David C. Bader, Principal Investigator, L-103, 7000 East Avenue, Livermore, CA 94550, USA", + "EC-Earth-Consortium":"AEMET, Spain; BSC, Spain; CNR-ISAC, Italy; DMI, Denmark; ENEA, Italy; FMI, Finland; Geomar, Germany; ICHEC, Ireland; ICTP, Italy; IDL, Portugal; IMAU, The Netherlands; IPMA, Portugal; KIT, Karlsruhe, Germany; KNMI, The Netherlands; Lund University, Sweden; Met Eireann, Ireland; NLeSC, The Netherlands; NTNU, Norway; Oxford University, UK; surfSARA, The Netherlands; SMHI, Sweden; Stockholm University, Sweden; Unite ASTR, Belgium; University College Dublin, Ireland; University of Bergen, Norway; University of Copenhagen, Denmark; University of Helsinki, Finland; University of Santiago de Compostela, Spain; Uppsala University, Sweden; Utrecht University, The Netherlands; Vrije Universiteit Amsterdam, the Netherlands; Wageningen University, The Netherlands. Mailing address: EC-Earth consortium, Rossby Center, Swedish Meteorological and Hydrological Institute/SMHI, SE-601 76 Norrkoping, Sweden", + "ECMWF":"European Centre for Medium-Range Weather Forecasts, Reading RG2 9AX, UK", + "FIO-QLNM":"FIO (First Institute of Oceanography, State Oceanic Administration, Qingdao 266061, China), QNLM (Qingdao National Laboratory for Marine Science and Technology, Qingdao 266237, China)", + "HAMMOZ-Consortium":"ETH Zurich, Switzerland; Max Planck Institut fur Meteorologie, Germany; Forschungszentrum Julich, Germany; University of Oxford, UK; Finnish Meteorological Institute, Finland; Leibniz Institute for Tropospheric Research, Germany; Center for Climate Systems Modeling (C2SM) at ETH Zurich, Switzerland", + "INM":"Institute for Numerical Mathematics, Russian Academy of Science, Moscow 119991, Russia", "INPE":"National Institute for Space Research, Cachoeira Paulista, SP 12630-000, Brazil", "IPSL":"Institut Pierre Simon Laplace, Paris 75252, France", - "LASG-IAP":"Institute of Atmospheric Physics, Chinese Academy of Sciences, Beijing 100029, China", + "KIOST":"Korea Institute of Ocean Science & Technology, Busan 49111, Republic of Korea", "MESSy-Consortium":"The Modular Earth Submodel System (MESSy) Consortium, represented by the Institute for Physics of the Atmosphere, Deutsches Zentrum fur Luft- und Raumfahrt (DLR), Wessling, Bavaria 82234, Germany", - "MIROC":"JAMSTEC (Japan Agency for Marine-Earth Science and Technology, Kanagawa 236-0001, Japan), AORI (Atmosphere and Ocean Research Institute, The University of Tokyo, Chiba 277-8564, Japan), NIES (National Institute for Environmental Studies, Ibaraki 305-8506, Japan), and AICS (RIKEN Advanced Institute for Computational Science, Hyogo 650-0047, Japan)", + "MIROC":"JAMSTEC (Japan Agency for Marine-Earth Science and Technology, Kanagawa 236-0001, Japan), AORI (Atmosphere and Ocean Research Institute, The University of Tokyo, Chiba 277-8564, Japan), NIES (National Institute for Environmental Studies, Ibaraki 305-8506, Japan), and R-CCS (RIKEN Center for Computational Science, Hyogo 650-0047, Japan)", "MOHC":"Met Office Hadley Centre, Fitzroy Road, Exeter, Devon, EX1 3PB, UK", "MPI-M":"Max Planck Institute for Meteorology, Hamburg 20146, Germany", "MRI":"Meteorological Research Institute, Tsukuba, Ibaraki 305-0052, Japan", "NASA-GISS":"Goddard Institute for Space Studies, New York, NY 10025, USA", - "NCAR":"National Center for Atmospheric Research, Boulder, CO 80307, USA", - "NCC":"NorESM Climate modeling Consortium consisting of CICERO (Center for International Climate and Environmental Research, Oslo 0349), MET-Norway (Norwegian Meteorological Institute, Oslo 0313), NERSC (Nansen Environmental and Remote Sensing Center, Bergen 5006), NILU (Norwegian Institute for Air Research, Kjeller 2027), UiB (University of Bergen, Bergen 5007), UiO (University of Oslo, Oslo 0313) and UNI (Uni Research, Bergen 5008), Norway", + "NCAR":"National Center for Atmospheric Research, Climate and Global Dynamics Laboratory, 1850 Table Mesa Drive, Boulder, CO 80305, USA", + "NCC":"NorESM Climate modeling Consortium consisting of CICERO (Center for International Climate and Environmental Research, Oslo 0349), MET-Norway (Norwegian Meteorological Institute, Oslo 0313), NERSC (Nansen Environmental and Remote Sensing Center, Bergen 5006), NILU (Norwegian Institute for Air Research, Kjeller 2027), UiB (University of Bergen, Bergen 5007), UiO (University of Oslo, Oslo 0313) and UNI (Uni Research, Bergen 5008), Norway. Mailing address: NCC, c/o MET-Norway, Henrik Mohns plass 1, Oslo 0313, Norway", "NERC":"Natural Environment Research Council, STFC-RAL, Harwell, Oxford, OX11 0QX, UK", "NIMS-KMA":"National Institute of Meteorological Sciences/Korea Meteorological Administration, Climate Research Division, Seoho-bukro 33, Seogwipo-si, Jejudo 63568, Republic of Korea", + "NIWA":"National Institute of Water and Atmospheric Research, Hataitai, Wellington 6021, New Zealand", "NOAA-GFDL":"National Oceanic and Atmospheric Administration, Geophysical Fluid Dynamics Laboratory, Princeton, NJ 08540, USA", - "NOAA-NCEP":"National Oceanic and Atmospheric Administration, National Centers for Environmental Prediction, Camp Springs, MD 20746, USA", "NUIST":"Nanjing University of Information Science and Technology, Nanjing, 210044, China", "PCMDI":"Program for Climate Model Diagnosis and Intercomparison, Lawrence Livermore National Laboratory, Livermore, CA 94550, USA", - "THU":"Department of Earth System Science, Tsinghua University, Beijing 100084, China" + "RTE-RRTMGP-Consortium":"AER (Atmospheric and Environmental Research, Lexington, MA 02421, USA); UColorado (University of Colorado, Boulder, CO 80309, USA). Mailing address: AER c/o Eli Mlawer, 131 Hartwell Avenue, Lexington, MA 02421, USA", + "SNU":"Seoul National University, Seoul 08826, Republic of Korea", + "THU":"Department of Earth System Science, Tsinghua University, Beijing 100084, China", + "UA":"Department of Geosciences, University of Arizona, Tucson, AZ 85721, USA", + "UHH":"Universitat Hamburg, Hamburg 20148, Germany", + "UTAS":"Institute for Marine and Antarctic Studies, University of Tasmania, Hobart, Tasmania 7001, Australia", + "UofT":"Department of Physics, University of Toronto, 60 St George Street, Toronto, ON M5S1A7, Canada" }, "source_id":{ - "ACCESS-1-0":{ + "ACCESS-CM2":{ "activity_participation":[ - "CMIP" + "CMIP", + "FAFMIP", + "OMIP", + "RFMIP", + "ScenarioMIP" + ], + "cohort":[ + "Registered" + ], + "institution_id":[ + "CSIRO-ARCCSS-BoM" + ], + "source_id":"ACCESS-CM2", + "source":"ACCESS-CM2 (2018): \naerosol: UKCA-GLOMAP-mode\natmos: MetUM-HadGEM3-GA7.1 (N96; 192 x 144 longitude/latitude; 85 levels; top level 85 km)\natmosChem: none\nland: CABLE2.3.5\nlandIce: none\nocean: ACCESS-OM2 (GFDL-MOM5, tripolar primarily 1deg; 360 x 300 longitude/latitude; 50 levels; top grid cell 0-10 m)\nocnBgchem: none\nseaIce: CICE5.1 (same grid as ocean)" + }, + "ACCESS-ESM1-5":{ + "activity_participation":[ + "C4MIP", + "CDRMIP", + "CMIP", + "OMIP", + "RFMIP", + "ScenarioMIP" + ], + "cohort":[ + "Registered" + ], + "institution_id":[ + "CSIRO" + ], + "source_id":"ACCESS-ESM1-5", + "source":"ACCESS-ESM1.5 (2018): \naerosol: CLASSIC (v1.0)\natmos: HadGAM2 (r1.1, N96; 192 x 145 longitude/latitude; 38 levels; top level 39255 m)\natmosChem: none\nland: CABLE2.2.3\nlandIce: none\nocean: ACCESS-OM2 (MOM5, tripolar primarily 1deg; 360 x 300 longitude/latitude; 50 levels; top grid cell 0-10 m)\nocnBgchem: WOMBAT1.0 (same grid as ocean)\nseaIce: CICE5.1 (same grid as ocean)" + }, + "ARTS-2-3":{ + "activity_participation":[ + "RFMIP" ], "cohort":[ - "CMIP5" + "Registered" ], "institution_id":[ - "CSIRO-BOM" + "UHH" ], - "source_id":"ACCESS-1-0", - "source":"ACCESS 1.0 (2011): \naerosol: CLASSIC (v1.0)\natmos: HadGAM2 (r1.1; N96, 192 x 145 longitude/latitude; 38 levels; top level 39255 m)\natmosChem: none\nland: MOSES2.2\nlandIce: none\nocean: ACCESS-OM (MOM4p1; tripolar primarily 1deg, 360 x 300 longitude/latitude; 50 levels; top grid cell 0-10 m)\nocnBgchem: none\nseaIce: CICE4.1" + "source_id":"ARTS-2-3", + "source":"ARTS 2.3 (2015): \naerosol: none\natmos: none\natmosChem: none\nland: none\nlandIce: none\nocean: none\nocnBgchem: none\nseaIce: none" }, - "AWI-CM-1-0":{ + "AWI-CM-1-1-HR":{ "activity_participation":[ "CMIP", "CORDEX", "HighResMIP", "OMIP", - "PMIP", + "SIMIP", + "VIACSAB" + ], + "cohort":[ + "Registered" + ], + "institution_id":[ + "AWI" + ], + "source_id":"AWI-CM-1-1-HR", + "source":"AWI-CM 1.1 HR (2018): \naerosol: none\natmos: ECHAM6.3.04p1 (T127L95 native atmosphere T127 gaussian grid; 384 x 192 longitude/latitude; 95 levels; top level 80 km)\natmosChem: none\nland: JSBACH 3.20\nlandIce: none\nocean: FESOM 1.4 (unstructured grid in the horizontal with 1306775 wet nodes; 46 levels; top grid cell 0-5 m)\nocnBgchem: none\nseaIce: FESOM 1.4" + }, + "AWI-CM-1-1-LR":{ + "activity_participation":[ + "CMIP", + "CORDEX", + "HighResMIP", + "OMIP", + "SIMIP", + "ScenarioMIP", + "VIACSAB" + ], + "cohort":[ + "Registered" + ], + "institution_id":[ + "AWI" + ], + "source_id":"AWI-CM-1-1-LR", + "source":"AWI-CM 1.1 LR (2018): \naerosol: none\natmos: ECHAM6.3.04p1 (T63L47 native atmosphere T63 gaussian grid; 192 x 96 longitude/latitude; 47 levels; top level 80 km)\natmosChem: none\nland: JSBACH 3.20\nlandIce: none\nocean: FESOM 1.4 (unstructured grid in the horizontal with 126859 wet nodes; 46 levels; top grid cell 0-5 m)\nocnBgchem: none\nseaIce: FESOM 1.4" + }, + "AWI-CM-1-1-MR":{ + "activity_participation":[ + "CMIP", + "CORDEX", + "OMIP", "SIMIP", "ScenarioMIP", "VIACSAB" @@ -128,8 +217,72 @@ "institution_id":[ "AWI" ], - "source_id":"AWI-CM-1-0", - "source":"AWI-CM 1.0 (2017): \naerosol: none\natmos: ECHAM6.3.02p4 (T127L95 native atmosphere T127 gaussian grid; 384 x 192 longitude/latitude; 95 levels; top level 80 km)\natmosChem: none\nland: JSBACH 3.10\nlandIce: none\nocean: FESOM 1.4 (unstructured grid in the horizontal with 830305 wet nodes; 46 levels; top grid cell 0-5 m)\nocnBgchem: none\nseaIce: FESOM 1.4" + "source_id":"AWI-CM-1-1-MR", + "source":"AWI-CM 1.1 MR (2018): \naerosol: none\natmos: ECHAM6.3.04p1 (T127L95 native atmosphere T127 gaussian grid; 384 x 192 longitude/latitude; 95 levels; top level 80 km)\natmosChem: none\nland: JSBACH 3.20\nlandIce: none\nocean: FESOM 1.4 (unstructured grid in the horizontal with 830305 wet nodes; 46 levels; top grid cell 0-5 m)\nocnBgchem: none\nseaIce: FESOM 1.4" + }, + "AWI-ESM-1-1-LR":{ + "activity_participation":[ + "CMIP", + "PMIP" + ], + "cohort":[ + "Registered" + ], + "institution_id":[ + "AWI" + ], + "source_id":"AWI-ESM-1-1-LR", + "source":"AWI-ESM 1.1 LR (2018): \naerosol: none\natmos: ECHAM6.3.04p1 (T63L47 native atmosphere T63 gaussian grid; 192 x 96 longitude/latitude; 47 levels; top level 80 km)\natmosChem: none\nland: JSBACH 3.20 with dynamic vegetation\nlandIce: none\nocean: FESOM 1.4 (unstructured grid in the horizontal with 126859 wet nodes; 46 levels; top grid cell 0-5 m)\nocnBgchem: none\nseaIce: FESOM 1.4" + }, + "BCC-CSM2-HR":{ + "activity_participation":[ + "CMIP", + "HighResMIP" + ], + "cohort":[ + "Registered" + ], + "institution_id":[ + "BCC" + ], + "source_id":"BCC-CSM2-HR", + "source":"BCC-CSM 2 HR (2017): \naerosol: none\natmos: BCC_AGCM3_HR (T266; 800 x 400 longitude/latitude; 56 levels; top level 0.1 hPa)\natmosChem: none\nland: BCC_AVIM2\nlandIce: none\nocean: MOM4 (1/3 deg 10S-10N, 1/3-1 deg 10-30 N/S, and 1 deg in high latitudes; 360 x 232 longitude/latitude; 40 levels; top grid cell 0-10 m)\nocnBgchem: none\nseaIce: SIS2" + }, + "BCC-CSM2-MR":{ + "activity_participation":[ + "C4MIP", + "CFMIP", + "CMIP", + "DAMIP", + "DCPP", + "GMMIP", + "LS3MIP", + "LUMIP", + "RFMIP", + "ScenarioMIP" + ], + "cohort":[ + "Registered" + ], + "institution_id":[ + "BCC" + ], + "source_id":"BCC-CSM2-MR", + "source":"BCC-CSM 2 MR (2017): \naerosol: none\natmos: BCC_AGCM3_MR (T106; 320 x 160 longitude/latitude; 46 levels; top level 1.46 hPa)\natmosChem: none\nland: BCC_AVIM2\nlandIce: none\nocean: MOM4 (1/3 deg 10S-10N, 1/3-1 deg 10-30 N/S, and 1 deg in high latitudes; 360 x 232 longitude/latitude; 40 levels; top grid cell 0-10 m)\nocnBgchem: none\nseaIce: SIS2" + }, + "BCC-ESM1":{ + "activity_participation":[ + "AerChemMIP", + "CMIP" + ], + "cohort":[ + "Registered" + ], + "institution_id":[ + "BCC" + ], + "source_id":"BCC-ESM1", + "source":"BCC-ESM 1 (2017): \naerosol: none\natmos: BCC_AGCM3_LR (T42; 128 x 64 longitude/latitude; 26 levels; top level 2.19 hPa)\natmosChem: BCC-AGCM3-Chem\nland: BCC_AVIM2\nlandIce: none\nocean: MOM4 (1/3 deg 10S-10N, 1/3-1 deg 10-30 N/S, and 1 deg in high latitudes; 360 x 232 longitude/latitude; 40 levels; top grid cell 0-10 m)\nocnBgchem: none\nseaIce: SIS2" }, "BESM-2-7":{ "activity_participation":[ @@ -150,10 +303,13 @@ "BNU-ESM-1-1":{ "activity_participation":[ "C4MIP", + "CDRMIP", + "CFMIP", "CMIP", "GMMIP", "GeoMIP", "OMIP", + "RFMIP", "ScenarioMIP" ], "cohort":[ @@ -165,7 +321,7 @@ "source_id":"BNU-ESM-1-1", "source":"BNU-ESM 1.1 (2016): \naerosol: CAM-chem; semi-interactive\natmos: CAM4 (2deg; 144 x 96 longitude/latitude; 26 levels; top level 2.194 mb)\natmosChem: none\nland: CoLM version 2014 with carbon-nitrogen interactions\nlandIce: none\nocean: MOM4p1 (tripolar, primarily 1deg latitude/longitude, down to 1/3deg within 30deg of the equatorial tropics; 360 x 200 longitude/latitude; 50 levels; top grid cell 0-10 m)\nocnBgchem: Dynamic ecosystem-carbon model version 1\nseaIce: CICE4.1" }, - "CAMS_CSM1-0":{ + "CAMS-CSM1-0":{ "activity_participation":[ "CMIP" ], @@ -175,15 +331,112 @@ "institution_id":[ "CAMS" ], - "source_id":"CAMS_CSM1-0", + "source_id":"CAMS-CSM1-0", "source":"CAMS_CSM 1.0 (2016): \naerosol: none\natmos: ECHAM5_CAMS (T106; 320 x 160 longitude/latitude; 31 levels; top level 10 mb)\natmosChem: none\nland: CoLM 1.0\nlandIce: none\nocean: MOM4 (tripolar; 360 x 200 longitude/latitude, primarily 1deg latitude/longitude, down to 1/3deg within 30deg of the equatorial tropics; 50 levels; top grid cell 0-10 m)\nocnBgchem: none\nseaIce: SIS 1.0" }, + "CAS-ESM1-0":{ + "activity_participation":[ + "AerChemMIP", + "C4MIP", + "CFMIP", + "CMIP", + "CORDEX", + "DAMIP", + "DynVarMIP", + "FAFMIP", + "GMMIP", + "GeoMIP", + "HighResMIP", + "LS3MIP", + "LUMIP", + "OMIP", + "PMIP", + "SIMIP", + "ScenarioMIP", + "VIACSAB", + "VolMIP" + ], + "cohort":[ + "Registered" + ], + "institution_id":[ + "CAS" + ], + "source_id":"CAS-ESM1-0", + "source":"CAS-ESM 1.0 (2015): \naerosol: IAP AACM\natmos: IAP AGCM4.1 (Finite difference dynamical core; 256 x 128 longitude/latitude; 30 levels; top level 2.2 hPa)\natmosChem: IAP AACM\nland: CoLM\nlandIce: none\nocean: LICOM2.0 (LICOM2.0, primarily 1deg; 362 x 196 longitude/latitude; 30 levels; top grid cell 0-10 m)\nocnBgchem: IAP OBGCM\nseaIce: CICE4" + }, + "CESM2":{ + "activity_participation":[ + "AerChemMIP", + "C4MIP", + "CDRMIP", + "CFMIP", + "CMIP", + "CORDEX", + "DAMIP", + "DCPP", + "DynVarMIP", + "GMMIP", + "GeoMIP", + "HighResMIP", + "ISMIP6", + "LS3MIP", + "LUMIP", + "OMIP", + "PAMIP", + "PMIP", + "RFMIP", + "SIMIP", + "ScenarioMIP", + "VIACSAB", + "VolMIP" + ], + "cohort":[ + "Registered" + ], + "institution_id":[ + "NCAR" + ], + "source_id":"CESM2", + "source":"CESM2 (2018): \naerosol: MAM4 (same grid as atmos)\natmos: CAM6 (0.9x1.25 finite volume grid; 288 x 192 longitude/latitude; 32 levels; top level 2.25 mb)\natmosChem: MAM4 (same grid as atmos)\nland: CLM5 (same grid as atmos)\nlandIce: CISM2.1\nocean: POP2 (320x384 longitude/latitude; 60 levels; top grid cell 0-10 m)\nocnBgchem: MARBL (same grid as ocean)\nseaIce: CICE5.1 (same grid as ocean)" + }, + "CESM2-SE":{ + "activity_participation":[ + "CMIP", + "HighResMIP" + ], + "cohort":[ + "Registered" + ], + "institution_id":[ + "NCAR" + ], + "source_id":"CESM2-SE", + "source":"CESM2-SE (2019): \naerosol: MAM4 (same grid as atmos)\natmos: CAM6 (0.25 degree spectral element; 777602 cells; 30 levels; top level 2.25 mb)\natmosChem: MAM4 (same grid as atmos)\nland: CLM5 (same grid as atmos)\nlandIce: CISM2.1\nocean: POP2 (320 x 384 longitude/latitude; 60 levels; top grid cell 0-10 m)\nocnBgchem: MARBL (same grid as ocean)\nseaIce: CICE5.1 (same grid as ocean)" + }, + "CESM2-WACCM":{ + "activity_participation":[ + "AerChemMIP", + "CMIP", + "GeoMIP", + "ScenarioMIP" + ], + "cohort":[ + "Registered" + ], + "institution_id":[ + "NCAR" + ], + "source_id":"CESM2-WACCM", + "source":"CESM2-WACCM (2018): \naerosol: MAM4 (same grid as atmos)\natmos: WACCM6 (0.9x1.25 finite volume grid; 288 x 192 longitude/latitude; 70 levels; top level 4.5e-06 mb)\natmosChem: MAM4 (same grid as atmos)\nland: CLM5 (same grid as atmos)\nlandIce: CISM2.1\nocean: POP2 (320 x 384 longitude/latitude; 60 levels; top grid cell 0-10 m)\nocnBgchem: MARBL (same grid as ocean)\nseaIce: CICE5.1 (same grid as ocean)" + }, "CIESM":{ "activity_participation":[ "CFMIP", "CMIP", "CORDEX", "GMMIP", + "HighResMIP", "OMIP", "SIMIP", "ScenarioMIP" @@ -287,7 +540,20 @@ }, "CNRM-CM6-1":{ "activity_participation":[ - "" + "CFMIP", + "CMIP", + "DAMIP", + "DCPP", + "FAFMIP", + "GMMIP", + "HighResMIP", + "ISMIP6", + "LS3MIP", + "OMIP", + "PAMIP", + "PMIP", + "RFMIP", + "ScenarioMIP" ], "cohort":[ "Registered" @@ -296,11 +562,15 @@ "CNRM-CERFACS" ], "source_id":"CNRM-CM6-1", - "source":"CNRM-CM6-1 (2016): \naerosol: climatological fields computed by TACTIC (v2.0)\natmos: Arpege 6.2 (Tl127; 91 levels; top level 78.4 km)\natmosChem: OZL_v2\nland: Surfex 8.0c\nlandIce: none (except for some FAFMIP experiments)\nocean: Nemo 3.6 (eORCA1; tripolar primarily 1deg latitude/longitude; 75 levels; top grid cell 0-1 m)\nocnBgchem: none\nseaIce: Gelato 6.1" + "source":"CNRM-CM6-1 (2017): \naerosol: prescribed monthly fields computed by TACTIC_v2 scheme\natmos: Arpege 6.3 (T127; Gaussian Reduced with 24572 grid points in total distributed over 128 latitude circles (with 256 grid points per latitude circle between 30degN and 30degS reducing to 20 grid points per latitude circle at 88.9degN and 88.9degS); 91 levels; top level 78.4 km)\natmosChem: OZL_v2\nland: Surfex 8.0c\nlandIce: GRISLI: Collaborating with l'Institut des Geosciences de l'Environnement in Grenoble on offline ice-sheet simulations\nocean: Nemo 3.6 (eORCA1, tripolar primarily 1deg; 362 x 294 longitude/latitude; 75 levels; top grid cell 0-1 m)\nocnBgchem: none\nseaIce: Gelato 6.1" }, "CNRM-CM6-1-HR":{ "activity_participation":[ - "" + "CMIP", + "DCPP", + "HighResMIP", + "OMIP", + "ScenarioMIP" ], "cohort":[ "Registered" @@ -309,11 +579,21 @@ "CNRM-CERFACS" ], "source_id":"CNRM-CM6-1-HR", - "source":"CNRM-CM6-1-HR (2016): \naerosol: climatological fields computed by TACTIC (v2.0)\natmos: Arpege 6.2 (Tl359; 91 levels; top level 78.4 km)\natmosChem: OZL_v2\nland: Surfex 8.0c\nlandIce: none\nocean: Nemo 3.6 (eORCA025; tripolar primarily 1/4deg latitude/longitude; 75 levels; top grid cell 0-1 m)\nocnBgchem: none\nseaIce: Gelato 6.1" + "source":"CNRM-CM6-1-HR (2017): \naerosol: prescribed monthly fields computed by TACTIC_v2 scheme\natmos: Arpege 6.3 (T359; Gaussian Reduced with 181724 grid points in total distributed over 360 latitude circles (with 720 grid points per latitude circle between 32.2degN and 32.2degS reducing to 18 grid points per latitude circle at 89.6degN and 89.6degS); 91 levels; top level 78.4 km)\natmosChem: OZL_v2\nland: Surfex 8.0c\nlandIce: none\nocean: Nemo 3.6 (eORCA025, tripolar primarily 1/4deg; 1442 x 1050 longitude/latitude; 75 levels; top grid cell 0-1 m)\nocnBgchem: none\nseaIce: Gelato 6.1" }, "CNRM-ESM2-1":{ "activity_participation":[ - "" + "AerChemMIP", + "C4MIP", + "CDRMIP", + "CMIP", + "CORDEX", + "GeoMIP", + "LS3MIP", + "LUMIP", + "OMIP", + "RFMIP", + "ScenarioMIP" ], "cohort":[ "Registered" @@ -322,11 +602,13 @@ "CNRM-CERFACS" ], "source_id":"CNRM-ESM2-1", - "source":"CNRM-ESM2-1 (2016): \naerosol: TACTIC (v2.0)\natmos: Arpege 6.2 (Tl127; 91 levels; top level 78.4 km)\natmosChem: REPROBUS-C (v2.0)\nland: Surfex 8.0c\nlandIce: none\nocean: Nemo 3.6 (eORCA1; tripolar primarily 1deg latitude/longitude; 75 levels; top grid cell 0-1 m)\nocnBgchem: Pisces 2.s\nseaIce: Gelato 6.1" + "source":"CNRM-ESM2-1 (2017): \naerosol: TACTIC_v2\natmos: Arpege 6.3 (T127; Gaussian Reduced with 24572 grid points in total distributed over 128 latitude circles (with 256 grid points per latitude circle between 30degN and 30degS reducing to 20 grid points per latitude circle at 88.9degN and 88.9degS); 91 levels; top level 78.4 km)\natmosChem: REPROBUS-C_v2\nland: Surfex 8.0c\nlandIce: none\nocean: Nemo 3.6 (eORCA1, tripolar primarily 1deg; 362 x 294 longitude/latitude; 75 levels; top grid cell 0-1 m)\nocnBgchem: Pisces 2.s\nseaIce: Gelato 6.1" }, "CNRM-ESM2-1-HR":{ "activity_participation":[ - "" + "CMIP", + "OMIP", + "ScenarioMIP" ], "cohort":[ "Registered" @@ -335,63 +617,97 @@ "CNRM-CERFACS" ], "source_id":"CNRM-ESM2-1-HR", - "source":"CNRM-ESM2-1-HR (2016): \naerosol: TACTIC (v2.0)\natmos: Arpege 6.2 (Tl359; 91 levels; top level 78.4 km)\natmosChem: OZL_v2\nland: Surfex 8.0c\nlandIce: none\nocean: Nemo 3.6 (eORCA025; tripolar primarily 1/4deg latitude/longitude; 75 levels; top grid cell 0-1 m)\nocnBgchem: Pisces 2.s\nseaIce: Gelato 6.1" + "source":"CNRM-ESM2-1-HR (2017): \naerosol: TACTIC_v2\natmos: Arpege 6.3 (T359; Gaussian Reduced with 181724 grid points in total distributed over 360 latitude circles (with 720 grid points per latitude circle between 32.2degN and 32.2degS reducing to 18 grid points per latitude circle at 89.6degN and 89.6degS); 91 levels; top level 78.4 km)\natmosChem: REPROBUS-C_v2\nland: Surfex 8.0c\nlandIce: none\nocean: Nemo 3.6 (eORCA025, tripolar primarily 1/4deg; 1442 x 1050 longitude/latitude; 75 levels; top grid cell 0-1 m)\nocnBgchem: Pisces 2.s\nseaIce: Gelato 6.1" }, - "EC-Earth3":{ + "CSIRO-Mk3L-1-3":{ "activity_participation":[ - "" + "CMIP", + "PMIP" ], "cohort":[ "Registered" ], "institution_id":[ - "EC-Earth-Consortium" + "UTAS" ], - "source_id":"EC-Earth3", - "source":"EC-Earth3 (2017): \naerosol: none\natmos: IFS cy36r4 (TL255, linearly reduced Gaussian grid equivalent to 512 x 256, 91 levels, top level: 0,01 hPa)\natmosChem: none\nland: HTESSEL (land surface scheme built in IFS)\nlandIce: none\nocean: NEMO3.6 (ORCA1 tripolar primarily 1 deg latitude/longitude with meridional refinement down to 1/3 degree in the tropics; 75 levels; top grid cell 5 m)\nocnBgchem: none\nseaIce: LIM3" + "source_id":"CSIRO-Mk3L-1-3", + "source":"CSIRO Mk3L 1.3 (2006): \naerosol: none\natmos: unnamed (R21; 64 x 56 longitude/latitude; 18 levels; top level 36355 m)\natmosChem: none\nland: unnamed\nlandIce: none\nocean: MOM1.x (128 x 112 longitude/latitude; 31 levels; top grid cell 0-10 m; bottom grid cell 4600-5000 m)\nocnBgchem: none\nseaIce: unnamed (same grid as atmosphere)" }, - "EC-Earth3-AerChem":{ + "CanESM5":{ "activity_participation":[ - "" + "C4MIP", + "CDRMIP", + "CFMIP", + "CMIP", + "CORDEX", + "DAMIP", + "DCPP", + "DynVarMIP", + "FAFMIP", + "GMMIP", + "GeoMIP", + "ISMIP6", + "LS3MIP", + "LUMIP", + "OMIP", + "RFMIP", + "SIMIP", + "ScenarioMIP", + "VIACSAB", + "VolMIP" ], "cohort":[ "Registered" ], "institution_id":[ - "EC-Earth-Consortium" + "CCCma" ], - "source_id":"EC-Earth3-AerChem", - "source":"EC-Earth3-AerChem (2017): \naerosol: TM5\natmos: IFS cy36r4 (TL255, linearly reduced Gaussian grid equivalent to 512 x 256, 91 levels, top level: 0.01 hPa)\natmosChem: TM5 (3 deg. (long.) x 2 deg. (lat.), 34 levels, top level: 0.1 hPa\nland: HTESSEL (land surface scheme built in IFS)\nlandIce: none\nocean: NEMO3.6 (ORCA1 tripolar primarily 1 deg latitude/longitude with meridional refinement down to 1/3 degree in the tropics; 75 levels; top grid cell 5 m)\nocnBgchem: none\nseaIce: LIM3" + "source_id":"CanESM5", + "source":"CanESM5 (2019): \naerosol: interactive\natmos: CanAM5 (T63L49 native atmosphere, T63 Linear Gaussian Grid; 128 x 64 longitude/latitude; 49 levels; top level 1 hPa)\natmosChem: specified oxidants for aerosols\nland: CLASS3.6/CTEM1.2\nlandIce: specified ice sheets\nocean: NEMO3.4.1 (ORCA1 tripolar grid, 1 deg with refinement to 1/3 deg within 20 degrees of the equator; 361 x 290 longitude/latitude; 45 vertical levels; top grid cell 0-6.19 m)\nocnBgchem: Canadian Model of Ocean Carbon (CMOC); NPZD ecosystem with OMIP prescribed carbonate chemistry\nseaIce: LIM2" }, - "EC-Earth3-CC":{ + "CanESM5-CanOE":{ "activity_participation":[ - "" + "C4MIP", + "CDRMIP", + "CMIP", + "OMIP", + "ScenarioMIP" ], "cohort":[ "Registered" ], "institution_id":[ - "EC-Earth-Consortium" + "CCCma" ], - "source_id":"EC-Earth3-CC", - "source":"EC-Earth3-CC (2017): \naerosol: none\natmos: IFS cy36r4 (TL255, linearly reduced Gaussian grid equivalent to 512 x 256, 91 levels, top level: 0.01 hPa)\natmosChem: TM5 (3 deg. (long.) x 2 deg. (lat.), 34 levels, top level: 0.1 hPa\nland: LPJ-GUESS v4\nlandIce: none\nocean: NEMO3.6 (ORCA1 tripolar primarily 1 deg latitude/longitude with meridional refinement down to 1/3 degree in the tropics; 75 levels; top grid cell 5 m)\nocnBgchem: PISCES v2\nseaIce: LIM3" + "source_id":"CanESM5-CanOE", + "source":"CanESM5-CanOE (2019): \naerosol: interactive\natmos: CanAM5 (T63L49 native atmosphere, T63 Linear Gaussian Grid; 128 x 64 longitude/latitude; 49 levels; top level 1 hPa)\natmosChem: specified oxidants for aerosols\nland: CLASS3.6/CTEM1.2\nlandIce: specified ice sheets\nocean: NEMO3.4.1 (ORCA1 tripolar grid, 1 deg with refinement to 1/3 deg within 20 degrees of the equator; 361 x 290 longitude/latitude; 45 vertical levels; top grid cell 0-6.19 m)\nocnBgchem: Canadian Ocean Ecosystem (CanOE) with OMIP prescribed carbon chemistry\nseaIce: LIM2" }, - "EC-Earth3-GrIS":{ + "E3SM-1-0":{ "activity_participation":[ - "" + "CMIP" ], "cohort":[ "Registered" ], "institution_id":[ - "EC-Earth-Consortium" + "E3SM-Project" ], - "source_id":"EC-Earth3-GrIS", - "source":"EC-Earth3-GrIS (2017): \naerosol: none\natmos: IFS cy36r4 (TL255, linearly reduced Gaussian grid equivalent to 512 x 256, 91 levels, top level: 0.01 hPa)\natmosChem: none\nland: HTESSEL (land surface scheme built in IFS)\nlandIce: PISM 0.7 (5 km x 5 km, L442)\nocean: NEMO3.6 (ORCA1 tripolar primarily 1 deg latitude/longitude with meridional refinement down to 1/3 degree in the tropics; 75 levels; top grid cell 5 m)\nocnBgchem: none\nseaIce: LIM3" + "source_id":"E3SM-1-0", + "source":"E3SM 1.0 (2018): \naerosol: MAM4 with resuspension, marine organics, and secondary organics (same grid as atmos)\natmos: EAM (v1.0, cubed sphere spectral-element grid; 5400 elements with p=3; 1 deg average grid spacing; 90 x 90 x 6 longitude/latitude/cubeface; 72 levels; top level 0.1 hPa)\natmosChem: Troposphere specified oxidants for aerosols. Stratosphere linearized interactive ozone (LINOZ v2) (same grid as atmos)\nland: ELM (v1.0, cubed sphere spectral-element grid; 5400 elements with p=3; 1 deg average grid spacing; 90 x 90 x 6 longitude/latitude/cubeface; satellite phenology mode), MOSART (v1.0, 0.5 degree latitude/longitude grid)\nlandIce: none\nocean: MPAS-Ocean (v6.0, oEC60to30 unstructured SVTs mesh with 235160 cells and 714274 edges, variable resolution 60 km to 30 km; 60 levels; top grid cell 0-10 m)\nocnBgchem: none\nseaIce: MPAS-Seaice (v6.0, same grid as ocean)" }, - "EC-Earth3-HR":{ + "EC-Earth3":{ "activity_participation":[ - "" + "CMIP", + "CORDEX", + "DCPP", + "DynVarMIP", + "LS3MIP", + "PAMIP", + "RFMIP", + "SIMIP", + "ScenarioMIP", + "VIACSAB", + "VolMIP" ], "cohort":[ "Registered" @@ -399,12 +715,14 @@ "institution_id":[ "EC-Earth-Consortium" ], - "source_id":"EC-Earth3-HR", - "source":"EC-Earth3-HR (2017): \naerosol: none\natmos: IFS cy36r4 (TL511, linearly reduced Gaussian grid equivalent to 1024 x 512; 91 levels; top level 0.01 hPa)\natmosChem: none\nland: HTESSEL (land surface scheme built in IFS)\nlandIce: none\nocean: NEMO3.6 (tripolar, 1442x1921; 75 levels; top grid cell 5m)\nocnBgchem: none\nseaIce: LIM3" + "source_id":"EC-Earth3", + "source":"EC-Earth3 (2019): \naerosol: none\natmos: IFS cy36r4 (TL255, linearly reduced Gaussian grid equivalent to 512 x 256 longitude/latitude; 91 levels; top level 0.01 hPa)\natmosChem: none\nland: HTESSEL (land surface scheme built in IFS)\nlandIce: none\nocean: NEMO3.6 (ORCA1 tripolar primarily 1 deg with meridional refinement down to 1/3 degree in the tropics; 362 x 292 longitude/latitude; 75 levels; top grid cell 0-1 m)\nocnBgchem: none\nseaIce: LIM3" }, - "EC-Earth3-LR":{ + "EC-Earth3-AerChem":{ "activity_participation":[ - "" + "AerChemMIP", + "CMIP", + "ScenarioMIP" ], "cohort":[ "Registered" @@ -412,12 +730,16 @@ "institution_id":[ "EC-Earth-Consortium" ], - "source_id":"EC-Earth3-LR", - "source":"EC-Earth3-LR (2017): \naerosol: none\natmos: IFS cy36r4 (TL159, linearly reduced Gaussian grid equivalent to 320 x 160; 62 levels; top level 5 hPa)\natmosChem: none\nland: HTESSEL (land surface scheme built in IFS)\nlandIce: none\nocean: NEMO3.6 (ORCA1 tripolar primarily 1 deg latitude/longitude with meridional refinement down to 1/3 degree in the tropics; 75 levels; top grid cell 5 m)\nocnBgchem: none\nseaIce: LIM3" + "source_id":"EC-Earth3-AerChem", + "source":"EC-Earth3-AerChem (2019): \naerosol: TM5 (3 x 2 degrees; 120 x 90 longitude/latitude; 34 levels; top level: 0.1 hPa)\natmos: IFS cy36r4 (TL255, linearly reduced Gaussian grid equivalent to 512 x 256 longitude/latitude; 91 levels; top level 0.01 hPa)\natmosChem: TM5 (3 x 2 degrees; 120 x 90 longitude/latitude; 34 levels; top level: 0.1 hPa)\nland: HTESSEL (land surface scheme built in IFS)\nlandIce: none\nocean: NEMO3.6 (ORCA1 tripolar primarily 1 degree with meridional refinement down to 1/3 degree in the tropics; 362 x 292 longitude/latitude; 75 levels; top grid cell 0-1 m)\nocnBgchem: none\nseaIce: LIM3" }, - "EC-Earth3-Veg":{ + "EC-Earth3-CC":{ "activity_participation":[ - "" + "CDRMIP", + "CMIP", + "C4MIP", + "LUMIP", + "OMIP" ], "cohort":[ "Registered" @@ -425,12 +747,14 @@ "institution_id":[ "EC-Earth-Consortium" ], - "source_id":"EC-Earth3-Veg", - "source":"EC-Earth3-Veg (2017): \naerosol: none\natmos: IFS cy36r4 (TL255, linearly reduced Gaussian grid equivalent to 512 x 256, 91 levels, top level: 0.01 hPa)\natmosChem: none\nland: LPJ-GUESS v4\nlandIce: none\nocean: NEMO3.6 (ORCA1 tripolar primarily 1 deg latitude/longitude with meridional refinement down to 1/3 degree in the tropics; 75 levels; top grid cell 5 m)\nocnBgchem: none\nseaIce: LIM3" + "source_id":"EC-Earth3-CC", + "source":"EC-Earth3-CC (2019): \naerosol: none\natmos: IFS cy36r4 (TL255, linearly reduced Gaussian grid equivalent to 512 x 256 longitude/latitude; 91 levels; top level 0.01 hPa)\natmosChem: TM5 (3 x 2 degrees; 120 x 90 longitude/latitude; 34 levels; top level: 0.1 hPa)\nland: HTESSEL (land surface scheme built in IFS) and LPJ-GUESS v4\nlandIce: none\nocean: NEMO3.6 (ORCA1 tripolar primarily 1 degree with meridional refinement down to 1/3 degree in the tropics; 362 x 292 longitude/latitude; 75 levels; top grid cell 0-1 m)\nocnBgchem: PISCES v2\nseaIce: LIM3" }, - "EC-Earth3-Veg-LR":{ + "EC-Earth3-GrIS":{ "activity_participation":[ - "" + "CMIP", + "ISMIP6", + "PMIP" ], "cohort":[ "Registered" @@ -438,584 +762,1339 @@ "institution_id":[ "EC-Earth-Consortium" ], - "source_id":"EC-Earth3-Veg-LR", - "source":"EC-Earth3-Veg-LR (2017): \naerosol: none\natmos: IFS cy36r4 (TL159, linearly reduced Gaussian grid equivalent to 320 x 160; 62 levels; top level 5 hPa)\natmosChem: none\nland: LPJ-GUESS v4\nlandIce: none\nocean: NEMO3.6 (ORCA1 tripolar primarily 1 deg latitude/longitude with meridional refinement down to 1/3 degree in the tropics; 75 levels; top grid cell 5 m)\nocnBgchem: none\nseaIce: LIM3" + "source_id":"EC-Earth3-GrIS", + "source":"EC-Earth3-GrIS (2019): \naerosol: none\natmos: IFS cy36r4 (TL255, linearly reduced Gaussian grid equivalent to 512 x 256 longitude/latitude; 91 levels; top level 0.01 hPa)\natmosChem: none\nland: HTESSEL (land surface scheme built in IFS)\nlandIce: PISM 0.7 (5 km x 5 km, 442 levels)\nocean: NEMO3.6 (ORCA1 tripolar primarily 1 degree with meridional refinement down to 1/3 degree in the tropics; 362 x 292 longitude/latitude; 75 levels; top grid cell 0-1 m)\nocnBgchem: none\nseaIce: LIM3" }, - "EMAC-2-53-AerChem":{ + "EC-Earth3-HR":{ "activity_participation":[ - "AerChemMIP", - "CMIP" + "CMIP", + "DCPP", + "HighResMIP" ], "cohort":[ "Registered" ], "institution_id":[ - "MESSy-Consortium" + "EC-Earth-Consortium" ], - "source_id":"EMAC-2-53-AerChem", - "source":"EMAC-2-53-AerChem (2017): \naerosol: gmxe 2.2.x\natmos: ECHAM5.3.02 (modified, spectral T42; 128 x 64 longitude/latitude; 47 levels; top level 0.01 hPa)\natmosChem: MECCA 3.8.x\nland: same as Atmosphere\nlandIce: none\nocean: MPIOM 1.3.0-beta (bipolar GR1.5, approximately 1.5deg; 256 x 220 longitude/latitude; 40 levels; top grid cell 0-12 m)\nocnBgchem: none\nseaIce: thermodynamic (Semtner zero-layer) dynamic (Hibler 79) sea ice model" + "source_id":"EC-Earth3-HR", + "source":"EC-Earth3-HR (2019): \naerosol: none\natmos: IFS cy36r4 (TL511, linearly reduced Gaussian grid equivalent to 1024 x 512 longitude/latitude; 91 levels; top level 0.01 hPa)\natmosChem: none\nland: HTESSEL (land surface scheme built in IFS)\nlandIce: none\nocean: NEMO3.6 (ORCA025 tripolar primarily 0.25 degrees; 1442 x 1921 longitude/latitude; 75 levels; top grid cell 0-1 m)\nocnBgchem: none\nseaIce: LIM3" }, - "EMAC-2-53-Vol":{ + "EC-Earth3-LR":{ "activity_participation":[ - "" + "CMIP", + "PMIP" ], "cohort":[ "Registered" ], "institution_id":[ - "MESSy-Consortium" + "EC-Earth-Consortium" ], - "source_id":"EMAC-2-53-Vol", - "source":"EMAC-2-53-Vol (2017): \naerosol: gmxe 2.2.x\natmos: ECHAM5.3.2 (modified; spectral T42; 128 x 64 longitude/latitude; 90 levels; top level 0.001 hPa)\natmosChem: MECCA 3.8.x\nland: same as Atmosphere\nlandIce: none\nocean: MPIOM 1.3.0-beta (bipolar GR1.5; approximately 1.5deg reducing toward the poles, 256 x 220 longitude/latitude; 40 levels; top grid cell 0-12 m)\nocnBgchem: none\nseaIce: thermodynamic (Semtner zero-layer) dynamic (Hibler 79) sea ice model" + "source_id":"EC-Earth3-LR", + "source":"EC-Earth3-LR (2019): \naerosol: none\natmos: IFS cy36r4 (TL159, linearly reduced Gaussian grid equivalent to 320 x 160 longitude/latitude; 62 levels; top level 5 hPa)\natmosChem: none\nland: HTESSEL (land surface scheme built in IFS)\nlandIce: none\nocean: NEMO3.6 (ORCA1 tripolar primarily 1 degree with meridional refinement down to 1/3 degree in the tropics; 362 x 292 longitude/latitude; 75 levels; top grid cell 0-1 m)\nocnBgchem: none\nseaIce: LIM3" }, - "GFDL-AM4":{ + "EC-Earth3-Veg":{ "activity_participation":[ - "CMIP" + "CDRMIP", + "CMIP", + "LS3MIP", + "LUMIP", + "ScenarioMIP" ], "cohort":[ "Registered" ], "institution_id":[ - "NOAA-GFDL" + "EC-Earth-Consortium" ], - "source_id":"GFDL-AM4", - "source":"GFDL-AM4 (2017): \naerosol: interactive\natmos: GFDL-AM4.0 (Cubed-sphere (c96) - 1 degree nominal horizontal resolution; 360x180 longitude/latitude; 32 levels; model top: 1 hPa)\natmosChem: fast chemistry, aerosol only\nland: GFDL-LM4.0\nlandIce: GFDL-LM4.0\nocean: none\nocnBgchem: none\nseaIce: none" + "source_id":"EC-Earth3-Veg", + "source":"EC-Earth3-Veg (2019): \naerosol: none\natmos: IFS cy36r4 (TL255, linearly reduced Gaussian grid equivalent to 512 x 256 longitude/latitude; 91 levels; top level 0.01 hPa)\natmosChem: none\nland: HTESSEL (land surface scheme built in IFS) and LPJ-GUESS v4\nlandIce: none\nocean: NEMO3.6 (ORCA1 tripolar primarily 1 degree with meridional refinement down to 1/3 degree in the tropics; 362 x 292 longitude/latitude; 75 levels; top grid cell 0-1 m)\nocnBgchem: none\nseaIce: LIM3" }, - "GFDL-CM4":{ + "EC-Earth3-Veg-LR":{ "activity_participation":[ "CMIP", - "OMIP" + "PMIP", + "ScenarioMIP" ], "cohort":[ "Registered" ], "institution_id":[ - "NOAA-GFDL" + "EC-Earth-Consortium" ], - "source_id":"GFDL-CM4", - "source":"GFDL-CM4 (2017): \naerosol: interactive\natmos: GFDL-AM4.1 (Cubed-sphere (c96) - 1 degree nominal horizontal resolution; 360x180 longitude/latitude; 32 levels; model top: 1 hPa)\natmosChem: unnamed (fast chemistry, aerosol only)\nland: GFDL-LM4.0\nlandIce: GFDL-LM4.0\nocean: GFDL-MOM6 (tripolar - nominal 0.25 deg latitude/longitude; 1440x720 longitude/latitude; 75 levels; top grid cell 0-2 m)\nocnBgchem: none\nseaIce: SIS2" + "source_id":"EC-Earth3-Veg-LR", + "source":"EC-Earth3-Veg-LR (2019): \naerosol: none\natmos: IFS cy36r4 (TL159, linearly reduced Gaussian grid equivalent to 320 x 160 longitude/latitude; 62 levels; top level 5 hPa)\natmosChem: none\nland: HTESSEL (land surface scheme built in IFS) and LPJ-GUESS v4\nlandIce: none\nocean: NEMO3.6 (ORCA1 tripolar primarily 1 degree with meridional refinement down to 1/3 degree in the tropics; 362 x 292 longitude/latitude; 75 levels; top grid cell 0-1 m)\nocnBgchem: none\nseaIce: LIM3" }, - "GFDL-ESM4":{ + "EC-Earth3P":{ "activity_participation":[ - "AerChemMIP", - "C4MIP", - "CFMIP", "CMIP", - "DAMIP", - "DynVarMIP", - "GMMIP", - "LUMIP", - "OMIP", - "RFMIP", - "ScenarioMIP" + "HighResMIP" ], "cohort":[ "Registered" ], "institution_id":[ - "NOAA-GFDL" + "EC-Earth-Consortium" ], - "source_id":"GFDL-ESM4", - "source":"GFDL-ESM4 (2017): \naerosol: interactive\natmos: GFDL-AM4.1 (Cubed-sphere (c96) - 1 degree nominal horizontal resolution; 360x180 longitude/latitude; 48 levels, model top: 1 Pa)\natmosChem: GFDL-ATMCHEM4.1 (full atmospheric chemistry)\nland: GFDL-LM4.1\nlandIce: GFDL-LM4.1\nocean: GFDL-MOM6 (tripolar - nominal 0.5 deg; 720x360 longitude/latitude; 75 levels; top grid cell 0-2 m)\nocnBgchem: COBALT 2.0\nseaIce: SIS2" + "source_id":"EC-Earth3P", + "source":"EC-Earth3P (2017): \naerosol: none\natmos: IFS cy36r4 (TL255, linearly reduced Gaussian grid equivalent to 512 x 256 longitude/latitude; 91 levels; top level 0.01 hPa)\natmosChem: none\nland: HTESSEL (land surface scheme built in IFS)\nlandIce: none\nocean: NEMO3.6 (ORCA1 tripolar primarily 1 degree with meridional refinement down to 1/3 degree in the tropics; 362 x 292 longitude/latitude; 75 levels; top grid cell 0-1 m)\nocnBgchem: none\nseaIce: LIM3" }, - "GISS-E2-1G":{ + "EC-Earth3P-HR":{ "activity_participation":[ - "" + "HighResMIP" ], "cohort":[ "Registered" ], "institution_id":[ - "NASA-GISS" + "EC-Earth-Consortium" ], - "source_id":"GISS-E2-1G", - "source":"GISS-E2.1G (2016): \naerosol: varies with physics-version (p==1 none, p==3 OMA, p==4 TOMAS, p==5 MATRIX)\natmos: GISS-E2.1 (90 x 144 2x2.5; 40 levels; top level 0.1hPa)\natmosChem: varies with physics-version (p==1 Non-interactive, p>1 GPUCCINI)\nland: GISS LSM\nlandIce: Fixed\nocean: GISS Ocean (1 deg latitude/longitude; 32 levels; top grid cell 0-10m)\nocnBgchem: none\nseaIce: GISS SI" + "source_id":"EC-Earth3P-HR", + "source":"EC-Earth3P-HR (2017): \naerosol: none\natmos: IFS cy36r4 (TL511, linearly reduced Gaussian grid equivalent to 1024 x 512 longitude/latitude; 91 levels; top level 0.01 hPa)\natmosChem: none\nland: HTESSEL (land surface scheme built in IFS)\nlandIce: none\nocean: NEMO3.6 (ORCA025; tripolar primarily 0.25 degrees; 1442 x 1921 longitude/latitude; 75 levels; top grid cell 0-1 m)\nocnBgchem: none\nseaIce: LIM3" }, - "GISS-E2-1H":{ + "EC-Earth3P-VHR":{ "activity_participation":[ - "" + "HighResMIP" ], "cohort":[ "Registered" ], "institution_id":[ - "NASA-GISS" + "EC-Earth-Consortium" ], - "source_id":"GISS-E2-1H", - "source":"GISS-E2.1H (2016): \naerosol: varies with physics-version (p==1 none, p==3 OMA, p==4 TOMAS, p==5 MATRIX)\natmos: GISS-E2.1 (90 x 144 2x2.5; 40 levels; top level 0.1hPa)\natmosChem: varies with physics-version (p==1 Non-interactive, p>1 GPUCCINI)\nland: GISS LSM\nlandIce: Fixed\nocean: HYCOM Ocean (tripolar grid; ~1 deg latitude/longitude; 26 levels; top grid cell 0-10m)\nocnBgchem: none\nseaIce: GISS SI" + "source_id":"EC-Earth3P-VHR", + "source":"EC-Earth3P-VHR (2017): \naerosol: none\natmos: IFS cy36r4 (TL1279, linearly reduced Gaussian grid equivalent to 2560 x 1280 longitude/latitude; 91 levels; top level 0.01 hPa)\natmosChem: none\nland: HTESSEL (land surface scheme built in IFS)\nlandIce: none\nocean: NEMO3.6 (ORCA012 tripolar primarily 0.08 degrees; 4322 x 3059 longitude/latitude; 75 levels; top grid cell 0-1 m)\nocnBgchem: none\nseaIce: LIM3" }, - "HadGEM3-GC31-HH":{ + "ECMWF-IFS-HR":{ "activity_participation":[ - "" + "HighResMIP" ], "cohort":[ "Registered" ], "institution_id":[ - "MOHC" + "ECMWF" ], - "source_id":"HadGEM3-GC31-HH", - "source":"HadGEM3-GC31-HH (2016): \naerosol: UKCA-GLOMAP-mode\natmos: MetUM-HadGEM3-GA7.1 (1024 x 768 N512; 85 levels; top level 85km)\natmosChem: none\nland: JULES-HadGEM3-GL7.1\nlandIce: none\nocean: NEMO-HadGEM3-GO6.0 (ORCA12 tripolar primarily 1/12 deg latitude/longitude; 75 levels; top grid cell 0-1m)\nocnBgchem: none\nseaIce: CICE-HadGEM3-GSI8 (ORCA12 tripolar primarily 1/12 deg latitude/longitude)" + "source_id":"ECMWF-IFS-HR", + "source":"ECMWF-IFS-HR (2017): \naerosol: none\natmos: IFS (IFS CY43R1, Tco399, cubic octahedral reduced Gaussian grid equivalent to 1600 x 800 longitude/latitude; 91 levels; top level 0.01 hPa)\natmosChem: none\nland: HTESSEL (as implemented in IFS CY43R1)\nlandIce: none\nocean: NEMO3.4 (NEMO v3.4; ORCA025 tripolar grid; 1442 x 1021 longitude/latitude; 75 levels; top grid cell 0-1 m)\nocnBgchem: none\nseaIce: LIM2 (LIM v2; ORCA025 tripolar grid; 1442 x 1021 longitude/latitude)" }, - "HadGEM3-GC31-HM":{ + "ECMWF-IFS-LR":{ "activity_participation":[ - "" + "HighResMIP" ], "cohort":[ "Registered" ], "institution_id":[ - "MOHC" + "ECMWF" ], - "source_id":"HadGEM3-GC31-HM", - "source":"HadGEM3-GC31-HM (2016): \naerosol: UKCA-GLOMAP-mode\natmos: MetUM-HadGEM3-GA7.1 (1024 x 768 N512; 85 levels; top level 85km)\natmosChem: none\nland: JULES-HadGEM3-GL7.1\nlandIce: none\nocean: NEMO-HadGEM3-GO6.0 (ORCA025 tripolar primarily 0.25 deg latitude/longitude; 75 levels; top grid cell 0-1m)\nocnBgchem: none\nseaIce: CICE-HadGEM3-GSI8 (ORCA025 tripolar primarily 0.25 deg latitude/longitude)" + "source_id":"ECMWF-IFS-LR", + "source":"ECMWF-IFS-LR (2017): \naerosol: none\natmos: IFS (IFS CY43R1, Tco199, cubic octahedral reduced Gaussian grid equivalent to 800 x 400 longitude/latitude; 91 levels; top level 0.01 hPa)\natmosChem: none\nland: HTESSEL (as implemented in IFS CY43R1)\nlandIce: none\nocean: NEMO3.4 (NEMO v3.4; ORCA1 tripolar grid; 362 x 292 longitude/latitude; 75 levels; top grid cell 0-1 m)\nocnBgchem: none\nseaIce: LIM2 (LIM v2; ORCA1 tripolar grid; 362 x 292 longitude/latitude)" }, - "HadGEM3-GC31-LL":{ + "ECMWF-IFS-MR":{ "activity_participation":[ - "" + "HighResMIP" ], "cohort":[ "Registered" ], "institution_id":[ - "MOHC" + "ECMWF" ], - "source_id":"HadGEM3-GC31-LL", - "source":"HadGEM3-GC31-LL (2016): \naerosol: UKCA-GLOMAP-mode\natmos: MetUM-HadGEM3-GA7.1 (192 x 144 N96; 85 levels; top level 85km)\natmosChem: none\nland: JULES-HadGEM3-GL7.1\nlandIce: none\nocean: NEMO-HadGEM3-GO6.0 (ORCA1 tripolar primarily 1 deg latitude/longitude with meridional refinement down to 1/3 degree in the tropics; 75 levels; top grid cell 0-1m)\nocnBgchem: none\nseaIce: CICE-HadGEM3-GSI8 (ORCA1 tripolar primarily 1 deg latitude/longitude)" + "source_id":"ECMWF-IFS-MR", + "source":"ECMWF-IFS-MR (2017): \naerosol: none\natmos: IFS (IFS CY43R1, Tco199, cubic octahedral reduced Gaussian grid equivalent to 800 x 400 longitude/latitude; 91 levels; top level 0.01 hPa)\natmosChem: none\nland: HTESSEL (as implemented in IFS CY43R1)\nlandIce: none\nocean: NEMO3.4 (NEMO v3.4; ORCA025 tripolar grid; 1442 x 1021 longitude/latitude; 75 levels; top grid cell 0-1 m)\nocnBgchem: none\nseaIce: LIM2 (LIM v2; ORCA025 tripolar grid; 1442 x 1021 longitude/latitude)" }, - "HadGEM3-GC31-MM":{ + "EMAC-2-53-AerChem":{ "activity_participation":[ - "" + "AerChemMIP", + "CMIP" ], "cohort":[ "Registered" ], "institution_id":[ - "MOHC" + "MESSy-Consortium" ], - "source_id":"HadGEM3-GC31-MM", - "source":"HadGEM3-GC31-MM (2016): \naerosol: UKCA-GLOMAP-mode\natmos: MetUM-HadGEM3-GA7.1 (432 x 324 N216; 85 levels; top level 85km)\natmosChem: none\nland: JULES-HadGEM3-GL7.1\nlandIce: none\nocean: NEMO-HadGEM3-GO6.0 (ORCA025 tripolar primarily 0.25 deg latitude/longitude; 75 levels; top grid cell 0-1m)\nocnBgchem: none\nseaIce: CICE-HadGEM3-GSI8 (ORCA025 tripolar primarily 0.25 deg latitude/longitude)" + "source_id":"EMAC-2-53-AerChem", + "source":"EMAC-2-53-AerChem (2017): \naerosol: gmxe 2.2.x\natmos: ECHAM5.3.02 (modified, spectral T42; 128 x 64 longitude/latitude; 47 levels; top level 0.01 hPa)\natmosChem: MECCA 3.8.x\nland: same as Atmosphere\nlandIce: none\nocean: MPIOM 1.3.0-beta (bipolar GR1.5, approximately 1.5deg; 256 x 220 longitude/latitude; 40 levels; top grid cell 0-12 m)\nocnBgchem: none\nseaIce: thermodynamic (Semtner zero-layer) dynamic (Hibler 79) sea ice model" }, - "IITM-ESM":{ + "EMAC-2-53-Vol":{ "activity_participation":[ - "" + "CMIP", + "VolMIP" ], "cohort":[ "Registered" ], "institution_id":[ - "CCCR-IITM" + "MESSy-Consortium" ], - "source_id":"IITM-ESM", - "source":"IITM-ESM (2015): \naerosol: unnamed (prescribed MAC-v2)\natmos: GFS (192 x 94 T62; 64 levels; top level 0.2 mb)\natmosChem: none\nland: NOAH LSM\nlandIce: none\nocean: MOM4p1 (tripolar, 360x200; 50 levels; top grid cell 5m)\nocnBgchem: TOPAZ\nseaIce: SIS" + "source_id":"EMAC-2-53-Vol", + "source":"EMAC-2-53-Vol (2017): \naerosol: gmxe 2.2.x\natmos: ECHAM5.3.02 (modified; spectral T42; 128 x 64 longitude/latitude; 47 levels; top level 0.01 hPa)\natmosChem: MECCA 3.8.x\nland: same as Atmosphere\nlandIce: none\nocean: MPIOM 1.3.0-beta (bipolar GR1.5, approximately 1.5deg reducing toward the poles; 256 x 220 longitude/latitude; 40 levels; top grid cell 0-12 m)\nocnBgchem: none\nseaIce: thermodynamic (Semtner zero-layer) dynamic (Hibler 79) sea ice model" }, - "MIROC-ES2H":{ + "FGOALS-f3-H":{ "activity_participation":[ - "" + "CMIP", + "HighResMIP" ], "cohort":[ "Registered" ], "institution_id":[ - "MIROC" + "CAS" ], - "source_id":"MIROC-ES2H", - "source":"MIROC-ES2H (2017): \naerosol: SPRINTARS6.0\natmos: CCSR AGCM (T85; 256 x 128 longitude/latitude; 81 levels; top level 0.004 hPa)\natmosChem: CHASER4.0\nland: MATSIRO6.0+VISIT-e ver.1.0\nlandIce: none\nocean: COCO4.9 (tripolar primarily 1deg; 360 x 256 longitude/latitude; 63 levels; top grid cell 0-2 m)\nocnBgchem: OECO ver.2.0; NPZD-type with C/N/P/Fe/O cycles\nseaIce: COCO4.9" + "source_id":"FGOALS-f3-H", + "source":"FGOALS-f3-H (2017): \naerosol: none\natmos: FAMIL2.2 (Cubed-sphere, c384; 1440 x 720 longitude/latitude; 32 levels; top level 2.16 hPa)\natmosChem: none\nland: CLM4.0\nlandIce: none\nocean: LICOM3.0 (LICOM3.0, tripolar primarily 0.1deg; 3600 x 2302 longitude/latitude; 55 levels; top grid cell 0-5 m)\nocnBgchem: none\nseaIce: CICE4.0" }, - "MIROC-ES2L":{ + "FGOALS-f3-L":{ "activity_participation":[ - "" + "CMIP", + "DCPP", + "GMMIP", + "OMIP", + "SIMIP", + "ScenarioMIP" ], "cohort":[ "Registered" ], "institution_id":[ - "MIROC" + "CAS" ], - "source_id":"MIROC-ES2L", - "source":"MIROC-ES2L (2017): \naerosol: SPRINTARS6.0\natmos: CCSR AGCM (T42; 128 x 64 longitude/latitude; 40 levels; top level 3 hPa)\natmosChem: none\nland: MATSIRO6.0+VISIT-e ver.1.0\nlandIce: none\nocean: COCO4.9 (tripolar primarily 1deg; 360 x 256 longitude/latitude; 63 levels; top grid cell 0-2 m)\nocnBgchem: OECO ver.2.0; NPZD-type with C/N/P/Fe/O cycles\nseaIce: COCO4.9" + "source_id":"FGOALS-f3-L", + "source":"FGOALS-f3-L (2017): \naerosol: none\natmos: FAMIL2.2 (Cubed-sphere, c96; 360 x 180 longitude/latitude; 32 levels; top level 2.16 hPa)\natmosChem: none\nland: CLM4.0\nlandIce: none\nocean: LICOM3.0 (LICOM3.0, tripolar primarily 1deg; 360 x 218 longitude/latitude; 30 levels; top grid cell 0-10 m)\nocnBgchem: none\nseaIce: CICE4.0" }, - "MIROC6":{ + "FGOALS-g3":{ "activity_participation":[ - "" + "CMIP", + "CORDEX", + "DAMIP", + "DCPP", + "FAFMIP", + "GMMIP", + "LS3MIP", + "OMIP", + "PMIP", + "SIMIP", + "ScenarioMIP" ], "cohort":[ "Registered" ], "institution_id":[ - "MIROC" + "CAS" ], - "source_id":"MIROC6", - "source":"MIROC6 (2017): \naerosol: SPRINTARS6.0\natmos: CCSR AGCM (T85; 256x128; 81 levels; top level 0.004 hPa)\natmosChem: none\nland: MATSIRO6.0\nlandIce: none\nocean: COCO4.9 (360x256x63; tripolar primarily 1deg; 63 levels; top grid cell 0-2 m)\nocnBgchem: none\nseaIce: COCO4.9" + "source_id":"FGOALS-g3", + "source":"FGOALS-g3 (2017): \naerosol: none\natmos: GAMIL2 (180 x 90 longitude/latitude; 26 levels; top level 2.19hPa)\natmosChem: none\nland: CLM4.0\nlandIce: none\nocean: LICOM3.0 (LICOM3.0, tripolar primarily 1deg; 360 x 218 longitude/latitude; 30 levels; top grid cell 0-10 m)\nocnBgchem: none\nseaIce: CICE4.0" }, - "MPIESM-1-2-HR":{ + "FIO-ESM-2-0":{ "activity_participation":[ - "" + "CMIP", + "DCPP", + "GMMIP", + "OMIP", + "ScenarioMIP", + "SIMIP" ], "cohort":[ "Registered" ], "institution_id":[ - "MPI-M" + "FIO-QLNM" ], - "source_id":"MPIESM-1-2-HR", - "source":"MPIESM1.2-HR (2017): \naerosol: none, prescribed MACv2-SP\natmos: ECHAM6.3 (spectral T127; 384 x 192 longitude/latitude; 95 levels; top level 0.01 hPa)\natmosChem: none\nland: JSBACH3.2\nlandIce: none/prescribed\nocean: MPIOM1.63 (tripolar TP04; approximately 0.4deg latitude/longitude; 40 levels; top grid cell 0-12 m)\nocnBgchem: HAMOCC\nseaIce: thermodynamic (Semtner zero-layer) dynamic (Hibler 79) sea ice model" + "source_id":"FIO-ESM-2-0", + "source":"FIO-ESM 2.0 (2018): \naerosol: Prescribed monthly fields\natmos: CAM4 (0.9x1.25 finite volume grid; 192 x 288 longitude/latitude; 26 levels; top level ~2 hPa)\natmosChem: none\nland: CLM4.0 (same grid at atmos)\nlandIce: none\nocean: POP2-W (POP2 coupled with MASNUM surface wave model, Displaced Pole; 320 x 384 longitude/latitude; 60 levels; top grid cell 0-10 m)\nocnBgchem: none\nseaIce: CICE4.0 (same grid as ocean)" }, - "MPIESM-1-2-LR":{ + "GFDL-AM4":{ "activity_participation":[ - "" + "CMIP" ], "cohort":[ "Registered" ], "institution_id":[ - "MPI-M" + "NOAA-GFDL" ], - "source_id":"MPIESM-1-2-LR", - "source":"MPIESM1.2-LR (2017): \naerosol: none, prescribed MACv2-SP\natmos: ECHAM6.3 (spectral T63; 192 x 96 longitude/latitude; 47 levels; top level 0.01 hPa)\natmosChem: none\nland: JSBACH3.2\nlandIce: none/prescribed\nocean: MPIOM1.63 (bipolar GR1.5; approximately 1.5deg latitude/longitude; 40 levels; top grid cell 0-12 m)\nocnBgchem: HAMOCC\nseaIce: thermodynamic (Semtner zero-layer) dynamic (Hibler 79) sea ice model" + "source_id":"GFDL-AM4", + "source":"GFDL-AM4 (2018): \naerosol: interactive\natmos: GFDL-AM4.0 (Cubed-sphere (c96) - 1 degree nominal horizontal resolution; 360 x 180 longitude/latitude; 33 levels; top level 1 hPa)\natmosChem: fast chemistry, aerosol only\nland: GFDL-LM4.0\nlandIce: GFDL-LM4.0\nocean: none\nocnBgchem: none\nseaIce: none" }, - "MPIESM-2-LR":{ + "GFDL-CM4":{ "activity_participation":[ - "" + "CFMIP", + "CMIP", + "DynVarMIP", + "GMMIP", + "OMIP", + "RFMIP", + "ScenarioMIP" ], "cohort":[ "Registered" ], "institution_id":[ - "MPI-M" + "NOAA-GFDL" ], - "source_id":"MPIESM-2-LR", - "source":"MPIESM2 (2017): \naerosol: none, prescribed MACv2-SP\natmos: ICON-AES (icosahedral/triangles; 160 km; 47 levels; top level 80 km)\natmosChem: none\nland: JSBACH4.2\nlandIce: none/prescribed\nocean: ICON-OES (icosahedral/triangles; 40 km; 40 levels; top grid cell 0-12 m)\nocnBgchem: HAMOCC\nseaIce: thermodynamic (Semtner zero-layer) dynamic (Hibler 79) sea ice model" + "source_id":"GFDL-CM4", + "source":"GFDL-CM4 (2018): \naerosol: interactive\natmos: GFDL-AM4.0.1 (Cubed-sphere (c96) - 1 degree nominal horizontal resolution; 360 x 180 longitude/latitude; 33 levels; top level 1 hPa)\natmosChem: fast chemistry, aerosol only\nland: GFDL-LM4.0.1 (1 degree nominal horizontal resolution; 360 x 180 longitude/latitude; 20 levels; bottom level 10m); land-Veg:unnamed (dynamic vegetation, dynamic land use); land-Hydro:unnamed (soil water and ice, multi-layer snow, rivers and lakes)\nlandIce: GFDL-LM4.0.1\nocean: GFDL-OM4p25 (GFDL-MOM6, tripolar - nominal 0.25 deg; 1440 x 1080 longitude/latitude; 75 levels; top grid cell 0-2 m)\nocnBgchem: GFDL-BLINGv2\nseaIce: GFDL-SIM4p25 (GFDL-SIS2.0, tripolar - nominal 0.25 deg; 1440 x 1080 longitude/latitude; 5 layers; 5 thickness categories)" }, - "MRI-ESM2-0":{ + "GFDL-CM4C192":{ "activity_participation":[ - "" + "HighResMIP" ], "cohort":[ "Registered" ], "institution_id":[ - "MRI" + "NOAA-GFDL" ], - "source_id":"MRI-ESM2-0", - "source":"MRI-ESM2.0 (2017): \naerosol: MASINGAR mk2r4\natmos: MRI-AGCM3.5 (320 x 160 TL159; 80 levels; top level 0.01 hPa)\natmosChem: MRI-CCM2.1\nland: HAL 1.0\nlandIce: none\nocean: MRI.COM4.4 (tripolar primarily 0.5 deg latitude/1 deg longitude with meridional refinement down to 0.3 deg within 10 degrees north and south of the equator; 360 x 364 longitude/latitude; 61 levels; top grid cell 0-2 m)\nocnBgchem: MRI.COM4.4\nseaIce: MRI.COM4.4" + "source_id":"GFDL-CM4C192", + "source":"GFDL-CM4C192 (2018): \naerosol: interactive\natmos: GFDL-AM4C192 (Cubed-sphere (c192) - 0.5 degree nominal horizontal resolution; 720 x 360 longitude/latitude; 33 levels; top level 1 hPa)\natmosChem: fast chemistry, aerosol only\nland: GFDL-LM4.0.1\nlandIce: GFDL-LM4.0.1\nocean: GFDL-OM4p25 (GFDL-MOM6, tripolar - nominal 0.25 deg; 1440 x 1080 longitude/latitude; 75 levels; top grid cell 0-2 m)\nocnBgchem: none\nseaIce: GFDL-SIM4p25 (GFDL-SIS2.0, tripolar - nominal 0.25 deg; 1440 x 1080 longitude/latitude; 5 layers; 5 thickness categories)" }, - "NICAM16-7S":{ + "GFDL-ESM2M":{ "activity_participation":[ - "" + "FAFMIP" ], "cohort":[ "Registered" ], "institution_id":[ - "MIROC" + "NOAA-GFDL" ], - "source_id":"NICAM16-7S", - "source":"NICAM16-7S (2017): \naerosol: Prescribed MACv2-SP\natmos: NICAM.16 (56km icosahedral grid; 163,842 grid cells (=10*4^7+2); 38 levels; top level 40 km)\natmosChem: none\nland: MATSIRO6 (w/o MOSAIC)\nlandIce: none\nocean: none\nocnBgchem: none\nseaIce: Fixed" + "source_id":"GFDL-ESM2M", + "source":"GFDL-ESM2M (2012): \naerosol: prescribed\natmos: GFDL-AM2 (144 x 90 longitude/latitude; 24 levels; top level 1 hPa)\natmosChem: prescribed\nland: GFDL-LM3.0\nlandIce: GFDL-LM3.0\nocean: GFDL-MOM4p1 (tripolar - nominal 1 deg; 360 x 200 longitude/latitude; 50 levels; top grid cell 0-10 m)\nocnBgchem: GFDL-TOPAZ2\nseaIce: GFDL-SIM2 (GFDL-SIS, tripolar - nominal 1 deg; 360 x 200 longitude/latitude; 3 layers; 5 thickness categories)" }, - "NICAM16-8S":{ + "GFDL-ESM4":{ "activity_participation":[ - "" + "AerChemMIP", + "C4MIP", + "CDRMIP", + "CMIP", + "DAMIP", + "DynVarMIP", + "LUMIP", + "ScenarioMIP" ], "cohort":[ "Registered" ], "institution_id":[ - "MIROC" + "NOAA-GFDL" ], - "source_id":"NICAM16-8S", - "source":"NICAM16-8S (2017): \naerosol: Prescribed MACv2-SP\natmos: NICAM.16 (28km icosahedral grid; 655,362 grid cells (=10*4^8+2); 38 levels; top level 40 km)\natmosChem: none\nland: MATSIRO6 (w/o MOSAIC)\nlandIce: none\nocean: none\nocnBgchem: none\nseaIce: Fixed" + "source_id":"GFDL-ESM4", + "source":"GFDL-ESM4 (2018): \naerosol: interactive\natmos: GFDL-AM4.1 (Cubed-sphere (c96) - 1 degree nominal horizontal resolution; 360 x 180 longitude/latitude; 49 levels; top level 1 Pa)\natmosChem: GFDL-ATMCHEM4.1 (full atmospheric chemistry)\nland: GFDL-LM4.1\nlandIce: GFDL-LM4.1\nocean: GFDL-OM4p5 (GFDL-MOM6, tripolar - nominal 0.5 deg; 720 x 576 longitude/latitude; 75 levels; top grid cell 0-2 m)\nocnBgchem: GFDL-COBALTv2\nseaIce: GFDL-SIM4p5 (GFDL-SIS2.0, tripolar - nominal 0.5 deg; 720 x 576 longitude/latitude; 5 layers; 5 thickness categories)" }, - "NICAM16-9D-L78":{ + "GFDL-OM4p5B":{ "activity_participation":[ - "" + "OMIP" ], "cohort":[ "Registered" ], "institution_id":[ - "MIROC" + "NOAA-GFDL" ], - "source_id":"NICAM16-9D-L78", - "source":"NICAM16-9D-L78 (2017): \naerosol: Prescribed MACv2-SP\natmos: NICAM.16 (14km icosahedral grid; 2,621,442 grid cells (=10*4^9+2); 78 levels; top level 40 km)\natmosChem: none\nland: MATSIRO6 (w/o MOSAIC)\nlandIce: none\nocean: none\nocnBgchem: none\nseaIce: Fixed" + "source_id":"GFDL-OM4p5B", + "source":"GFDL-OM4p5B (2018): \naerosol: none\natmos: none\natmosChem: none\nland: none\nlandIce: none\nocean: GFDL-OM4p5 (GFDL-MOM6, tripolar - nominal 0.5 deg; 720 x 576 longitude/latitude; 75 levels; top grid cell 0-2 m)\nocnBgchem: GFDL-BLINGv2\nseaIce: GFDL-SIM4p5 (GFDL-SIS2.0, tripolar - nominal 0.5 deg; 720 x 576 longitude/latitude; 5 layers; 5 thickness categories)" }, - "NICAM16-9S":{ + "GISS-E2-1-G":{ "activity_participation":[ - "" + "AerChemMIP", + "C4MIP", + "CFMIP", + "CMIP", + "DAMIP", + "DynVarMIP", + "FAFMIP", + "GMMIP", + "ISMIP6", + "LS3MIP", + "LUMIP", + "OMIP", + "PAMIP", + "PMIP", + "RFMIP", + "SIMIP", + "ScenarioMIP", + "VIACSAB", + "VolMIP" ], "cohort":[ "Registered" ], "institution_id":[ - "MIROC" + "NASA-GISS" ], - "source_id":"NICAM16-9S", - "source":"NICAM16-9S (2017): \naerosol: Prescribed MACv2-SP\natmos: NICAM.16 (14km icosahedral grid; 2,621,442 grid cells (=10*4^9+2); 38 levels; top level 40 km)\natmosChem: none\nland: MATSIRO6 (w/o MOSAIC)\nlandIce: none\nocean: none\nocnBgchem: none\nseaIce: Fixed" + "source_id":"GISS-E2-1-G", + "source":"GISS-E2.1G (2016): \naerosol: Varies with physics-version (p==1 none, p==3 OMA, p==4 TOMAS, p==5 MATRIX)\natmos: GISS-E2.1 (2.5x2 degree; 144 x 90 longitude/latitude; 40 levels; top level 0.1 hPa)\natmosChem: Varies with physics-version (p==1 Non-interactive, p>1 GPUCCINI)\nland: GISS LSM\nlandIce: none\nocean: GISS Ocean (1 degree; 360 x 180 latitude/longitude; 32 levels; top grid cell 0-10 m)\nocnBgchem: none\nseaIce: GISS SI" }, - "NorESM2-HH":{ + "GISS-E2-1-H":{ "activity_participation":[ - "HighResMIP" + "CMIP", + "OMIP", + "PAMIP", + "SIMIP", + "ScenarioMIP" ], "cohort":[ "Registered" ], "institution_id":[ - "NCC" + "NASA-GISS" ], - "source_id":"NorESM2-HH", - "source":"NorESM2-HH (2018): \naerosol: OsloAero\natmos: CAM-OSLO (0.25 degree resolution; 1152 x 768; 32 levels; top level 3 mb)\natmosChem: OsloChemSimp\nland: CLM\nlandIce: CISM\nocean: MICOM (0.25 degree resolution; 1440 x 1152; 70 levels; top grid cell minimum 0-2.5 m [native model uses hybrid density and generic upper-layer coordinate interpolated to z-level for contributed data])\nocnBgchem: HAMOCC\nseaIce: CICE" + "source_id":"GISS-E2-1-H", + "source":"GISS-E2.1H (2016): \naerosol: Varies with physics-version (p==1 none, p==3 OMA, p==4 TOMAS, p==5 MATRIX)\natmos: GISS-E2.1 (2.5x2 degree; 144 x 90 longitude/latitude; 40 levels; top level 0.1 hPa)\natmosChem: Varies with physics-version (p==1 Non-interactive, p>1 GPUCCINI)\nland: GISS LSM\nlandIce: none\nocean: HYCOM Ocean (~1 degree tripolar grid; 360 x 180 latitude/longitude; 26 levels; top grid cell 0-10 m)\nocnBgchem: none\nseaIce: GISS SI" }, - "NorESM2-LM":{ + "GISS-E2-1-MA-G":{ + "activity_participation":[ + "CMIP", + "RFMIP", + "VolMIP" + ], + "cohort":[ + "Registered" + ], + "institution_id":[ + "NASA-GISS" + ], + "source_id":"GISS-E2-1-MA-G", + "source":"GISS-E2.1MA-G (2018): \naerosol: Varies with physics-version (p==1 none, p==3 OMA, p==4 TOMAS, p==5 MATRIX)\natmos: GISS-E2.1MA (2.5x2 degree; 144 x 90 longitude/latitude; 102 levels; top level 0.002 hPa)\natmosChem: Varies with physics-version (p==1 Non-interactive, p>1 GPUCCINI)\nland: GISS LSM\nlandIce: none\nocean: GISS Ocean (1 degree; 360 x 180 longitude/latitude; 32 levels; top grid cell 0-10 m)\nocnBgchem: none\nseaIce: GISS SI" + }, + "GISS-E3-G":{ "activity_participation":[ "AerChemMIP", + "C4MIP", "CFMIP", "CMIP", "DAMIP", - "DCPP", + "DynVarMIP", + "FAFMIP", + "GMMIP", + "ISMIP6", + "LS3MIP", "LUMIP", "OMIP", + "PAMIP", "PMIP", "RFMIP", + "SIMIP", "ScenarioMIP", + "VIACSAB", "VolMIP" ], "cohort":[ "Registered" ], "institution_id":[ - "NCC" + "NASA-GISS" ], - "source_id":"NorESM2-LM", - "source":"NorESM2-LM (2017): \naerosol: OsloAero\natmos: CAM-OSLO (2 degree resolution; 144 x 96; 32 levels; top level 3 mb)\natmosChem: OsloChemSimp\nland: CLM\nlandIce: CISM\nocean: MICOM (1 degree resolution; 360 x 384; 70 levels; top grid cell minimum 0-2.5 m [native model uses hybrid density and generic upper-layer coordinate interpolated to z-level for contributed data])\nocnBgchem: HAMOCC\nseaIce: CICE" + "source_id":"GISS-E3-G", + "source":"GISS-E3-G (2018): \naerosol: Varies with physics-version (p==1 none, p==3 OMA, p==4 TOMAS, p==5 MATRIX)\natmos: GISS-E3 (Cubed sphere, C90; 90 x 90 x 6 gridboxes/cubeface, grid resolution aligns with longitude/latitude along central lines for each cubeface; 102 levels; top level 0.002 hPa)\natmosChem: Varies with physics-version (p==1 Non-interactive, p>1 GPUCCINI)\nland: GISS LSM\nlandIce: none\nocean: GISS Ocean (1 degree; 360 x 180 longitude/latitude; 32 levels; top grid cell 0-10 m)\nocnBgchem: none\nseaIce: GISS SI" }, - "NorESM2-LME":{ + "HadGEM3-GC31-HH":{ "activity_participation":[ - "C4MIP", "CMIP", - "GeoMIP", - "LUMIP", - "OMIP" + "HighResMIP" ], "cohort":[ "Registered" ], "institution_id":[ - "NCC" + "MOHC", + "NERC" ], - "source_id":"NorESM2-LME", - "source":"NorESM2-LME (2017): \naerosol: OsloAero\natmos: CAM-OSLO (2 degree resolution; 144 x 96; 32 levels; top level 3 mb)\natmosChem: OsloChemSimp\nland: CLM\nlandIce: CISM\nocean: MICOM (1 degree resolution; 360 x 384; 70 levels; top grid cell minimum 0-2.5 m [native model uses hybrid density and generic upper-layer coordinate interpolated to z-level for contributed data])\nocnBgchem: HAMOCC\nseaIce: CICE" + "source_id":"HadGEM3-GC31-HH", + "source":"HadGEM3-GC31-HH (2016): \naerosol: UKCA-GLOMAP-mode\natmos: MetUM-HadGEM3-GA7.1 (N512; 1024 x 768 longitude/latitude; 85 levels; top level 85 km)\natmosChem: none\nland: JULES-HadGEM3-GL7.1\nlandIce: none\nocean: NEMO-HadGEM3-GO6.0 (eORCA12 tripolar primarily 1/12 deg; 4320 x 3604 longitude/latitude; 75 levels; top grid cell 0-1 m)\nocnBgchem: none\nseaIce: CICE-HadGEM3-GSI8 (eORCA12 tripolar primarily 1/12 deg; 4320 x 3604 longitude/latitude)" }, - "NorESM2-LMEC":{ + "HadGEM3-GC31-HM":{ "activity_participation":[ - "AerChemMIP" + "CMIP", + "HighResMIP" ], "cohort":[ "Registered" ], "institution_id":[ - "NCC" + "MOHC", + "NERC" ], - "source_id":"NorESM2-LMEC", - "source":"NorESM2-LMEC (2017): \naerosol: OsloAero\natmos: CAM-OSLO (2 degree resolution; 144 x 96; 32 levels; top level 3 mb)\natmosChem: OsloChemComp\nland: CLM\nlandIce: CISM\nocean: MICOM (1 degree resolution; 360 x 384; 70 levels; top grid cell minimum 0-2.5 m [native model uses hybrid density and generic upper-layer coordinate interpolated to z-level for contributed data])\nocnBgchem: HAMOCC\nseaIce: CICE" + "source_id":"HadGEM3-GC31-HM", + "source":"HadGEM3-GC31-HM (2016): \naerosol: UKCA-GLOMAP-mode\natmos: MetUM-HadGEM3-GA7.1 (N512; 1024 x 768 longitude/latitude; 85 levels; top level 85 km)\natmosChem: none\nland: JULES-HadGEM3-GL7.1\nlandIce: none\nocean: NEMO-HadGEM3-GO6.0 (eORCA025 tripolar primarily 0.25 deg; 1440 x 1205 longitude/latitude; 75 levels; top grid cell 0-1 m)\nocnBgchem: none\nseaIce: CICE-HadGEM3-GSI8 (eORCA025 tripolar primarily 0.25 deg; 1440 x 1205 longitude/latitude)" }, - "NorESM2-MH":{ + "HadGEM3-GC31-LL":{ "activity_participation":[ - "AerChemMIP", "CFMIP", "CMIP", "DAMIP", + "FAFMIP", + "HighResMIP", + "PMIP", + "RFMIP" + ], + "cohort":[ + "Registered" + ], + "institution_id":[ + "MOHC" + ], + "source_id":"HadGEM3-GC31-LL", + "source":"HadGEM3-GC31-LL (2016): \naerosol: UKCA-GLOMAP-mode\natmos: MetUM-HadGEM3-GA7.1 (N96; 192 x 144 longitude/latitude; 85 levels; top level 85 km)\natmosChem: none\nland: JULES-HadGEM3-GL7.1\nlandIce: none\nocean: NEMO-HadGEM3-GO6.0 (eORCA1 tripolar primarily 1 deg with meridional refinement down to 1/3 degree in the tropics; 360 x 330 longitude/latitude; 75 levels; top grid cell 0-1 m)\nocnBgchem: none\nseaIce: CICE-HadGEM3-GSI8 (eORCA1 tripolar primarily 1 deg; 360 x 330 longitude/latitude)" + }, + "HadGEM3-GC31-LM":{ + "activity_participation":[ + "CMIP", + "HighResMIP" + ], + "cohort":[ + "Registered" + ], + "institution_id":[ + "MOHC" + ], + "source_id":"HadGEM3-GC31-LM", + "source":"HadGEM3-GC31-LM (2016): \naerosol: UKCA-GLOMAP-mode\natmos: MetUM-HadGEM3-GA7.1 (N96; 192 x 144 longitude/latitude; 85 levels; top level 85 km)\natmosChem: none\nland: JULES-HadGEM3-GL7.1\nlandIce: none\nocean: NEMO-HadGEM3-GO6.0 (eORCA025 tripolar primarily 0.25 deg; 1440 x 1205 longitude/latitude; 75 levels; top grid cell 0-1 m)\nocnBgchem: none\nseaIce: CICE-HadGEM3-GSI8 (eORCA025 tripolar primarily 0.25 deg; 1440 x 1205 longitude/latitude)" + }, + "HadGEM3-GC31-MH":{ + "activity_participation":[ + "CMIP", + "HighResMIP" + ], + "cohort":[ + "Registered" + ], + "institution_id":[ + "MOHC" + ], + "source_id":"HadGEM3-GC31-MH", + "source":"HadGEM3-GC31-MH (2016): \naerosol: UKCA-GLOMAP-mode\natmos: MetUM-HadGEM3-GA7.1 (N216; 432 x 324 longitude/latitude; 85 levels; top level 85 km)\natmosChem: none\nland: JULES-HadGEM3-GL7.1\nlandIce: none\nocean: NEMO-HadGEM3-GO6.0 (eORCA12 tripolar primarily 1/12 deg; 4320 x 3604 longitude/latitude; 75 levels; top grid cell 0-1 m)\nocnBgchem: none\nseaIce: CICE-HadGEM3-GSI8 (eORCA12 tripolar primarily 1/12 deg; 4320 x 3604 longitude/latitude)" + }, + "HadGEM3-GC31-MM":{ + "activity_participation":[ + "CMIP", + "DCPP", + "GMMIP", + "HighResMIP", + "LS3MIP", + "OMIP" + ], + "cohort":[ + "Registered" + ], + "institution_id":[ + "MOHC" + ], + "source_id":"HadGEM3-GC31-MM", + "source":"HadGEM3-GC31-MM (2016): \naerosol: UKCA-GLOMAP-mode\natmos: MetUM-HadGEM3-GA7.1 (N216; 432 x 324 longitude/latitude; 85 levels; top level 85 km)\natmosChem: none\nland: JULES-HadGEM3-GL7.1\nlandIce: none\nocean: NEMO-HadGEM3-GO6.0 (eORCA025 tripolar primarily 0.25 deg; 1440 x 1205 longitude/latitude; 75 levels; top grid cell 0-1 m)\nocnBgchem: none\nseaIce: CICE-HadGEM3-GSI8 (eORCA025 tripolar primarily 0.25 deg; 1440 x 1205 longitude/latitude)" + }, + "ICON-ESM-LR":{ + "activity_participation":[ + "CMIP", "OMIP", - "RFMIP", - "ScenarioMIP" + "SIMIP" ], "cohort":[ "Registered" ], "institution_id":[ - "NCC" + "MPI-M" ], - "source_id":"NorESM2-MH", - "source":"NorESM2-MH (2017): \naerosol: OsloAero\natmos: CAM-OSLO (1 degree resolution; 288 x 192; 32 levels; top level 3 mb)\natmosChem: OsloChemSimp\nland: CLM\nlandIce: CISM\nocean: MICOM (0.25 degree resolution; 1440 x 1152; 70 levels; top grid cell minimum 0-2.5 m [native model uses hybrid density and generic upper-layer coordinate interpolated to z-level for contributed data])\nocnBgchem: HAMOCC\nseaIce: CICE" + "source_id":"ICON-ESM-LR", + "source":"ICON-ESM-LR (2017): \naerosol: none, prescribed MACv2-SP\natmos: ICON-A (icosahedral/triangles; 160 km; 47 levels; top level 80 km)\natmosChem: none\nland: JSBACH4.20\nlandIce: none/prescribed\nocean: ICON-O (icosahedral/triangles; 40 km; 40 levels; top grid cell 0-12 m)\nocnBgchem: HAMOCC\nseaIce: unnamed (thermodynamic (Semtner zero-layer) dynamic (Hibler 79) sea ice model)" }, - "NorESM2-MM":{ + "IITM-ESM":{ "activity_participation":[ - "AerChemMIP", + "CMIP", + "GMMIP" + ], + "cohort":[ + "Registered" + ], + "institution_id":[ + "CCCR-IITM" + ], + "source_id":"IITM-ESM", + "source":"IITM-ESM (2015): \naerosol: prescribed MAC-v2\natmos: IITM-GFSv1 (T62L64, Linearly Reduced Gaussian Grid; 192 x 94 longitude/latitude; 64 levels; top level 0.2 mb)\natmosChem: none\nland: NOAH LSMv2.7.1\nlandIce: none\nocean: MOM4p1 (tripolar, primarily 1deg; 360 x 200 longitude/latitude; 50 levels; top grid cell 0-10 m)\nocnBgchem: TOPAZv2.0\nseaIce: SISv1.0" + }, + "INM-CM4-8":{ + "activity_participation":[ + "CMIP", + "PMIP" + ], + "cohort":[ + "Registered" + ], + "institution_id":[ + "INM" + ], + "source_id":"INM-CM4-8", + "source":"INM-CM4-8 (2016): \naerosol: INM-AER1\natmos: INM-AM4-8 (2x1.5; 180 x 120 longitude/latitude; 21 levels; top level sigma = 0.01)\natmosChem: none\nland: INM-LND1\nlandIce: none\nocean: INM-OM5 (North Pole shifted to 60N, 90E; 360 x 318 longitude/latitude; 40 levels; sigma vertical coordinate)\nocnBgchem: none\nseaIce: INM-ICE1" + }, + "INM-CM5-0":{ + "activity_participation":[ + "CMIP" + ], + "cohort":[ + "Registered" + ], + "institution_id":[ + "INM" + ], + "source_id":"INM-CM5-0", + "source":"INM-CM5-0 (2016): \naerosol: INM-AER1\natmos: INM-AM5-0 (2x1.5; 180 x 120 longitude/latitude; 73 levels; top level sigma = 0.0002)\natmosChem: none\nland: INM-LND1\nlandIce: none\nocean: INM-OM5 (North Pole shifted to 60N, 90E. 0.5x0.25; 720 x 720 longitude/latitude; 40 levels; vertical sigma coordinate)\nocnBgchem: none\nseaIce: INM-ICE1" + }, + "INM-CM5-H":{ + "activity_participation":[ + "CMIP" + ], + "cohort":[ + "Registered" + ], + "institution_id":[ + "INM" + ], + "source_id":"INM-CM5-H", + "source":"INM-CM5-H (2016): \naerosol: INM-AER1\natmos: INM-AM5-H (0.67x0.5; 540 x 360 longitude/latitude; 73 levels; top level sigma = 0.0002)\natmosChem: none\nland: INM-LND1\nlandIce: none\nocean: INM-OM5-H (North Pole shifted to 60N, 90E. 0.167x0.125; 2160x1440 longitude/latitude; 40 levels; vertical sigma coordinate)\nocnBgchem: none\nseaIce: INM-ICE1" + }, + "IPSL-CM6A-ATM-HR":{ + "activity_participation":[ + "HighResMIP" + ], + "cohort":[ + "Registered" + ], + "institution_id":[ + "IPSL" + ], + "source_id":"IPSL-CM6A-ATM-HR", + "source":"IPSL-CM6A-ATM-HR (2018): \naerosol: none\natmos: LMDZ (NPv6, N256; 512 x 360 longitude/latitude; 79 levels; top level 40000 m)\natmosChem: none\nland: ORCHIDEE (v2.0, Water/Carbon/Energy mode)\nlandIce: none\nocean: none\nocnBgchem: none\nseaIce: none" + }, + "IPSL-CM6A-LR":{ + "activity_participation":[ + "C4MIP", "CFMIP", "CMIP", - "DAMIP", + "DCPP", + "FAFMIP", + "GMMIP", + "GeoMIP", + "LS3MIP", + "LUMIP", "OMIP", + "PMIP", "RFMIP", + "ScenarioMIP", + "VolMIP" + ], + "cohort":[ + "Registered" + ], + "institution_id":[ + "IPSL" + ], + "source_id":"IPSL-CM6A-LR", + "source":"IPSL-CM6A-LR (2017): \naerosol: none\natmos: LMDZ (NPv6, N96; 144 x 143 longitude/latitude; 79 levels; top level 40000 m)\natmosChem: none\nland: ORCHIDEE (v2.0, Water/Carbon/Energy mode)\nlandIce: none\nocean: NEMO-OPA (eORCA1.3, tripolar primarily 1deg; 362 x 332 longitude/latitude; 75 levels; top grid cell 0-2 m)\nocnBgchem: NEMO-PISCES\nseaIce: NEMO-LIM3" + }, + "KACE-1-0-G":{ + "activity_participation":[ + "CMIP", "ScenarioMIP" ], "cohort":[ "Registered" ], "institution_id":[ - "NCC" + "NIMS-KMA" ], - "source_id":"NorESM2-MM", - "source":"NorESM2-MM (2017): \naerosol: OsloAero\natmos: CAM-OSLO (1 degree resolution; 288 x 192; 32 levels; top level 3 mb)\natmosChem: OsloChemSimp\nland: CLM\nlandIce: CISM\nocean: MICOM (1 degree resolution; 360 x 384; 70 levels; top grid cell minimum 0-2.5 m [native model uses hybrid density and generic upper-layer coordinate interpolated to z-level for contributed data])\nocnBgchem: HAMOCC\nseaIce: CICE" + "source_id":"KACE-1-0-G", + "source":"KACE1.0-G (2018): \naerosol: UKCA-GLOMAP-mode\natmos: MetUM-HadGEM3-GA7.1 (N96; 192 x 144 longitude/latitude; 85 levels; top level 85 km)\natmosChem: none\nland: JULES-HadGEM3-GL7.1\nlandIce: none\nocean: MOM4p1 (tripolar primarily 1deg; 360 x 200 longitude/latitude; 50 levels; top grid cell 0-10 m)\nocnBgchem: none\nseaIce: CICE-HadGEM3-GSI8 (tripolar primarily 1deg; 360 x 200 longitude/latitude)" }, - "PCMDI-test-1-0":{ + "KIOST-ESM":{ "activity_participation":[ - "CMIP" + "C4MIP", + "CMIP", + "DynVarMIP", + "PMIP" ], "cohort":[ "Registered" ], "institution_id":[ - "PCMDI" + "KIOST" ], - "source_id":"PCMDI-test-1-0", - "source":"PCMDI-test 1.0 (1989): \naerosol: none\natmos: Earth1.0-gettingHotter (360x180; 50 levels; top level 0.1 mb)\natmosChem: none\nland: Earth1.0\nlandIce: none\nocean: BlueMarble1.0-warming (360x180; 50 levels; top grid cell 0-10m)\nocnBgchem: none\nseaIce: Declining1.0-warming" + "source_id":"KIOST-ESM", + "source":"KIOST-ESM (2018): \naerosol: none\natmos: GFDL-AM2.0 (cubed sphere (C48); 192 x 96 longitude/latitude; 32 vertical levels; top level 2 hPa)\natmosChem: Simple carbon aerosol model (emission type)\nland: NCAR-CLM4\nlandIce: NCAR-CLM4\nocean: GFDL-MOM5.0 (tripolar - nominal 1.0 deg; 360 x 200 longitude/latitude; 52 levels; top grid cell 0-2 m; NK mixed layer scheme)\nocnBgchem: TOPAZ2\nseaIce: GFDL-SIS" }, - "UKESM1-0-LL":{ + "LBLRTM-12-8":{ "activity_participation":[ - "" + "RFMIP" ], "cohort":[ "Registered" ], "institution_id":[ - "MOHC", - "NERC" + "AER" ], - "source_id":"UKESM1-0-LL", - "source":"UKESM1.0-LL (2017): \naerosol: UKCA-GLOMAP-mode\natmos: MetUM-HadGEM3-GA7.1 (192 x 144 N96; 85 levels; top level 85km)\natmosChem: UKCA-StratTrop\nland: JULES-HadGEM3-GL7.1\nlandIce: BISICLES (only active in ISMIP experiments)\nocean: NEMO-HadGEM3-GO6.0 (ORCA1 tripolar primarily 1 deg 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"gr1":"regridded data reported on a grid other than the native grid and other than the preferred target grid", + "gr1a":"regridded data reported in the region of Antarctica on a grid other than the native grid and other than the preferred target grid", + "gr1g":"regridded data reported in the region of Greenland on a grid other than the native grid and other than the preferred target grid", + "gr1z":"regridded zonal mean data reported on a grid other than the native latitude grid and other than the preferred latitude target grid", + "gr2":"regridded data reported on a grid other than the native grid and other than the preferred target grid", + "gr2a":"regridded data reported in the region of Antarctica on a grid other than the native grid and other than the preferred target grid", + "gr2g":"regridded data reported in the region of Greenland on a grid other than the native grid and other than the preferred target grid", + "gr2z":"regridded zonal mean data reported on a grid other than the native latitude grid and other than the preferred latitude target grid", + "gr3":"regridded data reported on a grid other than the native grid and other than the preferred target grid", + "gr3a":"regridded data reported in the region of Antarctica on a grid other than the native grid and other than the preferred target grid", + "gr3g":"regridded data reported in the region of Greenland on a grid other than the native grid and other than the preferred target grid", + "gr3z":"regridded zonal mean data reported on a grid other than the native latitude grid and other than the preferred latitude target grid", + "gr4":"regridded data reported on a grid other than the native grid and other than the preferred target grid", + "gr4a":"regridded data reported in the region of Antarctica on a grid other than the native grid and other than the preferred target grid", + "gr4g":"regridded data reported in the region of Greenland on a grid other than the native grid and other than the preferred target grid", + "gr4z":"regridded zonal mean data reported on a grid other than the native latitude grid and other than the preferred latitude target grid", + "gr5":"regridded data reported on a grid other than the native grid and other than the preferred target grid", + "gr5a":"regridded data reported in the region of Antarctica on a grid other than the native grid and other than the preferred target grid", + "gr5g":"regridded data reported in the region of Greenland on a grid other than the native grid and other than the preferred target grid", + "gr5z":"regridded zonal mean data reported on a grid other than the native latitude grid and other than the preferred latitude target grid", + "gr6":"regridded data reported on a grid other than the native grid and other than the preferred target grid", + "gr6a":"regridded data reported in the region of Antarctica on a grid other than the native grid and other than the preferred target grid", + "gr6g":"regridded data reported in the region of Greenland on a grid other than the native grid and other than the preferred target grid", + "gr6z":"regridded zonal mean data reported on a grid other than the native latitude grid and other than the preferred latitude target grid", + "gr7":"regridded data reported on a grid other than the native grid and other than the preferred target grid", + "gr7a":"regridded data reported in the region of Antarctica on a grid other than the native grid and other than the preferred target grid", + "gr7g":"regridded data reported in the region of Greenland on a grid other than the native grid and other than the preferred target grid", + "gr7z":"regridded zonal mean data reported on a grid other than the native latitude grid and other than the preferred latitude target grid", + "gr8":"regridded data reported on a grid other than the native grid and other than the preferred target grid", + "gr8a":"regridded data reported in the region of Antarctica on a grid other than the native grid and other than the preferred target grid", + "gr8g":"regridded data reported in the region of Greenland on a grid other than the native grid and other than the preferred target grid", + "gr8z":"regridded zonal mean data reported on a grid other than the native latitude grid and other than the preferred latitude target grid", + "gr9":"regridded data reported on a grid other than the native grid and other than the preferred target grid", + "gr9a":"regridded data reported in the region of Antarctica on a grid other than the native grid and other than the preferred target grid", + "gr9g":"regridded data reported in the region of Greenland on a grid other than the native grid and other than the preferred target grid", + "gr9z":"regridded zonal mean data reported on a grid other than the native latitude grid and other than the preferred latitude target grid", + "gra":"regridded data in the region of Antarctica reported on the data provider's preferred target grid", + "grg":"regridded data in the region of Greenland reported on the data provider's preferred target grid", + "grz":"regridded zonal mean data reported on the data provider's preferred latitude target grid" + }, + "nominal_resolution":[ + "0.5 km", + "1 km", + "10 km", + "100 km", + "1000 km", + "10000 km", + "1x1 degree", + "2.5 km", + "25 km", + "250 km", + "2500 km", + "5 km", + "50 km", + "500 km", + "5000 km" + ], + "realm":{ + "aerosol":"Aerosol", + "atmos":"Atmosphere", + "atmosChem":"Atmospheric Chemistry", + "land":"Land Surface", + "landIce":"Land Ice", + "ocean":"Ocean", + "ocnBgchem":"Ocean Biogeochemistry", + "seaIce":"Sea Ice" + }, + "table_id":[ + "3hr", + "6hrLev", "6hrPlev", "6hrPlevPt", "AERday", @@ -1059,7 +2138,7 @@ "fx" ], "license":[ - "^CMIP6 model data produced by .* is licensed under a Creative Commons Attribution.*ShareAlike 4.0 International License (https://creativecommons.org/licenses)\\. Consult https://pcmdi.llnl.gov/CMIP6/TermsOfUse for terms of use governing CMIP6 output, including citation requirements and proper acknowledgment\\. Further information about this data, including some limitations, can be found via the further_info_url (recorded as a global attribute in this file) .*\\. The data producers and data providers make no warranty, either express or implied, including, but not limited to, warranties of merchantability and fitness for a particular purpose\\. All liabilities arising from the supply of the information (including any liability arising in negligence) are excluded to the fullest extent permitted by law\\.$" + "^CMIP6 model data produced by .* is licensed under a Creative Commons Attribution.*ShareAlike 4.0 International License .https://creativecommons.org/licenses.* *Consult https://pcmdi.llnl.gov/CMIP6/TermsOfUse for terms of use governing CMIP6 output, including citation requirements and proper acknowledgment\\. *Further information about this data, including some limitations, can be found via the further_info_url (recorded as a global attribute in this file).*\\. *The data producers and data providers make no warranty, either express or implied, including, but not limited to, warranties of merchantability and fitness for a particular purpose\\. *All liabilities arising from the supply of the information (including any liability arising in negligence) are excluded to the fullest extent permitted by law\\.$" ], "mip_era":[ "CMIP6" @@ -1149,442 +2228,1375 @@ "CHEM", "BGC" ], - "description":"DECK: 1pctCO2", - "end_year":"", - "experiment":"1 percent per year increase in CO2", - "experiment_id":"1pctCO2", - "min_number_yrs_per_sim":"150", + "experiment":"1 percent per year increase in CO2", + "experiment_id":"1pctCO2", + "parent_activity_id":[ + "CMIP" + ], + "parent_experiment_id":[ + "piControl" + ], + "required_model_components":[ + "AOGCM" + ], + "sub_experiment_id":[ + "none" + ] + }, + "1pctCO2-4xext":{ + "activity_id":[ + "ISMIP6" + ], + "additional_allowed_model_components":[ + "AER", + "CHEM", + "BGC" + ], + "experiment":"extension from year 140 of 1pctCO2 with 4xCO2", + "experiment_id":"1pctCO2-4xext", + "parent_activity_id":[ + "CMIP" + ], + "parent_experiment_id":[ + "1pctCO2" + ], + "required_model_components":[ + "AOGCM" + ], + "sub_experiment_id":[ + "none" + ] + }, + "1pctCO2-bgc":{ + "activity_id":[ + "C4MIP" + ], + "additional_allowed_model_components":[ + "AER", + "CHEM" + ], + 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"G7cirrus":{ + "dcppA-historical-niff":{ "activity_id":[ - "GeoMIP" + "DCPP" ], "additional_allowed_model_components":[ "AER", "CHEM", "BGC" ], - "description":"Against a background of the ScenarioMIP high forcing, reduce cirrus cloud optical depth by a constant amount", - "end_year":"2100", - "experiment":"increase cirrus ice crystal fall speed to reduce net forcing in SSP585 by 1 W m-2", - "experiment_id":"G7cirrus", - "min_number_yrs_per_sim":"86", + "experiment":"hindcast initialized from historical climate simulation but without using knowledge of subsequent historical forcing", + "experiment_id":"dcppA-historical-niff", "parent_activity_id":[ "CMIP" ], @@ -1594,110 +3606,139 @@ "required_model_components":[ "AOGCM" ], - "start_year":"2015", - "sub_experiment_id":[ - "none" - ], - "tier":"1" - }, - "a4SST":{ - "activity_id":[ - "CFMIP" - ], - "additional_allowed_model_components":[ - "AER", - "CHEM" - ], - "description":"As piSST, but with monthly-varying SSTs taken from years 111-140 of each model's own abrupt4xCO2 experiment instead of from piControl. Sea-ice is unchanged from piSST", - "end_year":"", - "experiment":"as piSST but with SSTs from abrupt4xCO2", - "experiment_id":"a4SST", - "min_number_yrs_per_sim":"30", - "parent_activity_id":[ - "CMIP" - ], - "parent_experiment_id":[ - "abrupt4xCO2" - ], - "required_model_components":[ - "AGCM" - ], - "start_year":"", "sub_experiment_id":[ - "none" - ], - "tier":"2" + "s1960", + "s1961", + "s1962", + "s1963", + "s1964", + "s1965", + "s1966", + "s1967", + "s1968", + "s1969", + "s1970", + "s1971", + "s1972", + "s1973", + "s1974", + "s1975", + "s1976", + "s1977", + "s1978", + "s1979", + "s1980", + "s1981", + "s1982", + "s1983", + "s1984", + "s1985", + "s1986", + "s1987", + "s1988", + "s1989", + "s1990", + "s1991", + "s1992", + "s1993", + "s1994", + "s1995", + "s1996", + "s1997", + "s1998", + "s1999", + "s2000", + "s2001", + "s2002", + "s2003", + "s2004", + "s2005", + "s2006", + "s2007", + "s2008", + "s2009", + "s2010", + "s2011", + "s2012", + "s2013", + "s2014", + "s2015", + "s2016" + ] }, - "a4SSTice":{ + "dcppB-forecast":{ "activity_id":[ - "CFMIP" + "DCPP" ], "additional_allowed_model_components":[ "AER", - "CHEM" + "CHEM", + "BGC" ], - "description":"As piSST, but with monthly-varying SSTs and sea-ice taken from years 111-140 of each model's own abrupt4xCO2 experiment instead of from piControl", - "end_year":"", - "experiment":"as piSST but with SSTs and sea ice from abrupt4xCO2", - "experiment_id":"a4SSTice", - "min_number_yrs_per_sim":"30", + "experiment":"forecast initialized from observations with forcing from ssp245", + "experiment_id":"dcppB-forecast", "parent_activity_id":[ - "CMIP" + "no parent", + "DCPP" ], "parent_experiment_id":[ - "abrupt4xCO2" + "no parent", + "dcppA-assim" ], "required_model_components":[ - "AGCM" + "AOGCM" ], - "start_year":"", "sub_experiment_id":[ - "none" - ], - "tier":"2" + "s2017", + "s2018", + "s2019", + "s2020", + "s2021", + "s2022", + "s2023", + "s2024", + "s2025", + "s2026", + "s2027", + "s2028", + "s2029" + ] }, - "a4SSTice-4xCO2":{ + "dcppC-amv-ExTrop-neg":{ "activity_id":[ - "CFMIP" + "DCPP" ], "additional_allowed_model_components":[ "AER", - "CHEM" + "CHEM", + "BGC" ], - "description":"As a4SSTice, but CO2 is quadrupled, and the increase in CO2 is seen by both the radiation scheme and vegetation", - "end_year":"", - "experiment":"as piSST but with SSTs and sea ice from abrupt4xCO2, and 4xCO2 seen by radiation and vegetation", - "experiment_id":"a4SSTice-4xCO2", - "min_number_yrs_per_sim":"30", + "experiment":"Idealized climate impact of negative extratropical AMV anomaly pattern", + "experiment_id":"dcppC-amv-ExTrop-neg", "parent_activity_id":[ "CMIP" ], "parent_experiment_id":[ - "abrupt4xCO2" + "piControl" ], "required_model_components":[ - "AGCM" + "AOGCM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "abrupt-0p5xCO2":{ + "dcppC-amv-ExTrop-pos":{ "activity_id":[ - "CFMIP" + "DCPP" ], "additional_allowed_model_components":[ "AER", "CHEM", "BGC" ], - "description":"Identical to the DECK abrupt-4xCO2, but at 0.5xCO2", - "end_year":"", - "experiment":"abrupt halving of CO2", - "experiment_id":"abrupt-0p5xCO2", - "min_number_yrs_per_sim":"150", + "experiment":"Idealized climate impact of positive extratropical AMV anomaly pattern", + "experiment_id":"dcppC-amv-ExTrop-pos", "parent_activity_id":[ "CMIP" ], @@ -1707,26 +3748,21 @@ "required_model_components":[ "AOGCM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "abrupt-2xCO2":{ + "dcppC-amv-Trop-neg":{ "activity_id":[ - "CFMIP" + "DCPP" ], "additional_allowed_model_components":[ "AER", "CHEM", "BGC" ], - "description":"Identical to the DECK abrupt-4xCO2, but at 2xCO2", - "end_year":"", - "experiment":"abrupt doubling of CO2", - "experiment_id":"abrupt-2xCO2", - "min_number_yrs_per_sim":"150", + "experiment":"Idealized climate impact of negative tropical AMV anomaly pattern", + "experiment_id":"dcppC-amv-Trop-neg", "parent_activity_id":[ "CMIP" ], @@ -1736,26 +3772,21 @@ "required_model_components":[ "AOGCM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "abrupt-4xCO2":{ + "dcppC-amv-Trop-pos":{ "activity_id":[ - "CMIP" + "DCPP" ], "additional_allowed_model_components":[ "AER", "CHEM", "BGC" ], - "description":"DECK: abrupt4xCO2", - "end_year":"", - "experiment":"abrupt quadrupling of CO2", - "experiment_id":"abrupt-4xCO2", - "min_number_yrs_per_sim":"150", + "experiment":"idealized positive tropical AMV anomaly pattern", + "experiment_id":"dcppC-amv-Trop-pos", "parent_activity_id":[ "CMIP" ], @@ -1765,26 +3796,21 @@ "required_model_components":[ "AOGCM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "abrupt-solm4p":{ + "dcppC-amv-neg":{ "activity_id":[ - "CFMIP" + "DCPP" ], "additional_allowed_model_components":[ "AER", "CHEM", "BGC" ], - "description":"Conceptually similar to abrupt 4xCO2 DECK experiment, except that the solar constant rather than CO2 is abruptly reduced by 4%", - "end_year":"", - "experiment":"abrupt 4% decrease in solar constant", - "experiment_id":"abrupt-solm4p", - "min_number_yrs_per_sim":"150", + "experiment":"Idealized climate impact of negative AMV anomaly pattern", + "experiment_id":"dcppC-amv-neg", "parent_activity_id":[ "CMIP" ], @@ -1794,26 +3820,21 @@ "required_model_components":[ "AOGCM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "abrupt-solp4p":{ + "dcppC-amv-pos":{ "activity_id":[ - "CFMIP" + "DCPP" ], "additional_allowed_model_components":[ "AER", "CHEM", "BGC" ], - "description":"Conceptually similar to abrupt 4xCO2 DECK experiment, except that the solar constant rather than CO2 is abruptly increased by 4%", - "end_year":"", - "experiment":"abrupt 4% increase in solar constant", - "experiment_id":"abrupt-solp4p", - "min_number_yrs_per_sim":"150", + "experiment":"Idealized climate impact of positive AMV anomaly pattern", + "experiment_id":"dcppC-amv-pos", "parent_activity_id":[ "CMIP" ], @@ -1823,81 +3844,71 @@ "required_model_components":[ "AOGCM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "amip":{ + "dcppC-atl-control":{ "activity_id":[ - "CMIP" + "DCPP" ], "additional_allowed_model_components":[ "AER", - "CHEM" + "CHEM", + "BGC" ], - "description":"DECK: AMIP", - "end_year":"2014", - "experiment":"AMIP", - "experiment_id":"amip", - "min_number_yrs_per_sim":"36", + "experiment":"Idealized Atlantic control", + "experiment_id":"dcppC-atl-control", "parent_activity_id":[ - "no parent" + "CMIP" ], "parent_experiment_id":[ - "no parent" + "piControl" ], "required_model_components":[ - "AGCM" + "AOGCM" ], - "start_year":"1979", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "amip-4xCO2":{ + "dcppC-atl-pacemaker":{ "activity_id":[ - "CFMIP" + "DCPP" ], "additional_allowed_model_components":[ "AER", - "CHEM" + "CHEM", + "BGC" ], - "description":"As CMIP5/CFMIP-2 amip4xCO2 experiment. AMIP experiment where SSTs are held at control values and the CO2 seen by the radiation scheme is quadrupled", - "end_year":"2014", - "experiment":"AMIP SSTs with 4xCO2", - "experiment_id":"amip-4xCO2", - "min_number_yrs_per_sim":"36", + "experiment":"pacemaker Atlantic experiment", + "experiment_id":"dcppC-atl-pacemaker", "parent_activity_id":[ - "no parent" + "CMIP" ], "parent_experiment_id":[ - "no parent" + "historical" ], "required_model_components":[ - "AGCM" + "AOGCM" ], - "start_year":"1979", "sub_experiment_id":[ - "none" - ], - "tier":"1" + "s1910", + "s1920", + "s1950" + ] }, - "amip-TIP":{ + "dcppC-atl-spg":{ "activity_id":[ - "GMMIP" + "DCPP" ], "additional_allowed_model_components":[ "AER", - "CHEM" + "CHEM", + "BGC" ], - "description":"The topography of the TIP is modified by setting surface elevations to 500m; to understand the combined thermal and mechanical forcing of the TIP. Same model as DECK", - "end_year":"2014", - "experiment":"same as \"amip\" run, but surface elevations of the Tibetan-Iranian Plateau and Himalayas reduced to 500m", - "experiment_id":"amip-TIP", - "min_number_yrs_per_sim":"36", + "experiment":"predictability of 1990s warming of Atlantic sub-polar gyre", + "experiment_id":"dcppC-atl-spg", "parent_activity_id":[ "no parent" ], @@ -1905,1068 +3916,764 @@ "no parent" ], "required_model_components":[ - "AGCM" + "AOGCM" ], - "start_year":"1979", "sub_experiment_id":[ - "none" - ], - "tier":"3" + "s1992", + "s1993", + "s1994", + "s1995", + "s1996", + "s1997", + "s1998", + "s1999" + ] }, - "amip-TIP-nosh":{ + "dcppC-forecast-addAgung":{ "activity_id":[ - "GMMIP" + "DCPP" ], "additional_allowed_model_components":[ "AER", - "CHEM" + "CHEM", + "BGC" ], - "description":"Surface sensible heat released at the elevation above 500m over the TIP is not allowed to heat the atmosphere. Same model as DECK", - "end_year":"2014", - "experiment":"same as \"amip\" run, but sensible heat not allowed for elevations of the Tibetan-Iranian Plateau and Himalayas above 500m", - "experiment_id":"amip-TIP-nosh", - "min_number_yrs_per_sim":"36", + "experiment":"2015 forecast with added Agung forcing", + "experiment_id":"dcppC-forecast-addAgung", "parent_activity_id":[ - "no parent" + "no parent", + "DCPP" ], "parent_experiment_id":[ - "no parent" + "no parent", + "dcppA-assim" ], "required_model_components":[ - "AGCM" + "AOGCM" ], - "start_year":"1979", "sub_experiment_id":[ - "none" - ], - "tier":"3" + "s2014" + ] }, - "amip-a4SST-4xCO2":{ + "dcppC-forecast-addElChichon":{ "activity_id":[ - "CFMIP" + "DCPP" ], "additional_allowed_model_components":[ "AER", - "CHEM" + "CHEM", + "BGC" ], - "description":"Same as amip, but a patterned SST anomaly is applied on top of the monthly-varying amip SSTs. This anomaly is a monthly climatology, taken from each model's own abrupt4xCO2 run minus piControl (using the mean of years 111-140 of abrupt4xCO2, and the parallel 30-year section of piControl). CO2 is quadrupled, and the increase in CO2 is seen by both the radiation scheme and vegetation", - "end_year":"2014", - "experiment":"as AMIP but with warming pattern from abrupt4xCO2 added to SSTs and 4xCO2 seen by radiation and vegetation", - "experiment_id":"amip-a4SST-4xCO2", - "min_number_yrs_per_sim":"36", + "experiment":"2015 forecast with added El Chichon forcing", + "experiment_id":"dcppC-forecast-addElChichon", "parent_activity_id":[ - "no parent" + "no parent", + "DCPP" ], "parent_experiment_id":[ - "no parent" + "no parent", + "dcppA-assim" ], "required_model_components":[ - "AGCM" + "AOGCM" ], - "start_year":"1979", "sub_experiment_id":[ - "none" - ], - "tier":"2" + "s2014" + ] }, - "amip-future4K":{ + "dcppC-forecast-addPinatubo":{ "activity_id":[ - "CFMIP" + "DCPP VolMIP" ], "additional_allowed_model_components":[ "AER", - "CHEM" + "CHEM", + "BGC" ], - "description":"As CMIP5/CFMIP-2 amipFuture experiment. AMIP experiment where SSTs are subject to a composite SST warming pattern derived from coupled models, scaled to an ice-free ocean mean of 4K", - "end_year":"2014", - "experiment":"AMIP with patterned 4K SST increase", - "experiment_id":"amip-future4K", - "min_number_yrs_per_sim":"36", + "experiment":"2015 forecast with added Pinatubo forcing", + "experiment_id":"dcppC-forecast-addPinatubo", "parent_activity_id":[ - "no parent" + "no parent", + "DCPP" ], "parent_experiment_id":[ - "no parent" + "no parent", + "dcppA-assim" ], "required_model_components":[ - "AGCM" + "AOGCM" ], - "start_year":"1979", "sub_experiment_id":[ - "none" - ], - "tier":"1" + "s2014" + ] }, - "amip-hist":{ + "dcppC-hindcast-noAgung":{ "activity_id":[ - "GMMIP" + "DCPP" ], "additional_allowed_model_components":[ "AER", - "CHEM" + "CHEM", + "BGC" ], - "description":"Extended AMIP run that covers 1870-2014. All natural and anthropogenic historical forcings as used in CMIP6 Historical Simulation will be included. AGCM resolution as CMIP6 Historical Simulation. The HadISST data will be used", - "end_year":"2014", - "experiment":"AMIP-style simulation covering the period 1870-2014", - "experiment_id":"amip-hist", - "min_number_yrs_per_sim":"144", + "experiment":"hindcast but with only background volcanic forcing to be the same as that used in the 2015 forecast", + "experiment_id":"dcppC-hindcast-noAgung", "parent_activity_id":[ - "no parent" + "no parent", + "DCPP" ], "parent_experiment_id":[ - "no parent" + "no parent", + "dcppA-assim" ], "required_model_components":[ - "AGCM" + "AOGCM" ], - "start_year":"1870", "sub_experiment_id":[ - "none" - ], - "tier":"1" + "s1962" + ] }, - "amip-hld":{ + "dcppC-hindcast-noElChichon":{ "activity_id":[ - "GMMIP" + "DCPP" ], "additional_allowed_model_components":[ "AER", - "CHEM" + "CHEM", + "BGC" ], - "description":"The topography of the highlands in Africa, N. America and S. America TP is modified by setting surface elevations to a certain height (500m). Same model as DECK", - "end_year":"2014", - "experiment":"same as \"amip\" run, but surface elevations of the East African Highlands in Africa, Sierra Madre in N. America and Andes in S. America reduced to 500m", - "experiment_id":"amip-hld", - "min_number_yrs_per_sim":"36", + "experiment":"hindcast but with only background volcanic forcing to be the same as that used in the 2015 forecast", + "experiment_id":"dcppC-hindcast-noElChichon", "parent_activity_id":[ - "no parent" + "no parent", + "DCPP" ], "parent_experiment_id":[ - "no parent" + "no parent", + "dcppA-assim" ], "required_model_components":[ - "AGCM" + "AOGCM" ], - "start_year":"1979", "sub_experiment_id":[ - "none" - ], - "tier":"3" + "s1981" + ] }, - "amip-lfmip-pObs":{ + "dcppC-hindcast-noPinatubo":{ "activity_id":[ - "LS3MIP" + "DCPP" ], "additional_allowed_model_components":[ "AER", "CHEM", "BGC" ], - "description":"Land-hist land conditions; AMIP SSTs", - "end_year":"2014", - "experiment":"prescribed land (from pseudo-observations) and AMIP SSTs", - "experiment_id":"amip-lfmip-pObs", - "min_number_yrs_per_sim":"36", + "experiment":"hindcast but with only background volcanic forcing to be the same as that used in the 2015 forecast", + "experiment_id":"dcppC-hindcast-noPinatubo", "parent_activity_id":[ - "no parent" + "no parent", + "DCPP" ], "parent_experiment_id":[ - "no parent" + "no parent", + "dcppA-assim" ], "required_model_components":[ - "AGCM" + "AOGCM" ], - "start_year":"1979", "sub_experiment_id":[ - "none" - ], - "tier":"2" + "s1990" + ] }, - "amip-lfmip-pdLC":{ + "dcppC-ipv-NexTrop-neg":{ "activity_id":[ - "LS3MIP" + "DCPP" ], "additional_allowed_model_components":[ "AER", "CHEM", "BGC" ], - "description":"Prescribed land conditions 1980-2014 climate; AMIP SSTs", - "end_year":"2014", - "experiment":"prescribed land (from current climatology) and AMIP SSTs", - "experiment_id":"amip-lfmip-pdLC", - "min_number_yrs_per_sim":"36", + "experiment":"idealized negative northern extratropical IPV anomaly pattern", + "experiment_id":"dcppC-ipv-NexTrop-neg", "parent_activity_id":[ - "no parent" + "CMIP" ], "parent_experiment_id":[ - "no parent" + "piControl" ], "required_model_components":[ - "AGCM" + "AOGCM" ], - "start_year":"1979", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "amip-lfmip-rmLC":{ + "dcppC-ipv-NexTrop-pos":{ "activity_id":[ - "LS3MIP" + "DCPP" ], "additional_allowed_model_components":[ "AER", "CHEM", "BGC" ], - "description":"Prescribed land conditions 30yr running mean; AMIP SSTs", - "end_year":"2014", - "experiment":"prescribed land conditions (from running mean climatology) and AMIP SSTs", - "experiment_id":"amip-lfmip-rmLC", - "min_number_yrs_per_sim":"36", + "experiment":"idealized positive northern extratropical IPV anomaly pattern", + "experiment_id":"dcppC-ipv-NexTrop-pos", "parent_activity_id":[ - "no parent" + "CMIP" ], "parent_experiment_id":[ - "no parent" + "piControl" ], "required_model_components":[ - "AGCM" + "AOGCM" ], - "start_year":"1979", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "amip-lwoff":{ + "dcppC-ipv-neg":{ "activity_id":[ - "CFMIP" + "DCPP" ], "additional_allowed_model_components":[ "AER", - "CHEM" + "CHEM", + "BGC" ], - "description":"As amip experiment, but with cloud-radiative effects switched off in the LW radiation code", - "end_year":"2014", - "experiment":"AMIP experiment with longwave cloud-radiative effects off", - "experiment_id":"amip-lwoff", - "min_number_yrs_per_sim":"36", + "experiment":"idealized negative IPV anomaly pattern", + "experiment_id":"dcppC-ipv-neg", "parent_activity_id":[ - "no parent" + "CMIP" ], "parent_experiment_id":[ - "no parent" + "piControl" ], "required_model_components":[ - "AGCM" + "AOGCM" ], - "start_year":"1979", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "amip-m4K":{ + "dcppC-ipv-pos":{ "activity_id":[ - "CFMIP" + "DCPP" ], "additional_allowed_model_components":[ "AER", - "CHEM" + "CHEM", + "BGC" ], - "description":"As amip experiment but SSTs are subject to a uniform cooling of 4K", - "end_year":"2014", - "experiment":"AMIP with uniform 4K SST decrease", - "experiment_id":"amip-m4K", - "min_number_yrs_per_sim":"36", + "experiment":"idealized positive IPV anomaly pattern", + "experiment_id":"dcppC-ipv-pos", "parent_activity_id":[ - "no parent" + "CMIP" ], "parent_experiment_id":[ - "no parent" + "piControl" ], "required_model_components":[ - "AGCM" + "AOGCM" ], - "start_year":"1979", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "amip-p4K":{ + "dcppC-pac-control":{ "activity_id":[ - "CFMIP" + "DCPP" ], "additional_allowed_model_components":[ "AER", - "CHEM" + "CHEM", + "BGC" ], - "description":"As CMIP5/CFMIP-2 amip4K experiment. AMIP experiment where SSTs are subject to a uniform warming of 4K", - "end_year":"2014", - "experiment":"AMIP with uniform 4K SST increase", - "experiment_id":"amip-p4K", - "min_number_yrs_per_sim":"36", + "experiment":"idealized Pacific control", + "experiment_id":"dcppC-pac-control", "parent_activity_id":[ - "no parent" + "CMIP" ], "parent_experiment_id":[ - "no parent" + "piControl" ], "required_model_components":[ - "AGCM" + "AOGCM" ], - "start_year":"1979", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "amip-p4K-lwoff":{ + "dcppC-pac-pacemaker":{ "activity_id":[ - "CFMIP" + "DCPP" ], "additional_allowed_model_components":[ "AER", - "CHEM" + "CHEM", + "BGC" ], - "description":"As amip-p4K experiment, but with cloud-radiative effects switched off in the LW radiation code", - "end_year":"2014", - "experiment":"AMIP experiment with uniform 4K SST increase and with longwave cloud radiative effects off", - "experiment_id":"amip-p4K-lwoff", - "min_number_yrs_per_sim":"36", + "experiment":"pacemaker Pacific experiment", + "experiment_id":"dcppC-pac-pacemaker", "parent_activity_id":[ - "no parent" + "CMIP" ], "parent_experiment_id":[ - "no parent" + "historical" ], "required_model_components":[ - "AGCM" + "AOGCM" ], - "start_year":"1979", "sub_experiment_id":[ - "none" - ], - "tier":"2" + "s1910", + "s1920", + "s1950" + ] }, - "amip-piForcing":{ + "deforest-globe":{ "activity_id":[ - "CFMIP" + "LUMIP" ], "additional_allowed_model_components":[ "AER", - "CHEM" + "CHEM", + "BGC" ], - "description":"Identical to standard AMIP experiment but from 1870-present with constant pre-industrial forcing levels (anthropogenic and natural)", - "end_year":"2014", - "experiment":"AMIP SSTs with pre-industrial anthropogenic and natural forcing", - "experiment_id":"amip-piForcing", - "min_number_yrs_per_sim":"145", + "experiment":"idealized transient global deforestation", + "experiment_id":"deforest-globe", "parent_activity_id":[ - "no parent" + "CMIP" ], "parent_experiment_id":[ - "no parent" + "piControl" ], "required_model_components":[ - "AGCM" + "AOGCM" ], - "start_year":"1870", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "aqua-4xCO2":{ + "esm-hist":{ "activity_id":[ - "CFMIP" + "CMIP" ], "additional_allowed_model_components":[ "AER", "CHEM" ], - "description":"Extended version of CMIP5/CFMIP-2 aqua4xCO2 experiment. Aquaplanet experiment where SSTs are held at control values and the CO2 seen by the radiation scheme is quadrupled", - "end_year":"", - "experiment":"aquaplanet with control SST and 4xCO2", - "experiment_id":"aqua-4xCO2", - "min_number_yrs_per_sim":"10", + "experiment":"all-forcing simulation of the recent past with atmospheric CO2 concentration calculated", + "experiment_id":"esm-hist", "parent_activity_id":[ - "no parent" + "CMIP" ], "parent_experiment_id":[ - "no parent" + "esm-piControl" ], "required_model_components":[ - "AGCM" + "AOGCM", + "BGC" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "aqua-control":{ + "esm-hist-ext":{ "activity_id":[ - "CFMIP" + "CMIP" ], "additional_allowed_model_components":[ "AER", "CHEM" ], - "description":"Extended version of CMIP5/CFMIP-2 aquaControl experiment. 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Aquaplanet experiment where SSTs are subject to a uniform warming of 4K", - "end_year":"", - "experiment":"aquaplanet with uniform 4K SST increase", - "experiment_id":"aqua-p4K", - "min_number_yrs_per_sim":"10", + "experiment":"pulse removal of 100 Gt carbon from pre-industrial atmosphere", + "experiment_id":"esm-pi-cdr-pulse", "parent_activity_id":[ - "no parent" + "CMIP" ], "parent_experiment_id":[ - "no parent" + "esm-piControl" ], "required_model_components":[ - "AGCM" + "AOGCM", + "BGC" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "aqua-p4K-lwoff":{ + "esm-piControl":{ "activity_id":[ - "CFMIP" + "CMIP" ], "additional_allowed_model_components":[ "AER", "CHEM" ], - "description":"As aqua-p4K experiment, but with cloud-radiative effects switched off in the LW radiation code", - "end_year":"", - "experiment":"aquaplanet with uniform 4K SST increase and with longwave cloud radiative effects off", - "experiment_id":"aqua-p4K-lwoff", - "min_number_yrs_per_sim":"10", + "experiment":"pre-industrial control simulation with CO2 concentration calculated", + "experiment_id":"esm-piControl", "parent_activity_id":[ - "no parent" + "CMIP" ], "parent_experiment_id":[ - "no parent" + "esm-piControl-spinup" ], "required_model_components":[ - "AGCM" + "AOGCM", + "BGC" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "control-1950":{ + "esm-piControl-spinup":{ "activity_id":[ - "HighResMIP" + "CMIP" ], "additional_allowed_model_components":[ - "AER" + "AER", + "CHEM" ], - "description":"Coupled integrations with constant 1950\"s forcing", - "end_year":"", - "experiment":"coupled control with fixed 1950's forcing (HighResMIP equivalent of pre-industrial control)", - "experiment_id":"control-1950", - "min_number_yrs_per_sim":"100", + "experiment":"pre-industrial control simulation with CO2 concentration calculated (spin-up)", + "experiment_id":"esm-piControl-spinup", "parent_activity_id":[ - "HighResMIP" + "no parent" ], "parent_experiment_id":[ - "spinup-1950" + "no parent" ], "required_model_components":[ - "AOGCM" + "AOGCM", + "BGC" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "control-slab":{ + "esm-ssp534-over":{ "activity_id":[ - "VolMIP" + "CDRMIP" ], "additional_allowed_model_components":[ "AER", - "CHEM", - "BGC" + "CHEM" ], - "description":"slab control run for volc-pinatubo-slab", - "end_year":"", - "experiment":"control with slab ocean", - "experiment_id":"control-slab", - "min_number_yrs_per_sim":"30", + "experiment":"emission-driven SSP5-3.4-OS scenario", + "experiment_id":"esm-ssp534-over", "parent_activity_id":[ - "no parent" + "C4MIP" ], "parent_experiment_id":[ - "no parent" + "esm-ssp585" ], "required_model_components":[ - "AGCM", - "SLAB" + "AOGCM", + "BGC" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"3" + ] }, - "dcppA-assim":{ + "esm-ssp585":{ "activity_id":[ - "DCPP" + "C4MIP" ], "additional_allowed_model_components":[ "AER", - "CHEM", - "BGC" + "CHEM" ], - "description":"A2.3 Assimilation runs used to generate initial conditions for hindcasts", - "end_year":"2016", - "experiment":"Assimilation run paralleling the historical simulation, which may be used to generate hindcast initial conditions", - "experiment_id":"dcppA-assim", - "min_number_yrs_per_sim":"56", + "experiment":"emission-driven RCP8.5 based on SSP5", + "experiment_id":"esm-ssp585", "parent_activity_id":[ - "no parent" + "CMIP" ], "parent_experiment_id":[ - "no parent" + "esm-hist" ], "required_model_components":[ - "AOGCM" + "AOGCM", + "BGC" ], - "start_year":"before 1961", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "dcppA-hindcast":{ + "esm-ssp585-ocn-alk":{ "activity_id":[ - "DCPP" + "CDRMIP" ], "additional_allowed_model_components":[ "AER", - "CHEM", - "BGC" + "CHEM" ], - "description":"A1 (and A2.1, A3.1, and A3.2) Decadal hindcasts begun near the end of each year from 1960 to 2016, or every other year at minimum. First full hindcast year follows start year (e.g., for s1960, first full hindcast year is 1961)", - "end_year":"5 - 10 years after start year", - "experiment":"hindcast initialized based on observations and using historical forcing", - "experiment_id":"dcppA-hindcast", - "min_number_yrs_per_sim":"5", + "experiment":"emission-driven SSP5-8.5 scenario but with ocean alkalinization from year 2020 onward", + "experiment_id":"esm-ssp585-ocn-alk", "parent_activity_id":[ - "no parent", - "DCPP" + "C4MIP" ], "parent_experiment_id":[ - "no parent", - "dcppA-assim" + "esm-ssp585" ], "required_model_components":[ - "AOGCM" - ], - "start_year":"a year in the range 1960-2016", - "sub_experiment_id":[ - "s1960", - "s1961", - "s1962", - "s1963", - "s1964", - "s1965", - "s1966", - "s1967", - "s1968", - "s1969", - "s1970", - "s1971", - "s1972", - "s1973", - "s1974", - "s1975", - "s1976", - "s1977", - "s1978", - "s1979", - "s1980", - "s1981", - "s1982", - "s1983", - "s1984", - "s1985", - "s1986", - "s1987", - "s1988", - "s1989", - "s1990", - "s1991", - "s1992", - "s1993", - "s1994", - "s1995", - "s1996", - "s1997", - "s1998", - "s1999", - "s2000", - "s2001", - "s2002", - "s2003", - "s2004", - "s2005", - "s2006", - "s2007", - "s2008", - "s2009", - "s2010", - "s2011", - "s2012", - "s2013", - "s2014", - "s2015", - "s2016" + "AOGCM", + "BGC" ], - "tier":"1" + "sub_experiment_id":[ + "none" + ] }, - "dcppA-hindcast-niff":{ + "esm-ssp585-ocn-alk-stop":{ "activity_id":[ - "DCPP" + "CDRMIP" ], "additional_allowed_model_components":[ "AER", - "CHEM", - "BGC" + "CHEM" ], - "description":"A4.1 Decadal hindcasts begun near the end of each year from 1960 to 2016, or every other year at minimum, but with no information from the future. First full hindcast year follows start year (e.g., for s1960, first full hindcast year is 1961)", - "end_year":"5 - 10 years after start year", - "experiment":"hindcast initialized based on observations but without using knowledge of subsequent historical forcing", - "experiment_id":"dcppA-hindcast-niff", - "min_number_yrs_per_sim":"5", + "experiment":"emission-driven SSP5-8.5 scenario with alkalinization terminated in year 2070", + "experiment_id":"esm-ssp585-ocn-alk-stop", "parent_activity_id":[ - "no parent", - "DCPP" + "CDRMIP" ], "parent_experiment_id":[ - "no parent", - "dcppA-assim" + "esm-ssp585-ocn-alk" ], "required_model_components":[ - "AOGCM" + "AOGCM", + "BGC" ], - "start_year":"a year in the range 1960-2016", "sub_experiment_id":[ - "s1960", - "s1961", - "s1962", - "s1963", - "s1964", - "s1965", - "s1966", - "s1967", - "s1968", - "s1969", - "s1970", - "s1971", - "s1972", - "s1973", - "s1974", - "s1975", - "s1976", - "s1977", - "s1978", - "s1979", - "s1980", - "s1981", - "s1982", - "s1983", - "s1984", - "s1985", - "s1986", - "s1987", - "s1988", - "s1989", - "s1990", - "s1991", - "s1992", - "s1993", - "s1994", - "s1995", - "s1996", - "s1997", - "s1998", - "s1999", - "s2000", - "s2001", - "s2002", - "s2003", - "s2004", - "s2005", - "s2006", - "s2007", - "s2008", - "s2009", - "s2010", - "s2011", - "s2012", - "s2013", - "s2014", - "s2015", - "s2016" - ], - "tier":"4" + "none" + ] }, - "dcppA-historical-niff":{ + "esm-ssp585-ssp126Lu":{ "activity_id":[ - "DCPP" + "LUMIP" ], "additional_allowed_model_components":[ "AER", - "CHEM", - "BGC" + "CHEM" ], - "description":"A4.2 Hindcasts initialized from historical climate simulations as in DCPP-A2.2, but with no information from the future. First full hindcast year follows start year (e.g., for s1960, first full hindcast year is 1961)", - "end_year":"5 - 10 years after start year", - "experiment":"hindcast initialized from historical climate simulation but without using knowledge of subsequent historical forcing", - "experiment_id":"dcppA-historical-niff", - "min_number_yrs_per_sim":"5", + "experiment":"emissions-driven SSP5-8.5 with SSP1-2.6 land use", + "experiment_id":"esm-ssp585-ssp126Lu", "parent_activity_id":[ "CMIP" ], "parent_experiment_id":[ - "historical" + "esm-hist" ], "required_model_components":[ - "AOGCM" + "AOGCM", + "BGC" ], - "start_year":"A year in the range 1960-2016", "sub_experiment_id":[ - "s1960", - "s1961", - "s1962", - "s1963", - "s1964", - "s1965", - "s1966", - "s1967", - "s1968", - "s1969", - "s1970", - "s1971", - "s1972", - "s1973", - "s1974", - "s1975", - "s1976", - "s1977", - "s1978", - "s1979", - "s1980", - "s1981", - "s1982", - "s1983", - "s1984", - "s1985", - "s1986", - "s1987", - "s1988", - "s1989", - "s1990", - "s1991", - "s1992", - "s1993", - "s1994", - "s1995", - "s1996", - "s1997", - "s1998", - "s1999", - "s2000", - "s2001", - "s2002", - "s2003", - "s2004", - "s2005", - "s2006", - "s2007", - "s2008", - "s2009", - "s2010", - "s2011", - "s2012", - "s2013", - "s2014", - "s2015", - "s2016" - ], - "tier":"4" + "none" + ] }, - "dcppB-forecast":{ + "esm-ssp585-ssp126Lu-ext":{ "activity_id":[ - "DCPP" + "CDRMIP" ], "additional_allowed_model_components":[ "AER", - "CHEM", - "BGC" + "CHEM" ], - "description":"B1 (and B2.1, B2.2) Ongoing decadal forecasts. First full forecast year follows start year (e.g., for s2017, first full forecast year is 2018)", - "end_year":"5 years after start year", - "experiment":"forecast initialized from observations with forcing from ssp245", - "experiment_id":"dcppB-forecast", - "min_number_yrs_per_sim":"5", + "experiment":"extension of the LUMIP emissions-driven simulation following SSP5-8.5 with SSP1-2.6 land use", + "experiment_id":"esm-ssp585-ssp126Lu-ext", "parent_activity_id":[ - "no parent", - "DCPP" + "LUMIP" ], "parent_experiment_id":[ - "no parent", - "dcppA-assim" + "esm-ssp585-ssp126Lu" ], "required_model_components":[ - "AOGCM" + "AOGCM", + "BGC" ], - "start_year":"a year in the range 2017-2029", "sub_experiment_id":[ - "s2017", - "s2018", - "s2019", - "s2020", - "s2021", - "s2022", - "s2023", - "s2024", - "s2025", - "s2026", - "s2027", - "s2028", - "s2029" - ], - "tier":"1" + "none" + ] }, - "dcppC-amv-ExTrop-neg":{ + "esm-ssp585ext":{ "activity_id":[ - "DCPP" + "CDRMIP" ], "additional_allowed_model_components":[ "AER", - 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"experiment_id":"dcppC-amv-ExTrop-pos", - "min_number_yrs_per_sim":"10", + "experiment":"instantaneous 100 Gt C addition to an industrial era atmosphere", + "experiment_id":"esm-yr2010CO2-CO2pulse", "parent_activity_id":[ - "CMIP" + "CDRMIP" ], "parent_experiment_id":[ - "piControl" + "esm-yr2010CO2-control" ], "required_model_components":[ - "AOGCM" + "AOGCM", + "BGC" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "dcppC-amv-Trop-neg":{ + "esm-yr2010CO2-cdr-pulse":{ "activity_id":[ - "DCPP" + "CDRMIP" ], "additional_allowed_model_components":[ "AER", - "CHEM", - "BGC" + "CHEM" ], - "description":"C1.8 Mechanisms and predictability of the hiatus and of similar long timescale variations of both signs", - "end_year":"", - "experiment":"Idealized climate impact of negative tropical AMV anomaly pattern", - "experiment_id":"dcppC-amv-Trop-neg", - "min_number_yrs_per_sim":"10", + "experiment":"instantaneous 100 Gt C removal from industrial era atmosphere", + "experiment_id":"esm-yr2010CO2-cdr-pulse", "parent_activity_id":[ - "CMIP" + "CDRMIP" ], "parent_experiment_id":[ - "piControl" + "esm-yr2010CO2-control" ], "required_model_components":[ - "AOGCM" + "AOGCM", + "BGC" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "dcppC-amv-Trop-pos":{ + "esm-yr2010CO2-control":{ "activity_id":[ - "DCPP" + "CDRMIP" ], "additional_allowed_model_components":[ "AER", - "CHEM", - "BGC" + "CHEM" ], - "description":"C1.8 Mechanisms and predictability of the hiatus and of similar long timescale variations of both signs", - "end_year":"", - "experiment":"idealized positive tropical AMV anomaly pattern", - "experiment_id":"dcppC-amv-Trop-pos", - "min_number_yrs_per_sim":"10", + "experiment":"historical emissions followed by fixed 2010 emissions (both model-diagnosed)", + "experiment_id":"esm-yr2010CO2-control", "parent_activity_id":[ - "CMIP" + "CDRMIP" ], "parent_experiment_id":[ - "piControl" + "esm-piControl" ], "required_model_components":[ - "AOGCM" + "AOGCM", + "BGC" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "dcppC-amv-neg":{ + "esm-yr2010CO2-noemit":{ "activity_id":[ - "DCPP" + "CDRMIP" ], "additional_allowed_model_components":[ "AER", - "CHEM", - "BGC" + "CHEM" ], - "description":"C1.3 Mechanisms and predictability of the hiatus and of similar long timescale variations of both signs", - "end_year":"", - "experiment":"Idealized climate impact of negative AMV anomaly pattern", - "experiment_id":"dcppC-amv-neg", - "min_number_yrs_per_sim":"10", + "experiment":"branches from esm-yr2010CO2-control with zero emissions", + "experiment_id":"esm-yr2010CO2-noemit", "parent_activity_id":[ - "CMIP" + "CDRMIP" ], "parent_experiment_id":[ - "piControl" + "esm-yr2010CO2-control" ], "required_model_components":[ - "AOGCM" + "AOGCM", + "BGC" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "dcppC-amv-pos":{ + "faf-all":{ "activity_id":[ - "DCPP" + "FAFMIP" ], "additional_allowed_model_components":[ "AER", "CHEM", "BGC" - ], - "description":"C1.2 Mechanisms and predictability of the hiatus and of similar long timescale variations of both signs", - "end_year":"", - "experiment":"Idealized climate impact of positive AMV anomaly pattern", - "experiment_id":"dcppC-amv-pos", - "min_number_yrs_per_sim":"10", + ], + "experiment":"control plus perturbative surface fluxes of momentum, heat and water into ocean", + "experiment_id":"faf-all", "parent_activity_id":[ "CMIP" ], @@ -2976,26 +4683,21 @@ "required_model_components":[ "AOGCM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "dcppC-atl-control":{ + "faf-heat":{ "activity_id":[ - "DCPP" + "FAFMIP" ], "additional_allowed_model_components":[ "AER", "CHEM", "BGC" ], - "description":"C1.1 Mechanisms and predictability of the hiatus and of similar long timescale variations of both signs", - "end_year":"", - "experiment":"Idealized Atlantic control", - "experiment_id":"dcppC-atl-control", - "min_number_yrs_per_sim":"10", + "experiment":"control plus perturbative surface flux of heat into ocean", + "experiment_id":"faf-heat", "parent_activity_id":[ "CMIP" ], @@ -3005,424 +4707,314 @@ "required_model_components":[ "AOGCM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "dcppC-atl-pacemaker":{ + "faf-passiveheat":{ "activity_id":[ - "DCPP" + "FAFMIP" ], "additional_allowed_model_components":[ "AER", "CHEM", "BGC" ], - "description":"C1.11 Mechanisms and predictability of the hiatus and of similar long timescale variations of both signs", - "end_year":"2014", - "experiment":"pacemaker Atlantic experiment", - "experiment_id":"dcppC-atl-pacemaker", - "min_number_yrs_per_sim":"65", + "experiment":"control plus surface flux of passive heat tracer into ocean", + "experiment_id":"faf-passiveheat", "parent_activity_id":[ "CMIP" ], "parent_experiment_id":[ - "historical" + "piControl" ], "required_model_components":[ "AOGCM" ], - "start_year":"1910 or 1950", "sub_experiment_id":[ - "s1910", - "s1950" - ], - "tier":"3" + "none" + ] }, - "dcppC-atl-spg":{ + "faf-stress":{ "activity_id":[ - "DCPP" + "FAFMIP" ], "additional_allowed_model_components":[ "AER", "CHEM", "BGC" ], - "description":"C2.1 (and C2.2) Mechanisms and predictability of the hiatus and of similar long timescale variations of both signs. First full hindcast year follows start year (e.g., for s1992, first full hindcast year is 1993)", - "end_year":"5 - 10 years after start year", - "experiment":"predictability of 1990s warming of Atlantic sub-polar gyre", - "experiment_id":"dcppC-atl-spg", - "min_number_yrs_per_sim":"5", + "experiment":"control plus perturbative surface flux of momentum into ocean", + "experiment_id":"faf-stress", "parent_activity_id":[ - "no parent" + "CMIP" ], "parent_experiment_id":[ - "no parent" + "piControl" ], "required_model_components":[ "AOGCM" ], - "start_year":"A year in the range 1992-1999", "sub_experiment_id":[ - "s1992", - "s1993", - "s1994", - "s1995", - "s1996", - "s1997", - "s1998", - "s1999" - ], - "tier":"3" + "none" + ] }, - "dcppC-forecast-addAgung":{ + "faf-water":{ "activity_id":[ - "DCPP" + "FAFMIP" ], "additional_allowed_model_components":[ "AER", "CHEM", "BGC" ], - "description":"C3.4 Effects of volcanoes on decadal prediction and predictability of forced and internal variability components. First full hindcast year is 2015", - "end_year":"5 - 10 years after start year", - "experiment":"2015 forecast with added Agung forcing", - "experiment_id":"dcppC-forecast-addAgung", - "min_number_yrs_per_sim":"5", + "experiment":"control plus perturbative surface flux of water into ocean", + "experiment_id":"faf-water", "parent_activity_id":[ - "no parent", - "DCPP" + "CMIP" ], "parent_experiment_id":[ - "no parent", - "dcppA-assim" + "piControl" ], "required_model_components":[ "AOGCM" ], - "start_year":"2014", "sub_experiment_id":[ - "s2014" - ], - "tier":"3" + "none" + ] }, - "dcppC-forecast-addElChichon":{ + "futSST-pdSIC":{ "activity_id":[ - "DCPP" + "PAMIP" ], "additional_allowed_model_components":[ "AER", "CHEM", "BGC" ], - "description":"C3.5 Effects of volcanoes on decadal prediction and predictability of forced and internal variability components. First full hindcast year is 2015", - "end_year":"5 - 10 years after start year", - "experiment":"2015 forecast with added El Chichon forcing", - "experiment_id":"dcppC-forecast-addElChichon", - "min_number_yrs_per_sim":"5", + "experiment":"Atmosphere time slice with future SST and present day SIC", + "experiment_id":"futSST-pdSIC", "parent_activity_id":[ - "no parent", - "DCPP" + "CMIP" ], "parent_experiment_id":[ - "no parent", - "dcppA-assim" + "amip" ], "required_model_components":[ - "AOGCM" + "AGCM" ], - "start_year":"2014", "sub_experiment_id":[ - "s2014" - ], - "tier":"3" + "none" + ] }, - "dcppC-forecast-addPinatubo":{ + "futureSST-4xCO2-solar":{ "activity_id":[ - "DCPP", - "VolMIP" + "GeoMIP" ], "additional_allowed_model_components":[ "AER", - "CHEM", - "BGC" + "CHEM" ], - "description":"C3.6 Effects of volcanoes on decadal prediction and predictability of forced and internal variability components. First full hindcast year is 2015", - "end_year":"5 - 10 years after start year", - "experiment":"2015 forecast with added Pinatubo forcing", - "experiment_id":"dcppC-forecast-addPinatubo", - "min_number_yrs_per_sim":"5", + "experiment":"year 100 SSTs from abrupt-4xCO2 with quadrupled CO2 and solar reduction", + "experiment_id":"futureSST-4xCO2-solar", "parent_activity_id":[ - "no parent", - "DCPP" + "GeoMIP" ], "parent_experiment_id":[ - "no parent", - "dcppA-assim" + "G1" ], "required_model_components":[ - "AOGCM" + "AGCM" ], - "start_year":"2014", "sub_experiment_id":[ - "s2014" - ], - "tier":"1" + "none" + ] }, - "dcppC-hindcast-noAgung":{ + "highres-future":{ "activity_id":[ - "DCPP" + "HighResMIP" ], "additional_allowed_model_components":[ - "AER", - "CHEM", - "BGC" + "AER" ], - "description":"C3.3 Effects of volcanoes on decadal prediction and predictability of forced and internal variability components. First full hindcast year is 1962", - "end_year":"5 - 10 years after start year", - "experiment":"hindcast but with only background volcanic forcing to be the same as that used in the 2015 forecast", - "experiment_id":"dcppC-hindcast-noAgung", - "min_number_yrs_per_sim":"5", + "experiment":"coupled future 2015-2050 using a scenario as close to CMIP5 RCP8.5 as possible within CMIP6", + "experiment_id":"highres-future", "parent_activity_id":[ - "no parent", - "DCPP" + "HighResMIP" ], "parent_experiment_id":[ - "no parent", - "dcppA-assim" + "hist-1950" ], "required_model_components":[ "AOGCM" ], - "start_year":"1962", "sub_experiment_id":[ - "s1962" - ], - "tier":"2" + "none" + ] }, - "dcppC-hindcast-noElChichon":{ + "highresSST-4xCO2":{ "activity_id":[ - "DCPP" + "HighResMIP" ], "additional_allowed_model_components":[ - "AER", - "CHEM", - "BGC" + "AER" ], - "description":"C3.2 Effects of volcanoes on decadal prediction and predictability of forced and internal variability components. First full hindcast year is 1982", - "end_year":"5 - 10 years after start year", - "experiment":"hindcast but with only background volcanic forcing to be the same as that used in the 2015 forecast", - "experiment_id":"dcppC-hindcast-noElChichon", - "min_number_yrs_per_sim":"5", + "experiment":"highresSST-present SST with 4xCO2 concentrations", + "experiment_id":"highresSST-4xCO2", "parent_activity_id":[ - "no parent", - "DCPP" + "HighResMIP" ], "parent_experiment_id":[ - "no parent", - "dcppA-assim" + "highresSST-present" ], "required_model_components":[ - "AOGCM" + "AGCM" ], - "start_year":"1981", "sub_experiment_id":[ - "s1981" - ], - "tier":"2" + "none" + ] }, - "dcppC-hindcast-noPinatubo":{ + "highresSST-LAI":{ "activity_id":[ - "DCPP" + "HighResMIP" ], "additional_allowed_model_components":[ - "AER", - "CHEM", - "BGC" + "AER" ], - "description":"C3.1 Effects of volcanoes on decadal prediction and predictability of forced and internal variability components. First full hindcast year is 1991", - "end_year":"5 - 10 years after start year", - "experiment":"hindcast but with only background volcanic forcing to be the same as that used in the 2015 forecast", - "experiment_id":"dcppC-hindcast-noPinatubo", - "min_number_yrs_per_sim":"5", + "experiment":"common LAI dataset within the highresSST-present experiment", + "experiment_id":"highresSST-LAI", "parent_activity_id":[ - "no parent", - "DCPP" + "HighResMIP" ], "parent_experiment_id":[ - "no parent", - "dcppA-assim" + "highresSST-present" ], "required_model_components":[ - "AOGCM" + "AGCM" ], - "start_year":"1990", "sub_experiment_id":[ - "s1990" - ], - "tier":"1" + "none" + ] }, - "dcppC-ipv-NexTrop-neg":{ + "highresSST-future":{ "activity_id":[ - "DCPP" + "HighResMIP" ], "additional_allowed_model_components":[ - "AER", - "CHEM", - "BGC" + "AER" ], - "description":"C1.9 and predictability of the hiatus and of similar long timescale variations of both signs", - "end_year":"", - "experiment":"idealized negative northern extratropical IPV anomaly pattern", - "experiment_id":"dcppC-ipv-NexTrop-neg", - "min_number_yrs_per_sim":"10", + "experiment":"forced atmosphere experiment for 2015-2050 using SST/sea-ice derived from CMIP5 RCP8.5 simulations and a scenario as close to RCP8.5 as possible within CMIP6", + "experiment_id":"highresSST-future", "parent_activity_id":[ - "CMIP" + "HighResMIP" ], "parent_experiment_id":[ - "piControl" + "highresSST-present" ], "required_model_components":[ - "AOGCM" + "AGCM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "dcppC-ipv-NexTrop-pos":{ + "highresSST-p4K":{ "activity_id":[ - "DCPP" + "HighResMIP" ], "additional_allowed_model_components":[ - "AER", - "CHEM", - "BGC" + "AER" ], - "description":"C1.9 Mechanisms and predictability of the hiatus and of similar long timescale variations of both signs", - "end_year":"", - "experiment":"idealized positive northern extratropical IPV anomaly pattern", - "experiment_id":"dcppC-ipv-NexTrop-pos", - "min_number_yrs_per_sim":"10", + "experiment":"uniform 4K warming of highresSST-present SST", + "experiment_id":"highresSST-p4K", "parent_activity_id":[ - "CMIP" + "HighResMIP" ], "parent_experiment_id":[ - "piControl" + "highresSST-present" ], "required_model_components":[ - "AOGCM" + "AGCM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "dcppC-ipv-neg":{ + "highresSST-present":{ "activity_id":[ - "DCPP" + "HighResMIP" ], "additional_allowed_model_components":[ - "AER", - "CHEM", - "BGC" + "AER" ], - "description":"C1.6 Mechanisms and predictability of the hiatus and of similar long timescale variations of both signs", - "end_year":"", - "experiment":"idealized negative IPV anomaly pattern", - "experiment_id":"dcppC-ipv-neg", - "min_number_yrs_per_sim":"10", + "experiment":"forced atmosphere experiment for 1950-2014", + "experiment_id":"highresSST-present", "parent_activity_id":[ - "CMIP" + "no parent" ], "parent_experiment_id":[ - "piControl" + "no parent" ], "required_model_components":[ - "AOGCM" + "AGCM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "dcppC-ipv-pos":{ + "highresSST-smoothed":{ "activity_id":[ - "DCPP" + "HighResMIP" ], "additional_allowed_model_components":[ - "AER", - "CHEM", - "BGC" + "AER" ], - "description":"C1.5 Mechanisms and predictability of the hiatus and of similar long timescale variations of both signs", - "end_year":"", - "experiment":"idealized positive IPV anomaly pattern", - "experiment_id":"dcppC-ipv-pos", - "min_number_yrs_per_sim":"10", + "experiment":"smoothed SST version of highresSST-present", + "experiment_id":"highresSST-smoothed", "parent_activity_id":[ - "CMIP" + "HighResMIP" ], "parent_experiment_id":[ - "piControl" + "highresSST-present" ], "required_model_components":[ - "AOGCM" + "AGCM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "dcppC-pac-control":{ + "hist-1950":{ "activity_id":[ - "DCPP" + "HighResMIP" ], "additional_allowed_model_components":[ - "AER", - "CHEM", - "BGC" + "AER" ], - "description":"C1.4 Mechanisms and predictability of the hiatus and of similar long timescale variations of both signs", - "end_year":"", - "experiment":"idealized Pacific control", - "experiment_id":"dcppC-pac-control", - "min_number_yrs_per_sim":"10", + "experiment":"coupled historical 1950-2014", + "experiment_id":"hist-1950", "parent_activity_id":[ - "CMIP" + "HighResMIP" ], "parent_experiment_id":[ - "piControl" + "spinup-1950" ], "required_model_components":[ "AOGCM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "dcppC-pac-pacemaker":{ + "hist-1950HC":{ "activity_id":[ - "DCPP" + "AerChemMIP" ], "additional_allowed_model_components":[ - "AER", - "CHEM", "BGC" ], - "description":"C1.10 Mechanisms and predictability of the hiatus and of similar long timescale variations of both signs. First full hindcast year is 2015", - "end_year":"2014", - "experiment":"pacemaker Pacific experiment", - "experiment_id":"dcppC-pac-pacemaker", - "min_number_yrs_per_sim":"65", + "experiment":"historical forcing, but with1950s halocarbon concentrations; initialized in 1950", + "experiment_id":"hist-1950HC", "parent_activity_id":[ "CMIP" ], @@ -3430,29 +5022,25 @@ "historical" ], "required_model_components":[ - "AOGCM" + "AOGCM", + "AER", + "CHEM" ], - "start_year":"either 1910 or 1950", "sub_experiment_id":[ - "s1910", - "s1950" - ], - "tier":"3" + "none" + ] }, - "deforest-globe":{ + "hist-CO2":{ "activity_id":[ - "LUMIP" + "DAMIP" ], "additional_allowed_model_components":[ "AER", "CHEM", "BGC" ], - "description":"Idealized deforestation experiment, 20 million km2 forest removed linearly over a period of 50 years, with an additional 30 years with no specified change in forest cover; all other forcings held constant", - "end_year":"", - "experiment":"idealized transient global deforestation", - "experiment_id":"deforest-globe", - "min_number_yrs_per_sim":"81", + "experiment":"historical CO2-only run", + "experiment_id":"hist-CO2", "parent_activity_id":[ "CMIP" ], @@ -3462,200 +5050,141 @@ "required_model_components":[ "AOGCM" ], - "start_year":"1850", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "esm-hist":{ + "hist-GHG":{ "activity_id":[ - "CMIP" + "DAMIP" ], "additional_allowed_model_components":[ "AER", - "CHEM" + "CHEM", + "BGC" ], - "description":"CMIP6 historical (CO2 emission-driven)", - "end_year":"2014", - "experiment":"all-forcing simulation of the recent past with atmospheric CO2 concentration calculated", - "experiment_id":"esm-hist", - "min_number_yrs_per_sim":"165", + "experiment":"historical well-mixed GHG-only run", + "experiment_id":"hist-GHG", "parent_activity_id":[ "CMIP" ], "parent_experiment_id":[ - "esm-piControl" + "piControl" ], "required_model_components":[ - "AOGCM", - "BGC" + "AOGCM" ], - "start_year":"1850", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "esm-hist-ext":{ + "hist-aer":{ "activity_id":[ - "CMIP" + "DAMIP" ], "additional_allowed_model_components":[ "AER", - "CHEM" + "CHEM", + "BGC" ], - "description":"Extension beyond 2014 of the CMIP6 historical (CO2 emission-driven)", - "end_year":"", - "experiment":"post-2014 all-forcing simulation with atmospheric CO2 concentration calculated", - "experiment_id":"esm-hist-ext", - "min_number_yrs_per_sim":"1", + "experiment":"historical anthropogenic aerosols-only run", + "experiment_id":"hist-aer", "parent_activity_id":[ "CMIP" ], "parent_experiment_id":[ - "esm-hist" + "piControl" ], "required_model_components":[ - "AOGCM", - "BGC" + "AOGCM" ], - "start_year":"2015", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "esm-piControl":{ + "hist-all-aer2":{ "activity_id":[ - "CMIP" + "DAMIP" ], "additional_allowed_model_components":[ "AER", - "CHEM" + "CHEM", + "BGC" ], - "description":"DECK: control (emission-driven)", - "end_year":"", - "experiment":"pre-industrial control simulation with CO2 concentration calculated", - "experiment_id":"esm-piControl", - "min_number_yrs_per_sim":"500", + "experiment":"historical ALL-forcing run with alternate estimates of aerosol forcing", + "experiment_id":"hist-all-aer2", "parent_activity_id":[ "CMIP" ], "parent_experiment_id":[ - "esm-piControl-spinup" + "piControl" ], "required_model_components":[ - "AOGCM", - "BGC" + "AOGCM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "esm-piControl-spinup":{ + "hist-all-nat2":{ "activity_id":[ - "CMIP" + "DAMIP" ], "additional_allowed_model_components":[ "AER", - "CHEM" - ], - "description":"DECK: spin-up portion of the control (emission-driven)", - "end_year":"", - "experiment":"pre-industrial control simulation with CO2 concentration calculated (spin-up)", - "experiment_id":"esm-piControl-spinup", - "min_number_yrs_per_sim":"100", - "parent_activity_id":[ - "no parent" - ], - "parent_experiment_id":[ - "no parent" - ], - "required_model_components":[ - "AOGCM", + "CHEM", "BGC" ], - "start_year":"", - "sub_experiment_id":[ - "none" - ], - "tier":"2" - }, - "esm-ssp585":{ - "activity_id":[ - "C4MIP" - ], - "additional_allowed_model_components":[ - "AER", - "CHEM" - ], - "description":"Emissions-driven future scenario simulation", - "end_year":"2100", - "experiment":"emission-driven RCP8.5 based on SSP5", - "experiment_id":"esm-ssp585", - "min_number_yrs_per_sim":"85", + "experiment":"historical ALL-forcing run with alternate estimates of natural forcing", + "experiment_id":"hist-all-nat2", "parent_activity_id":[ "CMIP" ], "parent_experiment_id":[ - "esm-hist" + "piControl" ], "required_model_components":[ - "AOGCM", - "BGC" + "AOGCM" ], - "start_year":"2015", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "esm-ssp585-ssp126Lu":{ + "hist-bgc":{ "activity_id":[ - "LUMIP" + "C4MIP" ], "additional_allowed_model_components":[ "AER", "CHEM" ], - "description":"Additional land use policy sensitivity simulation for high radiative forcing scenario, keep all forcings the same as in C4MIP esmssp5-8.5 scenario except use SSP1-2.6 land use; emission driven", - "end_year":"2100", - "experiment":"emissions-driven SSP5-8.5 with SSP1-2.6 land use", - "experiment_id":"esm-ssp585-ssp126Lu", - "min_number_yrs_per_sim":"86", + "experiment":"biogeochemically-coupled version of the simulation of the recent past with CO2 concentration prescribed", + "experiment_id":"hist-bgc", "parent_activity_id":[ "CMIP" ], "parent_experiment_id":[ - "esm-hist" + "piControl" ], "required_model_components":[ "AOGCM", "BGC" ], - "start_year":"2015", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "faf-all":{ + "hist-nat":{ "activity_id":[ - "FAFMIP" + "DAMIP" ], "additional_allowed_model_components":[ "AER", "CHEM", "BGC" ], - "description":"1xCO2 experiment, parallel to piControl, forced over the ocean simultaneously by surface windstress (as in the wind experiment), net heat flux (as in the heat experiment) and net freshwater flux (as in the water experiment) anomalies obtained from the CMIP5 ensemble mean of 1pctCO2 experiments at the time of 2xCO2, using a passive tracer to prevent negative climate feedback on the heat flux applied", - "end_year":"", - "experiment":"control plus perturbative surface fluxes of momentum, heat and water into ocean", - "experiment_id":"faf-all", - "min_number_yrs_per_sim":"70", + "experiment":"historical natural-only run", + "experiment_id":"hist-nat", "parent_activity_id":[ "CMIP" ], @@ -3665,26 +5194,21 @@ "required_model_components":[ "AOGCM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "faf-heat":{ + "hist-noLu":{ "activity_id":[ - "FAFMIP" + "LUMIP" ], "additional_allowed_model_components":[ "AER", "CHEM", "BGC" ], - "description":"1xCO2 experiment, parallel to piControl, forced over the ocean by surface net heat flux anomalies obtained from the CMIP5 ensemble mean of 1pctCO2 experiments at the time of 2xCO2, using a passive tracer to prevent negative climate feedback on the heat flux applied", - "end_year":"", - "experiment":"control plus perturbative surface flux of heat into ocean", - "experiment_id":"faf-heat", - "min_number_yrs_per_sim":"70", + "experiment":"historical with no land-use change", + "experiment_id":"hist-noLu", "parent_activity_id":[ "CMIP" ], @@ -3694,26 +5218,20 @@ "required_model_components":[ "AOGCM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "faf-passiveheat":{ + "hist-piAer":{ "activity_id":[ - "FAFMIP" + "AerChemMIP" ], "additional_allowed_model_components":[ - "AER", "CHEM", "BGC" ], - "description":"1xCO2 experiment, parallel to piControl, with a flux of passive tracer added at the ocean surface at the same rate as the surface net heat flux anomaly applied in the FAFMIP heat experiment", - "end_year":"", - "experiment":"control plus surface flux of passive heat tracer into ocean", - "experiment_id":"faf-passiveheat", - "min_number_yrs_per_sim":"70", + "experiment":"historical forcing, but with pre-industrial aerosol emissions", + "experiment_id":"hist-piAer", "parent_activity_id":[ "CMIP" ], @@ -3721,28 +5239,23 @@ "piControl" ], "required_model_components":[ - "AOGCM" + "AOGCM", + "AER" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "faf-stress":{ + "hist-piNTCF":{ "activity_id":[ - "FAFMIP" + "AerChemMIP" ], "additional_allowed_model_components":[ - "AER", "CHEM", "BGC" ], - "description":"1xCO2 experiment, parallel to piControl, forced over the ocean by surface windstress anomalies obtained from the CMIP5 ensemble mean of 1pctCO2 experiments at the time of 2xCO2", - "end_year":"", - "experiment":"control plus perturbative surface flux of momentum into ocean", - "experiment_id":"faf-stress", - "min_number_yrs_per_sim":"70", + "experiment":"historical forcing, but with pre-industrial NTCF emissions", + "experiment_id":"hist-piNTCF", "parent_activity_id":[ "CMIP" ], @@ -3750,218 +5263,186 @@ "piControl" ], "required_model_components":[ - "AOGCM" + "AOGCM", + "AER" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "faf-water":{ + "hist-resAMO":{ "activity_id":[ - "FAFMIP" + "GMMIP" ], "additional_allowed_model_components":[ "AER", "CHEM", "BGC" ], - "description":"1xCO2 experiment, parallel to piControl, forced over the ocean by surface net freshwater flux anomalies obtained from the CMIP5 ensemble mean of 1pctCO2 experiments at the time of 2xCO2", - "end_year":"", - "experiment":"control plus perturbative surface flux of water into ocean", - "experiment_id":"faf-water", - "min_number_yrs_per_sim":"70", + "experiment":"initialized from \"historical\" run year 1870 and SSTs in the AMO domain (0deg-70degN, 70degW-0deg) restored to AMIP SSTs with historical forcings", + "experiment_id":"hist-resAMO", "parent_activity_id":[ "CMIP" ], "parent_experiment_id":[ - "piControl" + "historical" ], "required_model_components":[ "AOGCM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "futureSST-4xCO2-solar":{ + "hist-resIPO":{ "activity_id":[ - "GeoMIP" + "GMMIP" ], "additional_allowed_model_components":[ "AER", - "CHEM" + "CHEM", + "BGC" ], - "description":"Time slice at year 100 of G1ext to examine radiative forcing of abrupt4xCO2 and G1", - "end_year":"", - "experiment":"year 100 SSTs from abrupt4xCO2 with quadrupled CO2 and solar reduction", - "experiment_id":"futureSST-4xCO2-solar", - "min_number_yrs_per_sim":"10", + "experiment":"initialized from \"historical\" run year 1870 and SSTs in tropical lobe of the IPO domain (20degS-20degN, 175degE-75degW) restored to AMIP SSTs with historical forcings", + "experiment_id":"hist-resIPO", "parent_activity_id":[ - "GeoMIP" + "CMIP" ], "parent_experiment_id":[ - "G1" + "historical" ], "required_model_components":[ - "AGCM" + "AOGCM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "highres-future":{ + "hist-sol":{ "activity_id":[ - "HighResMIP" + "DAMIP" ], "additional_allowed_model_components":[ - "AER" + "AER", + "CHEM", + "BGC" ], - "description":"Coupled integrations with SSP5 forcing (nearest to CMIP5 RCP8.5 (as in highresSST-future)", - "end_year":"2050", - "experiment":"coupled future 2015-2050 using a scenario as close to CMIP5 RCP8.5 as possible within CMIP6", - "experiment_id":"highres-future", - "min_number_yrs_per_sim":"36", + "experiment":"historical solar-only run", + "experiment_id":"hist-sol", "parent_activity_id":[ - "HighResMIP" + "CMIP" ], "parent_experiment_id":[ - "hist-1950" + "piControl" ], "required_model_components":[ "AOGCM" ], - "start_year":"2015", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "highresSST-4co2":{ + "hist-spAer-aer":{ "activity_id":[ - "HighResMIP" + "RFMIP" ], "additional_allowed_model_components":[ - "AER" + "" ], - "description":"Similar to CFMIP amip-4xCO2, SSTs are held at highresSST-present values and the CO2 seen by the radiation scheme is quadrupled", - "end_year":"2014", - "experiment":"highresSST-present SST with 4xCO2 concentrations", - "experiment_id":"highresSST-4co2", - "min_number_yrs_per_sim":"36", + "experiment":"historical simulation with specified anthropogenic aerosols, no other forcings", + "experiment_id":"hist-spAer-aer", "parent_activity_id":[ - "HighResMIP" + "CMIP" ], "parent_experiment_id":[ - "highresSST-present" + "piControl" ], "required_model_components":[ - "AGCM" + "AOGCM" ], - "start_year":"1979", "sub_experiment_id":[ "none" - ], - "tier":"3" + ] }, - "highresSST-LAI":{ + "hist-spAer-all":{ "activity_id":[ - "HighResMIP" + "RFMIP" ], "additional_allowed_model_components":[ - "AER" + "" ], - "description":"Forced global atmosphere-land simulations as highresSST-present, but using an common LAI dataset across models", - "end_year":"2014", - "experiment":"common LAI dataset within the highresSST-present experiment", - "experiment_id":"highresSST-LAI", - "min_number_yrs_per_sim":"36", + "experiment":"historical simulation with specified anthropogenic aerosols", + "experiment_id":"hist-spAer-all", "parent_activity_id":[ - "HighResMIP" + "CMIP" ], "parent_experiment_id":[ - "highresSST-present" + "piControl" ], "required_model_components":[ - "AGCM" + "AOGCM" ], - "start_year":"1979", "sub_experiment_id":[ "none" - ], - "tier":"3" + ] }, - "highresSST-future":{ + "hist-stratO3":{ "activity_id":[ - "HighResMIP" + "DAMIP" ], "additional_allowed_model_components":[ - "AER" + "AER", + "BGC" ], - "description":"Extend highresSST-present to 2050 with agreed SSP5/RCP8.5 forcings (with option to extend further to 2100)", - "end_year":"2050", - "experiment":"forced atmosphere experiment for 2015-2050 using SST/sea-ice derived from CMIP5 RCP8.5 simulations and a scenario as close to RCP8.5 as possible within CMIP6", - "experiment_id":"highresSST-future", - "min_number_yrs_per_sim":"36", + "experiment":"historical stratospheric-ozone-only run", + "experiment_id":"hist-stratO3", "parent_activity_id":[ - "HighResMIP" + "CMIP" ], "parent_experiment_id":[ - "highresSST-present" + "piControl" ], "required_model_components":[ - "AGCM" + "AOGCM" ], - "start_year":"2015", "sub_experiment_id":[ "none" - ], - "tier":"3" + ] }, - "highresSST-p4K":{ + "hist-volc":{ "activity_id":[ - "HighResMIP" + "DAMIP" ], "additional_allowed_model_components":[ - "AER" + "AER", + "CHEM", + "BGC" ], - "description":"Similar to CFMIP amip-p4K, add a uniform warming of 4K to highresSST-present SSTs and run the experiment parallel to highresSST-present", - "end_year":"2014", - "experiment":"uniform 4K warming of highresSST-present SST", - "experiment_id":"highresSST-p4K", - "min_number_yrs_per_sim":"36", + "experiment":"historical volcanic-only run", + "experiment_id":"hist-volc", "parent_activity_id":[ - "HighResMIP" + "CMIP" ], "parent_experiment_id":[ - "highresSST-present" + "piControl" ], "required_model_components":[ - "AGCM" + "AOGCM" ], - "start_year":"1979", "sub_experiment_id":[ "none" - ], - "tier":"3" + ] }, - "highresSST-present":{ + "histSST":{ "activity_id":[ - "HighResMIP" + "AerChemMIP" ], "additional_allowed_model_components":[ - "AER" + "CHEM", + "BGC" ], - "description":"Forced global atmosphere-land simulations using daily 1/4 degree SST and sea-ice forcings, and aerosol optical properties (not emissions) to constrain model spread", - "end_year":"2014", - "experiment":"forced atmosphere experiment for 1950-2014", - "experiment_id":"highresSST-present", - "min_number_yrs_per_sim":"65", + "experiment":"historical prescribed SSTs and historical forcing", + "experiment_id":"histSST", "parent_activity_id":[ "no parent" ], @@ -3969,198 +5450,168 @@ "no parent" ], "required_model_components":[ - "AGCM" + "AGCM", + "AER" ], - "start_year":"1950", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "highresSST-smoothed":{ + "histSST-1950HC":{ "activity_id":[ - "HighResMIP" + "AerChemMIP" ], "additional_allowed_model_components":[ - "AER" + "BGC" ], - "description":"Forced global atmosphere-land simulations as highresSST-present, but using smoothed SST to investigate impact of SST variability", - "end_year":"2014", - "experiment":"smoothed SST version of highresSST-present", - "experiment_id":"highresSST-smoothed", - "min_number_yrs_per_sim":"36", + "experiment":"historical SSTs and historical forcing, but with1950 halocarbon concentrations", + "experiment_id":"histSST-1950HC", "parent_activity_id":[ - "HighResMIP" + "no parent" ], "parent_experiment_id":[ - "highresSST-present" + "no parent" ], "required_model_components":[ - "AGCM" + "AGCM", + "AER", + "CHEM" ], - "start_year":"1979", "sub_experiment_id":[ "none" - ], - "tier":"3" + ] }, - "hist-1950":{ + "histSST-piAer":{ "activity_id":[ - "HighResMIP" + "AerChemMIP" ], "additional_allowed_model_components":[ - "AER" + "CHEM", + "BGC" ], - "description":"Coupled integrationswith historic external forcings (as in highresSST-present)", - "end_year":"2014", - "experiment":"coupled historical 1950-2014", - "experiment_id":"hist-1950", - "min_number_yrs_per_sim":"65", + "experiment":"historical SSTs and historical forcing, but with pre-industrial aerosol emissions", + "experiment_id":"histSST-piAer", "parent_activity_id":[ - "HighResMIP" + "no parent" ], "parent_experiment_id":[ - "spinup-1950" + "no parent" ], "required_model_components":[ - "AOGCM" + "AGCM", + "AER" ], - "start_year":"1950", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "hist-1950HC":{ + "histSST-piCH4":{ "activity_id":[ "AerChemMIP" ], "additional_allowed_model_components":[ "BGC" ], - "description":"Historical WMGHG concentrations and NTCF emissions, 1950 halocarbon concentrations, start 1950", - "end_year":"2014", - "experiment":"historical forcing, but with1950s halocarbon concentrations; initialized in 1950", - "experiment_id":"hist-1950HC", - "min_number_yrs_per_sim":"65", + "experiment":"historical SSTs and historical forcing, but with pre-industrial methane concentrations", + "experiment_id":"histSST-piCH4", "parent_activity_id":[ - "CMIP" + "no parent" ], "parent_experiment_id":[ - "historical" + "no parent" ], "required_model_components":[ - "AOGCM", + "AGCM", "AER", "CHEM" ], - "start_year":"1950", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "hist-CO2":{ + "histSST-piN2O":{ "activity_id":[ - "DAMIP" + "AerChemMIP" ], "additional_allowed_model_components":[ - "AER", - "CHEM", "BGC" ], - "description":"Historical CO2-only run", - "end_year":"2020", - "experiment":"historical CO2-only run", - "experiment_id":"hist-CO2", - "min_number_yrs_per_sim":"171", + "experiment":"historical SSTs and historical forcings, but with pre-industrial N2O concentrations", + "experiment_id":"histSST-piN2O", "parent_activity_id":[ - "CMIP" + "no parent" ], "parent_experiment_id":[ - "piControl" + "no parent" ], "required_model_components":[ - "AOGCM" + "AGCM", + "AER", + "CHEM" ], - "start_year":"1850", "sub_experiment_id":[ "none" - ], - "tier":"3" + ] }, - "hist-GHG":{ + "histSST-piNTCF":{ "activity_id":[ - "DAMIP" + "AerChemMIP" ], "additional_allowed_model_components":[ - "AER", "CHEM", "BGC" ], - "description":"Historical well-mixed GHG-only run. Models with interactive chemistry schemes should either turn off the chemistry or use a preindustrial climatology of stratospheric and tropospheric ozone in their radiation schemes. This will ensure that ozone is fixed in all these simulations, and simulated responses in models with and without coupled chemistry are comparable", - "end_year":"2020", - "experiment":"historical well-mixed GHG-only run", - "experiment_id":"hist-GHG", - "min_number_yrs_per_sim":"171", + "experiment":"historical SSTs and historical forcing, but with pre-industrial NTCF emissions", + "experiment_id":"histSST-piNTCF", "parent_activity_id":[ - "CMIP" + "no parent" ], "parent_experiment_id":[ - "piControl" + "no parent" ], "required_model_components":[ - "AOGCM" + "AGCM", + "AER" ], - "start_year":"1850", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "hist-aer":{ + "histSST-piO3":{ "activity_id":[ - "DAMIP" + "AerChemMIP" ], "additional_allowed_model_components":[ - "AER", - "CHEM", "BGC" ], - "description":"Historical anthropogenic-Aerosols-only run", - "end_year":"2020", - "experiment":"historical anthropogenic aerosols-only run", - "experiment_id":"hist-aer", - "min_number_yrs_per_sim":"171", + "experiment":"historical SSTs and historical forcing, but with pre-industrial ozone precursor emissions", + "experiment_id":"histSST-piO3", "parent_activity_id":[ - "CMIP" + "no parent" ], "parent_experiment_id":[ - "piControl" + "no parent" ], "required_model_components":[ - "AOGCM" + "AGCM", + "AER", + "CHEM" ], - "start_year":"1850", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "hist-all-aer2":{ + "historical":{ "activity_id":[ - "DAMIP" + "CMIP" ], "additional_allowed_model_components":[ "AER", "CHEM", "BGC" ], - "description":"Historical ALL forcing run with alternate estimates of aerosol concentrations/emissions", - "end_year":"2020", - "experiment":"historical ALL-forcing run with alternate estimates of aerosol forcing", - "experiment_id":"hist-all-aer2", - "min_number_yrs_per_sim":"171", + "experiment":"all-forcing simulation of the recent past", + "experiment_id":"historical", "parent_activity_id":[ "CMIP" ], @@ -4170,447 +5621,354 @@ "required_model_components":[ "AOGCM" ], - "start_year":"1850", "sub_experiment_id":[ "none" - ], - "tier":"3" + ] }, - "hist-all-nat2":{ + "historical-ext":{ "activity_id":[ - "DAMIP" + "CMIP" ], "additional_allowed_model_components":[ "AER", "CHEM", "BGC" ], - "description":"Historical ALL forcing run with alternates estimate of solar and volcanic forcing", - "end_year":"2020", - "experiment":"historical ALL-forcing run with alternate estimates of natural forcing", - "experiment_id":"hist-all-nat2", - "min_number_yrs_per_sim":"171", + "experiment":"post-2014 all-forcing simulation", + "experiment_id":"historical-ext", "parent_activity_id":[ "CMIP" ], "parent_experiment_id":[ - "piControl" + "historical" ], "required_model_components":[ "AOGCM" ], - "start_year":"1850", "sub_experiment_id":[ "none" - ], - "tier":"3" + ] }, - "hist-bgc":{ + "historical-withism":{ "activity_id":[ - "C4MIP" + "ISMIP6" ], "additional_allowed_model_components":[ "AER", - "CHEM" + "CHEM", + "BGC" ], - "description":"Concentration-driven historical simulation, biogeochemically-coupled", - "end_year":"2014", - "experiment":"biogeochemically-coupled version of the simulation of the recent past with CO2 concentration prescribed", - "experiment_id":"hist-bgc", - "min_number_yrs_per_sim":"165", + "experiment":"historical with interactive ice sheet", + "experiment_id":"historical-withism", "parent_activity_id":[ - "CMIP" + "ISMIP6" ], "parent_experiment_id":[ - "piControl" + "piControl-withism" ], "required_model_components":[ "AOGCM", - "BGC" + "ISM" ], - "start_year":"1850", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "hist-nat":{ + "ism-1pctCO2to4x-self":{ "activity_id":[ - "DAMIP" + "ISMIP6" ], "additional_allowed_model_components":[ - "AER", - "CHEM", - "BGC" + "" ], - "description":"Historical natural-only run", - "end_year":"2020", - "experiment":"historical natural-only run", - "experiment_id":"hist-nat", - "min_number_yrs_per_sim":"171", + "experiment":"offline ice sheet model forced by ISM's own AOGCM 1pctCO2to4x output", + "experiment_id":"ism-1pctCO2to4x-self", "parent_activity_id":[ - "CMIP" + "ISMIP6" ], "parent_experiment_id":[ - "piControl" + "ism-piControl-self" ], "required_model_components":[ - "AOGCM" + "ISM" ], - "start_year":"1850", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "hist-noLu":{ + "ism-1pctCO2to4x-std":{ "activity_id":[ - "LUMIP" + "ISMIP6" ], "additional_allowed_model_components":[ - "AER", - "CHEM", - "BGC" + "" ], - "description":"Same as CMIP6 historical but with land cover held at 1850, no human activity; concentration driven", - "end_year":"2014", - "experiment":"historical with no land-use change", - "experiment_id":"hist-noLu", - "min_number_yrs_per_sim":"165", + "experiment":"offline ice sheet model forced by ISMIP6-specified AOGCM 1pctCO2to4x output", + "experiment_id":"ism-1pctCO2to4x-std", "parent_activity_id":[ - "CMIP" + "ISMIP6" ], "parent_experiment_id":[ - "piControl" + "ism-pdControl-std" ], "required_model_components":[ - "AOGCM" + "ISM" ], - "start_year":"1850", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "hist-piAer":{ + "ism-amip-std":{ "activity_id":[ - "AerChemMIP" + "ISMIP6" ], "additional_allowed_model_components":[ - "CHEM", - "BGC" + "" ], - "description":"Historical WMGHG, halocarbon concentrations and O3 precursor emissions, 1850 aerosol precursor emissions", - "end_year":"2014", - "experiment":"historical forcing, but with pre-industrial aerosol emissions", - "experiment_id":"hist-piAer", - "min_number_yrs_per_sim":"165", + "experiment":"offline ice sheet forced by ISMIP6-specified AGCM AMIP output", + "experiment_id":"ism-amip-std", "parent_activity_id":[ - "CMIP" + "ISMIP6" ], "parent_experiment_id":[ - "piControl" + "ism-ctrl-std" ], "required_model_components":[ - "AOGCM", - "AER" + "ISM" ], - "start_year":"1850", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "hist-piNTCF":{ + "ism-asmb-std":{ "activity_id":[ - "AerChemMIP" + "ISMIP6" ], "additional_allowed_model_components":[ - "CHEM", - "BGC" + "" ], - "description":"Historical WMGHG and halocarbons concentrations, 1850 NTCF emissions", - "end_year":"2014", - "experiment":"historical forcing, but with pre-industrial NTCF emissions", - "experiment_id":"hist-piNTCF", - "min_number_yrs_per_sim":"165", + "experiment":"offline ice sheet forced by initMIP synthetic atmospheric experiment", + "experiment_id":"ism-asmb-std", "parent_activity_id":[ - "CMIP" + "ISMIP6" ], "parent_experiment_id":[ - "piControl" + "ism-ctrl-std" ], "required_model_components":[ - "AOGCM", - "AER" + "ISM" ], - "start_year":"1850", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "hist-resAMO":{ + "ism-bsmb-std":{ "activity_id":[ - "GMMIP" + "ISMIP6" ], "additional_allowed_model_components":[ - "AER", - "CHEM", - "BGC" + "" ], - "description":"Pacemaker 20th century historical run that includes all forcing as used in CMIP6 Historical Simulation, and the observational historical SST is restored in the AMO domain (0deg-70degN, 70degW-0deg)", - "end_year":"2014", - "experiment":"initialized from \"historical\" run year 1870 and SSTs in the AMO domain (0deg-70degN, 70degW-0deg) restored to AMIP SSTs with historical forcings", - "experiment_id":"hist-resAMO", - "min_number_yrs_per_sim":"145", + "experiment":"offline ice sheet forced by initMIP synthetic oceanic experiment", + "experiment_id":"ism-bsmb-std", "parent_activity_id":[ - "CMIP" + "ISMIP6" ], "parent_experiment_id":[ - "historical" + "ism-ctrl-std" ], "required_model_components":[ - "AOGCM" + "ISM" ], - "start_year":"1870", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "hist-resIPO":{ + "ism-ctrl-std":{ "activity_id":[ - "GMMIP" + "ISMIP6" ], "additional_allowed_model_components":[ - "AER", - "CHEM", - "BGC" + "" ], - "description":"Pacemaker 20th century historical run that includes all forcing as used in CMIP6 Historical Simulation, and the observational historical SST is restored in the tropical lobe of the IPO domain (20degS-20degN, 175degE-75degW)", - "end_year":"2014", - "experiment":"initialized from \"historical\" run year 1870 and SSTs in tropical lobe of the IPO domain (20degS-20degN, 175degE-75degW) restored to AMIP SSTs with historical forcings", - "experiment_id":"hist-resIPO", - "min_number_yrs_per_sim":"145", + "experiment":"offline ice sheet model initMIP control", + "experiment_id":"ism-ctrl-std", "parent_activity_id":[ - "CMIP" + "no parent" ], "parent_experiment_id":[ - "historical" + "no parent" ], "required_model_components":[ - "AOGCM" + "ISM" ], - "start_year":"1870", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "hist-sol":{ + "ism-historical-self":{ "activity_id":[ - "DAMIP" + "ISMIP6" ], "additional_allowed_model_components":[ - "AER", - "CHEM", - "BGC" + "" ], - "description":"Historical solar-only transient simulation using settings from CMIP6 historical simulation but fixed GHG and ODS (1850 level)", - "end_year":"2020", - "experiment":"historical solar-only run", - "experiment_id":"hist-sol", - "min_number_yrs_per_sim":"171", + "experiment":"offline ice sheet forced by ISM's own AOGCM historical output", + "experiment_id":"ism-historical-self", "parent_activity_id":[ - "CMIP" + "ISMIP6" ], "parent_experiment_id":[ - "piControl" + "ism-piControl-self" ], "required_model_components":[ - "AOGCM" + "ISM" ], - "start_year":"1850", "sub_experiment_id":[ "none" - ], - "tier":"3" + ] }, - "hist-spAer-aer":{ + "ism-historical-std":{ "activity_id":[ - "RFMIP" + "ISMIP6" ], - "additional_allowed_model_components":"", - "description":"Prescribed anthropogenic aerosol optical properties. Changes in aerosols only", - "end_year":"2014", - "experiment":"historical simulation with specified anthropogenic aerosols, no other forcings", - "experiment_id":"hist-spAer-aer", - "min_number_yrs_per_sim":"165", + "additional_allowed_model_components":[ + "" + ], + "experiment":"offline ice sheet forced by ISMIP6-specified AOGCM historical output", + "experiment_id":"ism-historical-std", "parent_activity_id":[ - "CMIP" + "ISMIP6" ], "parent_experiment_id":[ - "piControl" + "ism-pdControl-std" ], "required_model_components":[ - "AOGCM" + "ISM" ], - "start_year":"1850", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "hist-spAer-all":{ + "ism-lig127k-std":{ "activity_id":[ - "RFMIP" + "ISMIP6" ], - "additional_allowed_model_components":"", - "description":"Prescribed anthropogenic aerosol optical properties. All forcings", - "end_year":"2014", - "experiment":"historical simulation with specified anthropogenic aerosols", - "experiment_id":"hist-spAer-all", - "min_number_yrs_per_sim":"165", + "additional_allowed_model_components":[ + "" + ], + "experiment":"offline ice sheet forced by ISMIP6-specified AGCM last interglacial output", + "experiment_id":"ism-lig127k-std", "parent_activity_id":[ - "CMIP" + "no parent" ], "parent_experiment_id":[ - "piControl" + "no parent" ], "required_model_components":[ - "AOGCM" + "ISM" ], - "start_year":"1850", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "hist-stratO3":{ + "ism-pdControl-std":{ "activity_id":[ - "DAMIP" + "ISMIP6" ], "additional_allowed_model_components":[ - "AER", - "BGC" + "" ], - "description":"Historical stratospheric-ozone-only. In models with coupled chemistry, the chemistry scheme should be turned off, and the simulated ensemble mean monthly mean 3D stratospheric ozone concentrations from the CMIP6 historical simulations should be prescribed. Tropospheric ozone should be fixed at 3D long-term monthly mean piControl values, with a value of 100 ppbv ozone concentration in this piControl climatology used to separate the troposphere from the stratosphere. In models without coupled chemistry the same stratospheric ozone prescribed in the CMIP6 historical simulations should be prescribed. Stratospheric ozone concentrations will be provided by CCMI", - "end_year":"2020", - "experiment":"historical stratospheric-ozone-only run", - "experiment_id":"hist-stratO3", - "min_number_yrs_per_sim":"171", + "experiment":"offline ice sheet forced by ISMIP6-specified AOGCM pdControl output", + "experiment_id":"ism-pdControl-std", "parent_activity_id":[ - "CMIP" + "no parent" ], "parent_experiment_id":[ - "piControl" + "no parent" ], "required_model_components":[ - "AOGCM" + "ISM" ], - "start_year":"1850", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "hist-volc":{ + "ism-piControl-self":{ "activity_id":[ - "DAMIP" + "ISMIP6" ], "additional_allowed_model_components":[ - "AER", - "CHEM", - "BGC" + "" ], - "description":"Historical volcanic-only run", - "end_year":"2020", - "experiment":"historical volcanic-only run", - "experiment_id":"hist-volc", - "min_number_yrs_per_sim":"171", + "experiment":"offline ice sheet forced by ISM's own AOGCM piControl output", + "experiment_id":"ism-piControl-self", "parent_activity_id":[ - "CMIP" + "no parent" ], "parent_experiment_id":[ - "piControl" + "no parent" ], "required_model_components":[ - "AOGCM" + "ISM" ], - "start_year":"1850", "sub_experiment_id":[ "none" - ], - "tier":"3" + ] }, - "histSST":{ + "ism-ssp585-self":{ "activity_id":[ - "AerChemMIP" + "ISMIP6" ], "additional_allowed_model_components":[ - "CHEM" + "" ], - "description":"Historical transient with SSTs prescribed from historical", - "end_year":"2014", - "experiment":"historical prescribed SSTs and historical forcing", - "experiment_id":"histSST", - "min_number_yrs_per_sim":"165", + "experiment":"offline ice sheet forced by ISM's own AOGCM ssp585 output", + "experiment_id":"ism-ssp585-self", "parent_activity_id":[ - "no parent" + "ISMIP6" ], "parent_experiment_id":[ - "no parent" + "ism-historical-self" ], "required_model_components":[ - "AGCM", - "AER" + "ISM" ], - "start_year":"1850", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "histSST-1950HC":{ + "ism-ssp585-std":{ "activity_id":[ - "AerChemMIP" + "ISMIP6" ], - "additional_allowed_model_components":"", - "description":"Historical WMGHG concentrations and NTCF emissions, 1950 halocarbon concentrations", - "end_year":"2014", - "experiment":"historical SSTs and historical forcing, but with1950 halocarbon concentrations", - "experiment_id":"histSST-1950HC", - "min_number_yrs_per_sim":"65", + "additional_allowed_model_components":[ + "" + ], + "experiment":"offline ice sheet forced by ISMIP6-specified AOGCM ssp585 output", + "experiment_id":"ism-ssp585-std", "parent_activity_id":[ - "no parent" + "ISMIP6" ], "parent_experiment_id":[ - "no parent" + "ism-historical-std" ], "required_model_components":[ - "AGCM", - "AER", - "CHEM" + "ISM" ], - "start_year":"1950", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "histSST-piAer":{ + "land-cCO2":{ "activity_id":[ - "AerChemMIP" + "LUMIP" ], "additional_allowed_model_components":[ - "CHEM" + "" ], - "description":"Historical WMGHG, halocarbon concentrations and tropospheric ozone precursors emissions, 1850 aerosol precursor emissions, prescribed SSTs", - "end_year":"2014", - "experiment":"historical SSTs and historical forcing, but with pre-industrial aerosol emissions", - "experiment_id":"histSST-piAer", - "min_number_yrs_per_sim":"165", + "experiment":"historical land-only constant CO2", + "experiment_id":"land-cCO2", "parent_activity_id":[ "no parent" ], @@ -4618,25 +5976,22 @@ "no parent" ], "required_model_components":[ - "AGCM", - "AER" + "LAND", + "BGC" ], - "start_year":"1850", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "histSST-piCH4":{ + "land-cClim":{ "activity_id":[ - "AerChemMIP" + "LUMIP" ], - "additional_allowed_model_components":"", - "description":"Historical (non-CH4) WMGHG concentrations and NTCF emissions, 1850 CH4 concentrations", - "end_year":"2014", - "experiment":"historical SSTs and historical forcing, but with pre-industrial methane concentrations", - "experiment_id":"histSST-piCH4", - "min_number_yrs_per_sim":"165", + "additional_allowed_model_components":[ + "" + ], + "experiment":"historical land-only constant climate", + "experiment_id":"land-cClim", "parent_activity_id":[ "no parent" ], @@ -4644,28 +5999,22 @@ "no parent" ], "required_model_components":[ - "AGCM", - "AER", - "CHEM" + "LAND", + "BGC" ], - "start_year":"1850", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "histSST-piN2O":{ + "land-crop-grass":{ "activity_id":[ - "AerChemMIP" + "LUMIP" ], "additional_allowed_model_components":[ - "BGC" + "" ], - "description":"Historical (non-N2O) WMGHG concentrations and NTCF emissions, 1850 N2O concentrations", - "end_year":"2014", - "experiment":"historical SSTs and historical forcings, but with pre-industrial N2O concentrations", - "experiment_id":"histSST-piN2O", - "min_number_yrs_per_sim":"165", + "experiment":"historical land-only with cropland as natural grassland", + "experiment_id":"land-crop-grass", "parent_activity_id":[ "no parent" ], @@ -4673,29 +6022,22 @@ "no parent" ], "required_model_components":[ - "AGCM", - "AER", - "CHEM" + "LAND", + "BGC" ], - "start_year":"1850", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "histSST-piNTCF":{ + "land-crop-noFert":{ "activity_id":[ - "AerChemMIP" + "LUMIP" ], "additional_allowed_model_components":[ - "CHEM", - "BGC" + "" ], - "description":"Historical WMGHG concentrations and halocarbons emissions, 1850 NTCF emissions, prescribed SSTs", - "end_year":"2014", - "experiment":"historical SSTs and historical forcing, but with pre-industrial NTCF emissions", - "experiment_id":"histSST-piNTCF", - "min_number_yrs_per_sim":"165", + "experiment":"historical land-only with no fertilizer", + "experiment_id":"land-crop-noFert", "parent_activity_id":[ "no parent" ], @@ -4703,265 +6045,225 @@ "no parent" ], "required_model_components":[ - "AGCM", - "AER" + "LAND", + "BGC" ], - "start_year":"1850", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "histSST-piO3":{ + "land-crop-noIrrig":{ "activity_id":[ - "AerChemMIP" + "LUMIP" ], - "additional_allowed_model_components":"", - "description":"Historical WMGHG, halocarbon concentrations and aerosol precursor emissions, 1850 tropospheric ozone precursors emissions, prescribed SSTs", - "end_year":"2014", - "experiment":"historical SSTs and historical forcing, but with pre-industrial ozone precursor emissions", - "experiment_id":"histSST-piO3", - "min_number_yrs_per_sim":"165", + "additional_allowed_model_components":[ + "" + ], + "experiment":"historical land-only with no irrigation", + "experiment_id":"land-crop-noIrrig", "parent_activity_id":[ "no parent" ], "parent_experiment_id":[ "no parent" ], - "required_model_components":[ - "AGCM", - "AER", - "CHEM" + "required_model_components":[ + "LAND", + "BGC" ], - "start_year":"1850", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "historical":{ + "land-crop-noIrrigFert":{ "activity_id":[ - "CMIP" + "LUMIP" ], "additional_allowed_model_components":[ - "AER", - "CHEM", - "BGC" + "" ], - "description":"CMIP6 historical", - "end_year":"2014", - "experiment":"all-forcing simulation of the recent past", - "experiment_id":"historical", - "min_number_yrs_per_sim":"165", + "experiment":"historical land-only with managed crops but with irrigation and fertilization held constant", + "experiment_id":"land-crop-noIrrigFert", "parent_activity_id":[ - "CMIP" + "no parent" ], "parent_experiment_id":[ - "piControl" + "no parent" ], "required_model_components":[ - "AOGCM" + "LAND", + "BGC" ], - "start_year":"1850", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "historical-ext":{ + "land-hist":{ "activity_id":[ - "CMIP" + "LS3MIP LUMIP" ], "additional_allowed_model_components":[ - "AER", - "CHEM", "BGC" ], - "description":"Extension beyond 2014 of the CMIP6 historical", - "end_year":"present", - "experiment":"post-2014 all-forcing simulation", - "experiment_id":"historical-ext", - "min_number_yrs_per_sim":"1", + "experiment":"historical land-only", + "experiment_id":"land-hist", "parent_activity_id":[ - "CMIP" + "no parent" ], "parent_experiment_id":[ - "historical" + "no parent" ], "required_model_components":[ - "AOGCM" + "LAND" ], - "start_year":"2015", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "historical-withism":{ + "land-hist-altLu1":{ "activity_id":[ - "ISMIP6" + "LUMIP" ], "additional_allowed_model_components":[ - "AER", - "CHEM", - "BGC" + "" ], - "description":"Historical simulation that includes interactive ice sheets. Set up follows the historical experiment", - "end_year":"2014", - "experiment":"historical with interactive ice sheet", - "experiment_id":"historical-withism", - "min_number_yrs_per_sim":"165", + "experiment":"historical land-only alternate land-use history", + "experiment_id":"land-hist-altLu1", "parent_activity_id":[ - "ISMIP6" + "no parent" ], "parent_experiment_id":[ - "piControl-withism" + "no parent" ], "required_model_components":[ - "AOGCM", - "ISM" + "LAND", + "BGC" ], - "start_year":"1850", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "ism-1pctCO2to4x-self":{ + "land-hist-altLu2":{ "activity_id":[ - "ISMIP6" + "LUMIP" ], - "additional_allowed_model_components":"", - "description":"Idealized 1%/yr CO2 increase to 4xC02 over 140yrs and kept constant at 4xCO2 for an additional 200 to 400 yrs simulation with ice sheets forced \"offline\" with DECK 1pctCO2 using forcing from its own AOGCM", - "end_year":"", - "experiment":"offline ice sheet model forced by ISM's own AOGCM 1pctCO2to4x output", - "experiment_id":"ism-1pctCO2to4x-self", - "min_number_yrs_per_sim":"350", + "additional_allowed_model_components":[ + "" + ], + "experiment":"historical land-only alternate land use history", + "experiment_id":"land-hist-altLu2", "parent_activity_id":[ - "ISMIP6" + "no parent" ], "parent_experiment_id":[ - "ism-piControl-self" + "no parent" ], "required_model_components":[ - "ISM" + "LAND", + "BGC" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "ism-1pctCO2to4x-std":{ + "land-hist-altStartYear":{ "activity_id":[ - "ISMIP6" + "LUMIP" ], - "additional_allowed_model_components":"", - "description":"Idealized 1%/yr CO2 increase to 4xC02 over 140yrs and kept constant at 4xCO2 for an additional 200 to 400 yrs simulation with ice sheets forced \"offline\" with DECK 1pctCO2 using a standard forcing", - "end_year":"", - "experiment":"offline ice sheet model forced by ISMIP6-specified AOGCM 1pctCO2to4x output", - "experiment_id":"ism-1pctCO2to4x-std", - "min_number_yrs_per_sim":"350", + "additional_allowed_model_components":[ + "" + ], + "experiment":"historical land-only alternate start year", + "experiment_id":"land-hist-altStartYear", "parent_activity_id":[ - "ISMIP6" + "no parent" ], "parent_experiment_id":[ - "ism-pdControl-std" + "no parent" ], "required_model_components":[ - "ISM" + "LAND", + "BGC" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "ism-amip-std":{ + "land-hist-cruNcep":{ "activity_id":[ - "ISMIP6" + "LS3MIP" ], - "additional_allowed_model_components":"", - "description":"Offline ice sheet evolution for the last few decades forced by amip", - "end_year":"2014", - "experiment":"offline ice sheet forced by ISMIP6-specified AGCM AMIP output", - "experiment_id":"ism-amip-std", - "min_number_yrs_per_sim":"36", + "additional_allowed_model_components":[ + "BGC" + ], + "experiment":"as land-hist with CRU-NCEP forcings", + "experiment_id":"land-hist-cruNcep", "parent_activity_id":[ - "ISMIP6" + "no parent" ], "parent_experiment_id":[ - "ism-ctrl-std" + "no parent" ], "required_model_components":[ - "ISM" + "LAND" ], - "start_year":"1979", "sub_experiment_id":[ "none" - ], - "tier":"3" + ] }, - "ism-asmb-std":{ + "land-hist-princeton":{ "activity_id":[ - "ISMIP6" + "LS3MIP" ], - "additional_allowed_model_components":"", - "description":"Offline ice sheet simulation with synthetic atmospheric dataset to explore the uncertainty in sea level due to ice sheet initialization", - "end_year":"", - "experiment":"offline ice sheet forced by initMIP synthetic atmospheric experiment", - "experiment_id":"ism-asmb-std", - "min_number_yrs_per_sim":"100", + "additional_allowed_model_components":[ + "BGC" + ], + "experiment":"as land-hist with Princeton forcings", + "experiment_id":"land-hist-princeton", "parent_activity_id":[ - "ISMIP6" + "no parent" ], "parent_experiment_id":[ - "ism-ctrl-std" + "no parent" ], "required_model_components":[ - "ISM" + "LAND" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "ism-bsmb-std":{ + "land-hist-wfdei":{ "activity_id":[ - "ISMIP6" + "LS3MIP" ], - "additional_allowed_model_components":"", - "description":"Offline ice sheet simulation with synthetic oceanic dataset to explore the uncertainty in sea level due to ice sheet initialization", - "end_year":"", - "experiment":"offline ice sheet forced by initMIP synthetic oceanic experiment", - "experiment_id":"ism-bsmb-std", - "min_number_yrs_per_sim":"100", + "additional_allowed_model_components":[ + "BGC" + ], + "experiment":"as land-hist with WFDEI forcings", + "experiment_id":"land-hist-wfdei", "parent_activity_id":[ - "ISMIP6" + "no parent" ], "parent_experiment_id":[ - "ism-ctrl-std" + "no parent" ], "required_model_components":[ - "ISM" + "LAND" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "ism-ctrl-std":{ + "land-noFire":{ "activity_id":[ - "ISMIP6" + "LUMIP" ], - "additional_allowed_model_components":"", - "description":"Offline ice sheet control run for the initMIP experiment that explores the uncertainty in sea level due to ice sheet initialization", - "end_year":"", - "experiment":"offline ice sheet model initMIP control", - "experiment_id":"ism-ctrl-std", - "min_number_yrs_per_sim":"100", + "additional_allowed_model_components":[ + "" + ], + "experiment":"historical land-only with no human fire management", + "experiment_id":"land-noFire", "parent_activity_id":[ "no parent" ], @@ -4969,74 +6271,67 @@ "no parent" ], "required_model_components":[ - "ISM" + "LAND", + "BGC" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "ism-historical-self":{ + "land-noLu":{ "activity_id":[ - "ISMIP6" + "LUMIP" ], - "additional_allowed_model_components":"", - "description":"Historical simulation using \"offline\" ice sheet models. Forcing for ice sheet model is from its own AOGCM", - "end_year":"2014", - "experiment":"offline ice sheet forced by ISM's own AOGCM historical output", - "experiment_id":"ism-historical-self", - "min_number_yrs_per_sim":"165", + "additional_allowed_model_components":[ + "BGC" + ], + "experiment":"historical land-only with no land-use change", + "experiment_id":"land-noLu", "parent_activity_id":[ - "ISMIP6" + "no parent" ], "parent_experiment_id":[ - "ism-piControl-self" + "no parent" ], "required_model_components":[ - "ISM" + "LAND" ], - "start_year":"1850", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "ism-historical-std":{ + "land-noPasture":{ "activity_id":[ - "ISMIP6" + "LUMIP" ], - "additional_allowed_model_components":"", - "description":"Historical simulation using \"offline\" ice sheet models. Forcing for ice sheet model is the standard dataset based on CMIP6 AOGCM historical", - "end_year":"2014", - "experiment":"offline ice sheet forced by ISMIP6-specified AOGCM historical output", - "experiment_id":"ism-historical-std", - "min_number_yrs_per_sim":"165", + "additional_allowed_model_components":[ + "" + ], + "experiment":"historical land-only with constant pastureland", + "experiment_id":"land-noPasture", "parent_activity_id":[ - "ISMIP6" + "no parent" ], "parent_experiment_id":[ - "ism-pdControl-std" + "no parent" ], "required_model_components":[ - "ISM" + "LAND", + "BGC" ], - "start_year":"1850", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "ism-lig127k-std":{ + "land-noShiftCultivate":{ "activity_id":[ - "ISMIP6" + "LUMIP" ], - "additional_allowed_model_components":"", - "description":"Last interglacial simulation of ice sheet evolution driven by PMIP lig127k", - "end_year":"", - "experiment":"offline ice sheet forced by ISMIP6-specified AGCM last interglacial output", - "experiment_id":"ism-lig127k-std", - "min_number_yrs_per_sim":"20000", + "additional_allowed_model_components":[ + "" + ], + "experiment":"historical land-only with shifting cultivation turned off", + "experiment_id":"land-noShiftCultivate", "parent_activity_id":[ "no parent" ], @@ -5044,24 +6339,22 @@ "no parent" ], "required_model_components":[ - "ISM" + "LAND", + "BGC" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"3" + ] }, - "ism-pdControl-std":{ + "land-noWoodHarv":{ "activity_id":[ - "ISMIP6" + "LUMIP" ], - "additional_allowed_model_components":"", - "description":"Present-day control simulation for \"offline\" ice sheets", - "end_year":"", - "experiment":"offline ice sheet forced by ISMIP6-specified AOGCM pdControl output", - "experiment_id":"ism-pdControl-std", - "min_number_yrs_per_sim":"100", + "additional_allowed_model_components":[ + "" + ], + "experiment":"historical land-only with no wood harvest", + "experiment_id":"land-noWoodHarv", "parent_activity_id":[ "no parent" ], @@ -5069,24 +6362,22 @@ "no parent" ], "required_model_components":[ - "ISM" + "LAND", + "BGC" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "ism-piControl-self":{ + "land-ssp126":{ "activity_id":[ - "ISMIP6" + "LS3MIP" ], - "additional_allowed_model_components":"", - "description":"Pre-industrial control simulation for \"offline\" ice sheets", - "end_year":"", - "experiment":"offline ice sheet forced by ISM's own AOGCM piControl output", - "experiment_id":"ism-piControl-self", - "min_number_yrs_per_sim":"500", + "additional_allowed_model_components":[ + "BGC" + ], + "experiment":"future ssp1-2.6 land only", + "experiment_id":"land-ssp126", "parent_activity_id":[ "no parent" ], @@ -5094,300 +6385,283 @@ "no parent" ], "required_model_components":[ - "ISM" + "LAND" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "ism-ssp585-self":{ + "land-ssp434":{ "activity_id":[ - "ISMIP6" + "LS3MIP" ], - "additional_allowed_model_components":"", - "description":"Future climate ScenarioMIP SSP5-8.5 simulation using \"offline\" ice sheet models. Forcing for ice sheet model is from its own AOGCM", - "end_year":"2300", - "experiment":"offline ice sheet forced by ISM's own AOGCM ssp585 output", - "experiment_id":"ism-ssp585-self", - "min_number_yrs_per_sim":"85", + "additional_allowed_model_components":[ + "BGC" + ], + "experiment":"future ssp4-3.4 land only", + "experiment_id":"land-ssp434", "parent_activity_id":[ - "ISMIP6" + "no parent" ], "parent_experiment_id":[ - "ism-historical-self" + "no parent" ], "required_model_components":[ - "ISM" + "LAND" ], - "start_year":"2015", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "ism-ssp585-std":{ + "land-ssp585":{ "activity_id":[ - "ISMIP6" + "LS3MIP" + ], + "additional_allowed_model_components":[ + "BGC" ], - "additional_allowed_model_components":"", - "description":"Future climate ScenarioMIP SSP5-8.5 simulation using \"offline\" ice sheet models. Forcing for ice sheet model is the standard dataset based on ScenarioMIP ssp585", - "end_year":"2300", - "experiment":"offline ice sheet forced by ISMIP6-specified AOGCM ssp585 output", - "experiment_id":"ism-ssp585-std", - "min_number_yrs_per_sim":"85", + "experiment":"future ssp5-8.5 land only", + "experiment_id":"land-ssp585", "parent_activity_id":[ - "ISMIP6" + "no parent" ], "parent_experiment_id":[ - "ism-historical-std" + "no parent" ], "required_model_components":[ - "ISM" + "LAND" ], - "start_year":"2015", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "land-cCO2":{ + "lfmip-initLC":{ "activity_id":[ - "LUMIP" + "LS3MIP" ], - "additional_allowed_model_components":"", - "description":"Same as land-hist except with CO2 held constant", - "end_year":"2014", - "experiment":"historical land-only constant CO2", - "experiment_id":"land-cCO2", - "min_number_yrs_per_sim":"165", + "additional_allowed_model_components":[ + "AER", + "CHEM", + "BGC" + ], + "experiment":"initialized from \"historical\" run year 1980, but with land conditions initialized from pseudo-observations", + "experiment_id":"lfmip-initLC", "parent_activity_id":[ - "no parent" + "CMIP" ], "parent_experiment_id":[ - "no parent" + "historical" ], "required_model_components":[ - "LAND" + "AOGCM" ], - "start_year":"1850 or 1700", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "land-cClim":{ + "lfmip-pdLC":{ "activity_id":[ - "LUMIP" + "LS3MIP" ], - "additional_allowed_model_components":"", - "description":"Same as land-hist except with climate held constant", - "end_year":"2014", - "experiment":"historical land-only constant climate", - "experiment_id":"land-cClim", - "min_number_yrs_per_sim":"165", + "additional_allowed_model_components":[ + "AER", + "CHEM", + "BGC" + ], + "experiment":"prescribed land conditions (from current climate climatology) and initialized from \"historical\" run year 1980", + "experiment_id":"lfmip-pdLC", "parent_activity_id":[ - "no parent" + "CMIP" ], "parent_experiment_id":[ - "no parent" + "historical" ], "required_model_components":[ - "LAND" + "AOGCM" ], - "start_year":"1850 or 1700", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "land-crop-grass":{ + "lfmip-pdLC-cruNcep":{ "activity_id":[ - "LUMIP" + "LS3MIP" ], - "additional_allowed_model_components":"", - "description":"Same as land-hist but with all new crop and pastureland treated as unmanaged grassland", - "end_year":"2014", - "experiment":"historical land-only with cropland as natural grassland", - "experiment_id":"land-crop-grass", - "min_number_yrs_per_sim":"165", + "additional_allowed_model_components":[ + "AER", + "CHEM", + "BGC" + ], + "experiment":"as LFMIP-pdLC with Land-Hist-cruNcep", + "experiment_id":"lfmip-pdLC-cruNcep", "parent_activity_id":[ - "no parent" + "CMIP" ], "parent_experiment_id":[ - "no parent" + "historical" ], "required_model_components":[ - "LAND" + "AOGCM" ], - "start_year":"1850 or 1700", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "land-crop-noFert":{ + "lfmip-pdLC-princeton":{ "activity_id":[ - "LUMIP" + "LS3MIP" ], - "additional_allowed_model_components":"", - "description":"Same as land-hist but with fertilization rates and area held at 1850 levels/distribution", - "end_year":"2014", - "experiment":"historical land-only with no fertilizer", - "experiment_id":"land-crop-noFert", - "min_number_yrs_per_sim":"165", + "additional_allowed_model_components":[ + "AER", + "CHEM", + "BGC" + ], + "experiment":"as LFMIP-pdLC with Land-Hist-princeton", + "experiment_id":"lfmip-pdLC-princeton", "parent_activity_id":[ - "no parent" + "CMIP" ], "parent_experiment_id":[ - "no parent" + "historical" ], "required_model_components":[ - "LAND" + "AOGCM" ], - "start_year":"1850 or 1700", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "land-crop-noIrrig":{ + "lfmip-pdLC-wfdei":{ "activity_id":[ - "LUMIP" + "LS3MIP" ], - "additional_allowed_model_components":"", - "description":"Same as land-hist but with irrigated area held at 1850 levels", - "end_year":"2014", - "experiment":"historical land-only with no irrigation", - "experiment_id":"land-crop-noIrrig", - "min_number_yrs_per_sim":"165", + "additional_allowed_model_components":[ + "AER", + "CHEM", + "BGC" + ], + "experiment":"as LFMIP-pdLC with Land-Hist-wfdei", + "experiment_id":"lfmip-pdLC-wfdei", "parent_activity_id":[ - "no parent" + "CMIP" ], "parent_experiment_id":[ - "no parent" + "historical" ], "required_model_components":[ - "LAND" + "AOGCM" ], - "start_year":"1850 or 1700", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "land-crop-noIrrigFert":{ + "lfmip-rmLC":{ "activity_id":[ - "LUMIP" + "LS3MIP" ], - "additional_allowed_model_components":"", - "description":"Same as land-hist except with plants in cropland area utilizing at least some form of crop management (e.g., planting and harvesting) rather than simulating cropland vegetation as a natural grassland. Irrigated area and fertilizer area/use should be held constant", - "end_year":"2014", - "experiment":"historical land-only with managed crops but with irrigation and fertilization held constant", - "experiment_id":"land-crop-noIrrigFert", - "min_number_yrs_per_sim":"165", + "additional_allowed_model_components":[ + "AER", + "CHEM", + "BGC" + ], + "experiment":"prescribed land conditions (from running mean climatology) and initialized from \"historical\" run year 1980", + "experiment_id":"lfmip-rmLC", "parent_activity_id":[ - "no parent" + "CMIP" ], "parent_experiment_id":[ - "no parent" + "historical" ], "required_model_components":[ - "LAND" + "AOGCM" ], - "start_year":"1850 or 1700", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "land-future":{ + "lfmip-rmLC-cruNcep":{ "activity_id":[ "LS3MIP" ], - "additional_allowed_model_components":"", - "description":"Land only simulations", - "end_year":"2100", - "experiment":"future land-only", - "experiment_id":"land-future", - "min_number_yrs_per_sim":"86", + "additional_allowed_model_components":[ + "AER", + "CHEM", + "BGC" + ], + "experiment":"as LFMIP-rmLC with Land-Hist-cruNcep", + "experiment_id":"lfmip-rmLC-cruNcep", "parent_activity_id":[ - "no parent" + "CMIP" ], "parent_experiment_id":[ - "no parent" + "historical" ], "required_model_components":[ - "LAND" + "AOGCM" ], - "start_year":"2015", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "land-hist":{ + "lfmip-rmLC-princeton":{ "activity_id":[ - "LS3MIP", - "LUMIP" + "LS3MIP" ], - "additional_allowed_model_components":"", - "description":"Land only simulations", - "end_year":"2014", - "experiment":"historical land-only", - "experiment_id":"land-hist", - "min_number_yrs_per_sim":"165", + "additional_allowed_model_components":[ + "AER", + "CHEM", + "BGC" + ], + "experiment":"as LFMIP-rmLC with Land-Hist-princeton", + "experiment_id":"lfmip-rmLC-princeton", "parent_activity_id":[ - "no parent" + "CMIP" ], "parent_experiment_id":[ - "no parent" + "historical" ], "required_model_components":[ - "LAND" + "AOGCM" ], - "start_year":"1850 or 1700", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "land-hist-altLu1":{ + "lfmip-rmLC-wfdei":{ "activity_id":[ - "LUMIP" + "LS3MIP" ], - "additional_allowed_model_components":"", - "description":"Land only simulations", - "end_year":"2014", - "experiment":"historical land-only alternate land-use history", - "experiment_id":"land-hist-altLu1", - "min_number_yrs_per_sim":"165", + "additional_allowed_model_components":[ + "AER", + "CHEM", + "BGC" + ], + "experiment":"as LFMIP-rmLC with Land-Hist-wfdei", + "experiment_id":"lfmip-rmLC-wfdei", "parent_activity_id":[ - "no parent" + "CMIP" ], "parent_experiment_id":[ - "no parent" + "historical" ], "required_model_components":[ - "LAND" + "AOGCM" ], - "start_year":"1850 or 1700", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "land-hist-altLu2":{ + "lgm":{ "activity_id":[ - "LUMIP" + "PMIP" ], - "additional_allowed_model_components":"", - "description":"Land only simulations", - "end_year":"2014", - "experiment":"historical land-only alternate land use history", - "experiment_id":"land-hist-altLu2", - "min_number_yrs_per_sim":"165", + "additional_allowed_model_components":[ + "AER", + "CHEM", + "BGC" + ], + "experiment":"last glacial maximum", + "experiment_id":"lgm", "parent_activity_id":[ "no parent" ], @@ -5395,24 +6669,23 @@ "no parent" ], "required_model_components":[ - "LAND" + "AOGCM" ], - "start_year":"1850 or 1700", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "land-hist-altStartYear":{ + "lig127k":{ "activity_id":[ - "LUMIP" + "PMIP" ], - "additional_allowed_model_components":"", - "description":"Same as land-hist except starting from either 1700 (for models that typically start in 1850) or 1850 (for models that typically start in 1700)", - "end_year":"2014", - "experiment":"historical land-only alternate start year", - "experiment_id":"land-hist-altStartYear", - "min_number_yrs_per_sim":"165", + "additional_allowed_model_components":[ + "AER", + "CHEM", + "BGC" + ], + "experiment":"last interglacial (127k)", + "experiment_id":"lig127k", "parent_activity_id":[ "no parent" ], @@ -5420,24 +6693,23 @@ "no parent" ], "required_model_components":[ - "LAND" + "AOGCM" ], - "start_year":"1850 or 1700", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "land-hist-cruNcep":{ + "midHolocene":{ "activity_id":[ - "LS3MIP" + "PMIP" ], - "additional_allowed_model_components":"", - "description":"Land only simulations", - "end_year":"2014", - "experiment":"as land-hist with CRU-NCEP forcings", - "experiment_id":"land-hist-cruNcep", - "min_number_yrs_per_sim":"165", + "additional_allowed_model_components":[ + "AER", + "CHEM", + "BGC" + ], + "experiment":"mid-Holocene", + "experiment_id":"midHolocene", "parent_activity_id":[ "no parent" ], @@ -5445,24 +6717,23 @@ "no parent" ], "required_model_components":[ - "LAND" + "AOGCM" ], - "start_year":"1850", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "land-hist-princeton":{ + "midPliocene-eoi400":{ "activity_id":[ - "LS3MIP" + "PMIP" ], - "additional_allowed_model_components":"", - "description":"Land only simulations", - "end_year":"2014", - "experiment":"as land-hist with Princeton forcings", - "experiment_id":"land-hist-princeton", - "min_number_yrs_per_sim":"165", + "additional_allowed_model_components":[ + "AER", + "CHEM", + "BGC" + ], + "experiment":"mid-Pliocene warm period", + "experiment_id":"midPliocene-eoi400", "parent_activity_id":[ "no parent" ], @@ -5470,74 +6741,69 @@ "no parent" ], "required_model_components":[ - "LAND" + "AOGCM" ], - "start_year":"1850", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "land-hist-wfdei":{ + "modelSST-futArcSIC":{ "activity_id":[ - "LS3MIP" + "PAMIP" + ], + "additional_allowed_model_components":[ + "AER", + "CHEM", + "BGC" ], - "additional_allowed_model_components":"", - "description":"Land only simulations", - "end_year":"2014", - "experiment":"as land-hist with WFDEI forcings", - "experiment_id":"land-hist-wfdei", - "min_number_yrs_per_sim":"165", + "experiment":"Atmosphere time slice with present day coupled model SST and future Arctic SIC", + "experiment_id":"modelSST-futArcSIC", "parent_activity_id":[ - "no parent" + "CMIP" ], "parent_experiment_id":[ - "no parent" + "amip" ], "required_model_components":[ - "LAND" + "AGCM" ], - "start_year":"1850", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "land-noFire":{ + "modelSST-pdSIC":{ "activity_id":[ - "LUMIP" + "PAMIP" ], - "additional_allowed_model_components":"", - "description":"Same as land-hist but with anthropogenic ignition and suppression held to 1850 levels", - "end_year":"2014", - "experiment":"historical land-only with no human fire management", - "experiment_id":"land-noFire", - "min_number_yrs_per_sim":"165", + "additional_allowed_model_components":[ + "AER", + "CHEM", + "BGC" + ], + "experiment":"Atmosphere time slice present day control with coupled model SST", + "experiment_id":"modelSST-pdSIC", "parent_activity_id":[ - "no parent" + "CMIP" ], "parent_experiment_id":[ - "no parent" + "amip" ], "required_model_components":[ - "LAND" + "AGCM" ], - "start_year":"1850 or 1700", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "land-noLu":{ + "omip1":{ "activity_id":[ - "LUMIP" + "OMIP" ], - "additional_allowed_model_components":"", - "description":"Same as land-hist except no land-use change", - "end_year":"2014", - "experiment":"historical land-only with no land-use change", - "experiment_id":"land-noLu", - "min_number_yrs_per_sim":"165", + "additional_allowed_model_components":[ + "BGC" + ], + "experiment":"OMIP experiment forced by Large and Yeager (CORE-2, NCEP) atmospheric data set and initialized with observed physical and biogeochemical ocean data", + "experiment_id":"omip1", "parent_activity_id":[ "no parent" ], @@ -5545,24 +6811,21 @@ "no parent" ], "required_model_components":[ - "LAND" + "OGCM" ], - "start_year":"1850 or 1700", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "land-noPasture":{ + "omip1-spunup":{ "activity_id":[ - "LUMIP" + "OMIP" ], - "additional_allowed_model_components":"", - "description":"Same as land-hist but with grazing and other management on pastureland held at 1850 levels/distribution, i.e. all new pastureland is treated as unmanaged grassland (as in land-crop-grass)", - "end_year":"2014", - "experiment":"historical land-only with constant pastureland", - "experiment_id":"land-noPasture", - "min_number_yrs_per_sim":"165", + "additional_allowed_model_components":[ + "BGC" + ], + "experiment":"OMIP experiment forced by Large and Yeager (CORE-2, NCEP) atmospheric data set and initialized from at least a 2000-year spin up of the coupled physical-biogeochemical model", + "experiment_id":"omip1-spunup", "parent_activity_id":[ "no parent" ], @@ -5570,24 +6833,21 @@ "no parent" ], "required_model_components":[ - "LAND" + "OGCM" ], - "start_year":"1850 or 1700", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "land-noShiftCultivate":{ + "omip2":{ "activity_id":[ - "LUMIP" + "OMIP" ], - "additional_allowed_model_components":"", - "description":"Same as land-hist except shifting cultivation turned off. An additional LUC transitions dataset will be provided as a data layer within LUMIP LUH2 dataset with shifting cultivation deactivated", - "end_year":"2014", - "experiment":"historical land-only with shifting cultivation turned off", - "experiment_id":"land-noShiftCultivate", - "min_number_yrs_per_sim":"165", + "additional_allowed_model_components":[ + "BGC" + ], + "experiment":"OMIP experiment forced by JRA55-do atmospheric data set and initialized with observed physical and biogeochemical ocean data", + "experiment_id":"omip2", "parent_activity_id":[ "no parent" ], @@ -5595,24 +6855,21 @@ "no parent" ], "required_model_components":[ - "LAND" + "OGCM" ], - "start_year":"1850 or 1700", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "land-noWoodHarv":{ + "omip2-spunup":{ "activity_id":[ - "LUMIP" + "OMIP" ], - "additional_allowed_model_components":"", - "description":"Same as land-hist but with wood harvest maintained at 1850 amounts/areas", - "end_year":"2014", - "experiment":"historical land-only with no wood harvest", - "experiment_id":"land-noWoodHarv", - "min_number_yrs_per_sim":"165", + "additional_allowed_model_components":[ + "BGC" + ], + "experiment":"OMIP experiment forced by JRA55-do atmospheric data set and initialized from at least a 2000-year spin up of the coupled physical-biogeochemical model", + "experiment_id":"omip2-spunup", "parent_activity_id":[ "no parent" ], @@ -5620,28 +6877,23 @@ "no parent" ], "required_model_components":[ - "LAND" + "OGCM" ], - "start_year":"1850 or 1700", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "lfmip-initLC":{ + "pa-futAntSIC":{ "activity_id":[ - "LS3MIP" + "PAMIP" ], "additional_allowed_model_components":[ "AER", "CHEM", "BGC" ], - "description":"Initialized pseudo-observations land", - "end_year":"2014", - "experiment":"initialized from \"historical\" run year 1980, but with land conditions initialized from pseudo-observations", - "experiment_id":"lfmip-initLC", - "min_number_yrs_per_sim":"35", + "experiment":"Partially-coupled time slice constrained by future Antarctic SIC", + "experiment_id":"pa-futAntSIC", "parent_activity_id":[ "CMIP" ], @@ -5651,26 +6903,21 @@ "required_model_components":[ "AOGCM" ], - "start_year":"1980", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "lfmip-pdL-princeton":{ + "pa-futAntSIC-ext":{ "activity_id":[ - "LS3MIP" + "PAMIP" ], "additional_allowed_model_components":[ "AER", "CHEM", "BGC" ], - "description":"Prescribed land conditions 1980-2014 climate with Land-Hist-princeton", - "end_year":"2100", - "experiment":"as LFMIP-pdLC with Land-Hist-princeton", - "experiment_id":"lfmip-pdL-princeton", - "min_number_yrs_per_sim":"121", + "experiment":"Partially-coupled extended simulation with future Antarctic SIC", + "experiment_id":"pa-futAntSIC-ext", "parent_activity_id":[ "CMIP" ], @@ -5680,26 +6927,21 @@ "required_model_components":[ "AOGCM" ], - "start_year":"1980", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "lfmip-pdLC":{ + "pa-futArcSIC":{ "activity_id":[ - "LS3MIP" + "PAMIP" ], "additional_allowed_model_components":[ "AER", "CHEM", "BGC" ], - "description":"Prescribed land conditions 1980-2014 climate", - "end_year":"2100", - "experiment":"prescribed land conditions (from current climate climatology) and initialized from \"historical\" run year 1980", - "experiment_id":"lfmip-pdLC", - "min_number_yrs_per_sim":"121", + "experiment":"Partially-coupled time slice constrained by future Arctic SIC", + "experiment_id":"pa-futArcSIC", "parent_activity_id":[ "CMIP" ], @@ -5709,26 +6951,21 @@ "required_model_components":[ "AOGCM" ], - "start_year":"1980", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "lfmip-pdLC-cruNcep":{ + "pa-futArcSIC-ext":{ "activity_id":[ - "LS3MIP" + "PAMIP" ], "additional_allowed_model_components":[ "AER", "CHEM", "BGC" ], - "description":"Prescribed land conditions 1980-2014 climate with Land-Hist-cruNcep", - "end_year":"2100", - "experiment":"as LFMIP-pdLC with Land-Hist-cruNcep", - "experiment_id":"lfmip-pdLC-cruNcep", - "min_number_yrs_per_sim":"121", + "experiment":"Partially-coupled extended simulation with future Arctic SIC", + "experiment_id":"pa-futArcSIC-ext", "parent_activity_id":[ "CMIP" ], @@ -5738,26 +6975,21 @@ "required_model_components":[ "AOGCM" ], - "start_year":"1980", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "lfmip-pdLC-wfdei":{ + "pa-pdSIC":{ "activity_id":[ - "LS3MIP" + "PAMIP" ], "additional_allowed_model_components":[ "AER", "CHEM", "BGC" ], - "description":"Prescribed land conditions 1980-2014 climate with Land-Hist-wfdei", - "end_year":"2100", - "experiment":"as LFMIP-pdLC with Land-Hist-wfdei", - "experiment_id":"lfmip-pdLC-wfdei", - "min_number_yrs_per_sim":"121", + "experiment":"Partially-coupled time slice contrained by present day SIC", + "experiment_id":"pa-pdSIC", "parent_activity_id":[ "CMIP" ], @@ -5767,26 +6999,21 @@ "required_model_components":[ "AOGCM" ], - "start_year":"1980", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "lfmip-rmLC":{ + "pa-pdSIC-ext":{ "activity_id":[ - "LS3MIP" + "PAMIP" ], "additional_allowed_model_components":[ "AER", "CHEM", "BGC" ], - "description":"Prescribed land conditions 30yr running mean", - "end_year":"2100", - "experiment":"prescribed land conditions (from running mean climatology) and initialized from \"historical\" run year 1980", - "experiment_id":"lfmip-rmLC", - "min_number_yrs_per_sim":"121", + "experiment":"Partially-coupled extended simulation constrained by present day SIC", + "experiment_id":"pa-pdSIC-ext", "parent_activity_id":[ "CMIP" ], @@ -5796,26 +7023,21 @@ "required_model_components":[ "AOGCM" ], - "start_year":"1980", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "lfmip-rmLC-cruNcep":{ + "pa-piAntSIC":{ "activity_id":[ - "LS3MIP" + "PAMIP" ], "additional_allowed_model_components":[ "AER", "CHEM", "BGC" ], - "description":"Prescribed land conditions 30yr running mean with Land-Hist-cruNcep", - "end_year":"2100", - "experiment":"as LFMIP-rmLC with Land-Hist-cruNcep", - "experiment_id":"lfmip-rmLC-cruNcep", - "min_number_yrs_per_sim":"121", + "experiment":"Partially-coupled time slice with pre-industrial Antarctic SIC", + "experiment_id":"pa-piAntSIC", "parent_activity_id":[ "CMIP" ], @@ -5825,26 +7047,21 @@ "required_model_components":[ "AOGCM" ], - "start_year":"1980", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "lfmip-rmLC-princeton":{ + "pa-piArcSIC":{ "activity_id":[ - "LS3MIP" + "PAMIP" ], "additional_allowed_model_components":[ "AER", "CHEM", "BGC" ], - "description":"Prescribed land conditions 30yr running mean with Land-Hist-princeton", - "end_year":"2100", - "experiment":"as LFMIP-rmLC with Land-Hist-princeton", - "experiment_id":"lfmip-rmLC-princeton", - "min_number_yrs_per_sim":"121", + "experiment":"Partially-coupled time slice constrained by pre-industrial Arctic SIC", + "experiment_id":"pa-piArcSIC", "parent_activity_id":[ "CMIP" ], @@ -5854,298 +7071,260 @@ "required_model_components":[ "AOGCM" ], - "start_year":"1980", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "lfmip-rmLC-wfdei":{ + "past1000":{ "activity_id":[ - "LS3MIP" + "PMIP" ], "additional_allowed_model_components":[ "AER", "CHEM", "BGC" ], - "description":"Prescribed land conditions 30yr running mean with Land-Hist-wfdei", - "end_year":"2100", - "experiment":"as LFMIP-rmLC with Land-Hist-wfdei", - "experiment_id":"lfmip-rmLC-wfdei", - "min_number_yrs_per_sim":"121", + "experiment":"last millennium", + "experiment_id":"past1000", "parent_activity_id":[ - "CMIP" + "no parent" ], "parent_experiment_id":[ - "historical" + "no parent" ], "required_model_components":[ "AOGCM" ], - "start_year":"1980", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "lgm":{ + "pdSST-futAntSIC":{ "activity_id":[ - "PMIP" + "PAMIP" ], "additional_allowed_model_components":[ "AER", "CHEM", "BGC" ], - "description":"main forcings: ice-sheet; trace gases, astronomical parameters, dust (forcing, or feedback if dust cycle represented in model)", - "end_year":"", - "experiment":"last glacial maximum", - "experiment_id":"lgm", - "min_number_yrs_per_sim":"100", + "experiment":"Atmosphere time slice with present day SST and future Antarctic SIC", + "experiment_id":"pdSST-futAntSIC", "parent_activity_id":[ - "no parent" + "CMIP" ], "parent_experiment_id":[ - "no parent" + "amip" ], "required_model_components":[ - "AOGCM" + "AGCM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "lig127k":{ + "pdSST-futArcSIC":{ "activity_id":[ - "PMIP" + "PAMIP" ], "additional_allowed_model_components":[ "AER", "CHEM", "BGC" ], - "description":"main forcings: astronomical parameters, trace gases, dust (forcing, or feedback if dust cycle represented in model)", - "end_year":"", - "experiment":"last interglacial (127k)", - "experiment_id":"lig127k", - "min_number_yrs_per_sim":"100", + "experiment":"Atmosphere time slice with present day SST and future Arctic SIC", + "experiment_id":"pdSST-futArcSIC", "parent_activity_id":[ - "no parent" + "CMIP" ], "parent_experiment_id":[ - "no parent" + "amip" ], "required_model_components":[ - "AOGCM" + "AGCM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "midHolocene":{ + "pdSST-futArcSICSIT":{ "activity_id":[ - "PMIP" + "PAMIP" ], "additional_allowed_model_components":[ "AER", "CHEM", "BGC" ], - "description":"main forcings: trace gases, orbital parameters, dust (forcing, or feedback if dust cycle represented in model)", - "end_year":"", - "experiment":"mid-Holocene", - "experiment_id":"midHolocene", - "min_number_yrs_per_sim":"200", + "experiment":"Atmosphere time slice with present day SST and future Arctic SIC and sea ice thickness", + "experiment_id":"pdSST-futArcSICSIT", "parent_activity_id":[ - "no parent" + "CMIP" ], "parent_experiment_id":[ - "no parent" + "amip" ], "required_model_components":[ - "AOGCM" + "AGCM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "midPliocene-eoi400":{ + "pdSST-futBKSeasSIC":{ "activity_id":[ - "PMIP" + "PAMIP" ], "additional_allowed_model_components":[ "AER", "CHEM", "BGC" ], - "description":"main forcings: trace gases, orography, ice-sheet", - "end_year":"", - "experiment":"mid-Pliocene warm period", - "experiment_id":"midPliocene-eoi400", - "min_number_yrs_per_sim":"100", + "experiment":"Atmosphere time slice with present day SST and future Barents and Kara Seas SIC", + "experiment_id":"pdSST-futBKSeasSIC", "parent_activity_id":[ - "no parent" + "CMIP" ], "parent_experiment_id":[ - "no parent" + "amip" ], "required_model_components":[ - "AOGCM" + "AGCM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "omip1":{ + "pdSST-futOkhotskSIC":{ "activity_id":[ - "OMIP" + "PAMIP" ], - "additional_allowed_model_components":"", - "description":"Global ocean - sea-ice coupled experiment forced with the Coordinated Ocean - ice Reference Experiments inter-annually varying atmospheric and river data sets for years 1948-2009. Initial ocean tracer fields are based on observations. All Priority=1 OMIP diagnostics are requested for all five cycles of the 62-year forcing to quantify drift. All OMIP diagnostics (Priority=1,2,3) are requested for the 5th cycle", - "end_year":"310", - "experiment":"OMIP experiment forced by Large and Yeager (CORE-2, NCEP) atmospheric data set and initialized with observed physical and biogeochemical ocean data", - "experiment_id":"omip1", - "min_number_yrs_per_sim":"310", + "additional_allowed_model_components":[ + "AER", + "CHEM", + "BGC" + ], + "experiment":"Atmosphere time slice with present day SST and future Sea of Okhotsk SIC", + "experiment_id":"pdSST-futOkhotskSIC", "parent_activity_id":[ - "no parent" + "CMIP" ], "parent_experiment_id":[ - "no parent" + "amip" ], "required_model_components":[ - "OGCM" + "AGCM" ], - "start_year":"1", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, - "omip1-spunup":{ + "pdSST-pdSIC":{ "activity_id":[ - "OMIP" + "PAMIP" ], - "additional_allowed_model_components":"", - "description":"Same as the omip1 experiment except that it is not initialized with observed climatologies; rather it is initialized with results from at least a 2000-year spin up of the coupled physical-biogeochemical models. The spin up simulations may be made with the classic online or offline approach, or with tracer-acceleration techniques or fast solvers. If an online approach is used, at the end of the 5th cycle of CORE-II forcing, the model's physical fields should be reinitialized to the values at the start of the 3rd cycle in order to avoid long-term drift in those fields and to assure that they will not diverge greatly from physical fields in the omip1 simulation. The spin up also includes radiocarbon to evaluate deep-ocean circulation", - "end_year":"", - "experiment":"OMIP experiment forced by Large and Yeager (CORE-2, NCEP) atmospheric data set and initialized from at least a 2000-year spin up of the coupled physical-biogeochemical model", - "experiment_id":"omip1-spunup", - "min_number_yrs_per_sim":"310", + "additional_allowed_model_components":[ + "AER", + "CHEM", + "BGC" + ], + "experiment":"Atmosphere time slice with present day SST and SIC", + "experiment_id":"pdSST-pdSIC", "parent_activity_id":[ - "no parent" + "CMIP" ], "parent_experiment_id":[ - "no parent" + "amip" ], "required_model_components":[ - "OGCM" + "AGCM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, - "omip2":{ + "pdSST-pdSICSIT":{ "activity_id":[ - "OMIP" + "PAMIP" ], - "additional_allowed_model_components":"", - "description":"Global ocean - sea-ice coupled experiment forced with the JRA-55do inter-annually varying atmospheric and river data sets for years 1958-2016. Initial ocean tracer fields are based on observations. All Priority=1 OMIP diagnostics are requested for all five cycles of the 59-year forcing to quantify drift. All OMIP diagnostics (Priority=1,2,3) are requested for the 5th cycle", - "end_year":"", - "experiment":"OMIP experiment forced by JRA-55do atmospheric data set and initialized with observed physical and biogeochemical ocean data", - "experiment_id":"omip2", - "min_number_yrs_per_sim":"295", + "additional_allowed_model_components":[ + "AER", + "CHEM", + "BGC" + ], + "experiment":"Atmosphere time slice constrained by present day conditions including sea ice thickness", + "experiment_id":"pdSST-pdSICSIT", "parent_activity_id":[ - "no parent" + "CMIP" ], "parent_experiment_id":[ - "no parent" + "amip" ], "required_model_components":[ - "OGCM" + "AGCM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"3" + ] }, - "omip2-spunup":{ + "pdSST-piAntSIC":{ "activity_id":[ - "OMIP" + "PAMIP" ], - "additional_allowed_model_components":"", - "description":"Same as the omip2 experiment except that it is not initialized with observed climatologies; rather it is initialized with results from at least a 2000-year spin up of the coupled physical-biogeochemical models. The spin up simulations may be made with the classic online or offline approach, or with tracer-acceleration techniques or fast solvers. If an online approach is used, at the end of the 5th cycle ofthe JRA-55do forcing, the model's physical fields should be reinitialized to the values at the start of the 3rd cycle in order to avoid long-term drift in those fields and to assure that they will not diverge greatly from physical fields in the omip2 simulation. The spin up also includes radiocarbon to evaluate deep-ocean circulation", - "end_year":"", - "experiment":"OMIP experiment forced by JRA-55do atmospheric data set and initialized from at least a 2000-year spin up of the coupled physical-biogeochemical model", - "experiment_id":"omip2-spunup", - "min_number_yrs_per_sim":"295", + "additional_allowed_model_components":[ + "AER", + "CHEM", + "BGC" + ], + "experiment":"Atmosphere time slice with present day SST and pre-industrial Antarctic SIC", + "experiment_id":"pdSST-piAntSIC", "parent_activity_id":[ - "no parent" + "CMIP" ], "parent_experiment_id":[ - "no parent" + "amip" ], "required_model_components":[ - "OGCM" + "AGCM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"3" + ] }, - "past1000":{ + "pdSST-piArcSIC":{ "activity_id":[ - "PMIP" + "PAMIP" ], "additional_allowed_model_components":[ "AER", "CHEM", "BGC" ], - "description":"main forcings: trace gases, volcanoes, solar variability, land use", - "end_year":"1849", - "experiment":"last millennium", - "experiment_id":"past1000", - "min_number_yrs_per_sim":"1000", + "experiment":"Atmosphere time slice with present day SST and pre-industrial Arctic SIC", + "experiment_id":"pdSST-piArcSIC", "parent_activity_id":[ - "no parent" + "CMIP" ], "parent_experiment_id":[ - "no parent" + "amip" ], "required_model_components":[ - "AOGCM" + "AGCM" ], - "start_year":"850", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, "piClim-2xDMS":{ "activity_id":[ "AerChemMIP" ], "additional_allowed_model_components":[ - "CHEM" + "CHEM", + "BGC" ], - "description":"1850 control with doubled emissions of DMS", - "end_year":"", "experiment":"pre-industrial climatological SSTs and forcing, but with doubled emissions of DMS", "experiment_id":"piClim-2xDMS", - "min_number_yrs_per_sim":"30", "parent_activity_id":[ "CMIP" ], @@ -6156,22 +7335,19 @@ "AGCM", "AER" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"3" + ] }, "piClim-2xNOx":{ "activity_id":[ "AerChemMIP" ], - "additional_allowed_model_components":"", - "description":"1850 control with doubled emissions of lightning NOx", - "end_year":"", + "additional_allowed_model_components":[ + "BGC" + ], "experiment":"pre-industrial climatological SSTs and forcing, but with doubled production of NOx due to lightning", "experiment_id":"piClim-2xNOx", - "min_number_yrs_per_sim":"30", "parent_activity_id":[ "CMIP" ], @@ -6183,22 +7359,19 @@ "AER", "CHEM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"3" + ] }, "piClim-2xVOC":{ "activity_id":[ "AerChemMIP" ], - "additional_allowed_model_components":"", - "description":"1850 control with doubled emissions of biogenic VOCs", - "end_year":"", + "additional_allowed_model_components":[ + "BGC" + ], "experiment":"pre-industrial climatological SSTs and forcing, but with doubled emissions of biogenic VOCs", "experiment_id":"piClim-2xVOC", - "min_number_yrs_per_sim":"30", "parent_activity_id":[ "CMIP" ], @@ -6210,24 +7383,20 @@ "AER", "CHEM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"3" + ] }, "piClim-2xdust":{ "activity_id":[ "AerChemMIP" ], "additional_allowed_model_components":[ - "CHEM" + "CHEM", + "BGC" ], - "description":"1850 control with doubled dust emissions", - "end_year":"", "experiment":"pre-industrial climatological SSTs and forcing, but with doubled emissions of dust", "experiment_id":"piClim-2xdust", - "min_number_yrs_per_sim":"30", "parent_activity_id":[ "CMIP" ], @@ -6238,24 +7407,20 @@ "AGCM", "AER" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, "piClim-2xfire":{ "activity_id":[ "AerChemMIP" ], "additional_allowed_model_components":[ - "CHEM" + "CHEM", + "BGC" ], - "description":"1850 control with doubled emissions of fires", - "end_year":"", "experiment":"pre-industrial climatological SSTs and forcing, but with doubled emissions from fires", "experiment_id":"piClim-2xfire", - "min_number_yrs_per_sim":"30", "parent_activity_id":[ "CMIP" ], @@ -6266,24 +7431,20 @@ "AGCM", "AER" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"3" + ] }, "piClim-2xss":{ "activity_id":[ "AerChemMIP" ], "additional_allowed_model_components":[ - "CHEM" + "CHEM", + "BGC" ], - "description":"1850 control with doubled sea salt emissions", - "end_year":"", "experiment":"pre-industrial climatological SSTs and forcing, but with doubled emissions of sea salt", "experiment_id":"piClim-2xss", - "min_number_yrs_per_sim":"30", "parent_activity_id":[ "CMIP" ], @@ -6294,11 +7455,9 @@ "AGCM", "AER" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, "piClim-4xCO2":{ "activity_id":[ @@ -6308,11 +7467,8 @@ "AER", "CHEM" ], - "description":"As in RFMIP-ERF-PI-Cntrl but with 4xCO2", - "end_year":"", "experiment":"effective radiative forcing by 4xCO2", "experiment_id":"piClim-4xCO2", - "min_number_yrs_per_sim":"30", "parent_activity_id":[ "CMIP" ], @@ -6322,24 +7478,20 @@ "required_model_components":[ "AGCM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, "piClim-BC":{ "activity_id":[ "AerChemMIP" ], "additional_allowed_model_components":[ - "CHEM" + "CHEM", + "BGC" ], - "description":"Perturbation from 1850 control using 2014 BC emissions", - "end_year":"", "experiment":"pre-industrial climatological SSTs and forcing, but with 2014 black carbon emissions", "experiment_id":"piClim-BC", - "min_number_yrs_per_sim":"30", "parent_activity_id":[ "CMIP" ], @@ -6350,22 +7502,19 @@ "AGCM", "AER" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, "piClim-CH4":{ "activity_id":[ "AerChemMIP" ], - "additional_allowed_model_components":"", - "description":"Perturbation from 1850 control using 2014 CH4 concentrations", - "end_year":"", + "additional_allowed_model_components":[ + "BGC" + ], "experiment":"pre-industrial climatological SSTs and forcing, but with 2014 methane concentrations (including chemistry)", "experiment_id":"piClim-CH4", - "min_number_yrs_per_sim":"30", "parent_activity_id":[ "CMIP" ], @@ -6377,22 +7526,19 @@ "AER", "CHEM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, "piClim-HC":{ "activity_id":[ "AerChemMIP" ], - "additional_allowed_model_components":"", - "description":"Perturbation from 1850 control using 2014 halocarbon concentrations", - "end_year":"", + "additional_allowed_model_components":[ + "BGC" + ], "experiment":"pre-industrial climatological SSTs and forcing, but with 2014 halocarbon concentrations (including chemistry)", "experiment_id":"piClim-HC", - "min_number_yrs_per_sim":"30", "parent_activity_id":[ "CMIP" ], @@ -6404,22 +7550,19 @@ "AER", "CHEM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, "piClim-N2O":{ "activity_id":[ "AerChemMIP" ], - "additional_allowed_model_components":"", - "description":"Perturbation from 1850 control using 2014 N2O concentrations", - "end_year":"", + "additional_allowed_model_components":[ + "BGC" + ], "experiment":"pre-industrial climatological SSTs and forcing, but with 2014 N2O concentrations (including chemistry)", "experiment_id":"piClim-N2O", - "min_number_yrs_per_sim":"30", "parent_activity_id":[ "CMIP" ], @@ -6431,24 +7574,20 @@ "AER", "CHEM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, "piClim-NH3":{ "activity_id":[ "AerChemMIP" ], "additional_allowed_model_components":[ - "CHEM" + "CHEM", + "BGC" ], - "description":"Perturbation from 1850 control using 2014 NH3 emissions", - "end_year":"", "experiment":"pre-industrial climatological SSTs and forcing, but with 2014 ammonia emissions", "experiment_id":"piClim-NH3", - "min_number_yrs_per_sim":"30", "parent_activity_id":[ "CMIP" ], @@ -6459,22 +7598,19 @@ "AGCM", "AER" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"3" + ] }, "piClim-NOx":{ "activity_id":[ "AerChemMIP" ], - "additional_allowed_model_components":"", - "description":"Perturbation from 1850 control using 2014 NOx emissions", - "end_year":"", + "additional_allowed_model_components":[ + "BGC" + ], "experiment":"pre-industrial climatological SSTs and forcing, but with 2014 NOx emissions", "experiment_id":"piClim-NOx", - "min_number_yrs_per_sim":"30", "parent_activity_id":[ "CMIP" ], @@ -6486,11 +7622,9 @@ "AER", "CHEM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"3" + ] }, "piClim-NTCF":{ "activity_id":[ @@ -6500,11 +7634,8 @@ "CHEM", "BGC" ], - "description":"Perturbation from 1850 control using 2014 aerosol and ozone precursor emissions", - "end_year":"", "experiment":"pre-industrial climatological SSTs and forcing, but with 2014 NTCF emissions", "experiment_id":"piClim-NTCF", - "min_number_yrs_per_sim":"30", "parent_activity_id":[ "CMIP" ], @@ -6515,22 +7646,19 @@ "AGCM", "AER" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, "piClim-O3":{ "activity_id":[ "AerChemMIP" ], - "additional_allowed_model_components":"", - "description":"Perturbation from 1850 control using 2014 ozone precursor emissions", - "end_year":"", + "additional_allowed_model_components":[ + "BGC" + ], "experiment":"pre-industrial climatological SSTs and forcing, but with 2014 ozone precursor emissions", "experiment_id":"piClim-O3", - "min_number_yrs_per_sim":"30", "parent_activity_id":[ "CMIP" ], @@ -6542,24 +7670,20 @@ "AER", "CHEM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, "piClim-OC":{ "activity_id":[ "AerChemMIP" ], "additional_allowed_model_components":[ - "CHEM" + "CHEM", + "BGC" ], - "description":"Perturbation from 1850 control using 2014 OC emissions", - "end_year":"", "experiment":"pre-industrial climatological SSTs and forcing, but with 2014 organic carbon emissions", "experiment_id":"piClim-OC", - "min_number_yrs_per_sim":"30", "parent_activity_id":[ "CMIP" ], @@ -6570,24 +7694,20 @@ "AGCM", "AER" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"3" + ] }, "piClim-SO2":{ "activity_id":[ "AerChemMIP" ], "additional_allowed_model_components":[ - "CHEM" + "CHEM", + "BGC" ], - "description":"Perturbation from 1850 control using 2014 SO2 emissions", - "end_year":"", "experiment":"pre-industrial climatological SSTs and forcing, but with 2014 SO2 emissions", "experiment_id":"piClim-SO2", - "min_number_yrs_per_sim":"30", "parent_activity_id":[ "CMIP" ], @@ -6598,22 +7718,19 @@ "AGCM", "AER" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"3" + ] }, "piClim-VOC":{ "activity_id":[ "AerChemMIP" ], - "additional_allowed_model_components":"", - "description":"Perturbation from 1850 control using 2014 CO/VOC emissions", - "end_year":"", + "additional_allowed_model_components":[ + "BGC" + ], "experiment":"pre-industrial climatological SSTs and forcing, but with 2014 VOC emissions", "experiment_id":"piClim-VOC", - "min_number_yrs_per_sim":"30", "parent_activity_id":[ "CMIP" ], @@ -6625,26 +7742,21 @@ "AER", "CHEM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"3" + ] }, "piClim-aer":{ "activity_id":[ - "RFMIP", - "AerChemMIP" + "RFMIP AerChemMIP" ], "additional_allowed_model_components":[ "AER", - "CHEM" + "CHEM", + "BGC" ], - "description":"As in RFMIP-ERF-PI-Cntrl but with with present-day aerosols. Note that this experiment is considered to be tier 1 by RFMIP but tier 2 by AerChemMIP", - "end_year":"", "experiment":"effective radiative forcing by present-day aerosols", "experiment_id":"piClim-aer", - "min_number_yrs_per_sim":"30", "parent_activity_id":[ "CMIP" ], @@ -6654,11 +7766,9 @@ "required_model_components":[ "AGCM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, "piClim-anthro":{ "activity_id":[ @@ -6668,11 +7778,8 @@ "AER", "CHEM" ], - "description":"As in RFMIP-ERF-PI-Cntrl but with present-day anthropogenic forcing (greenhouse gases, aerosols and land-use)", - "end_year":"", "experiment":"effective radiative forcing by present day anthropogenic agents", "experiment_id":"piClim-anthro", - "min_number_yrs_per_sim":"30", "parent_activity_id":[ "CMIP" ], @@ -6682,26 +7789,21 @@ "required_model_components":[ "AGCM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, "piClim-control":{ "activity_id":[ - "RFMIP", - "AerChemMIP" + "RFMIP AerChemMIP" ], "additional_allowed_model_components":[ "AER", - "CHEM" + "CHEM", + "BGC" ], - "description":"30-year atmosphere only integration using preindustrial sea-surface temperature and sea-ice climatology. Interactive vegetation", - "end_year":"", "experiment":"effective radiative forcing in present-day", "experiment_id":"piClim-control", - "min_number_yrs_per_sim":"30", "parent_activity_id":[ "CMIP" ], @@ -6711,11 +7813,9 @@ "required_model_components":[ "AGCM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, "piClim-ghg":{ "activity_id":[ @@ -6723,13 +7823,11 @@ ], "additional_allowed_model_components":[ "AER", - "CHEM" + "CHEM", + "BGC" ], - "description":"As in RFMIP-ERF-PI-Cntrl but with present-day greenhouse gases", - "end_year":"", "experiment":"effective radiative forcing by present-day greenhouse gases", "experiment_id":"piClim-ghg", - "min_number_yrs_per_sim":"30", "parent_activity_id":[ "CMIP" ], @@ -6739,11 +7837,9 @@ "required_model_components":[ "AGCM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, "piClim-histaer":{ "activity_id":[ @@ -6751,13 +7847,11 @@ ], "additional_allowed_model_components":[ "AER", - "CHEM" + "CHEM", + "BGC" ], - "description":"Time-varying forcing by aerosols. SST and sea ice fixed at preindustrial control. Interactive vegetation", - "end_year":"2100", "experiment":"transient effective radiative forcing by aerosols", "experiment_id":"piClim-histaer", - "min_number_yrs_per_sim":"251", "parent_activity_id":[ "CMIP" ], @@ -6767,11 +7861,9 @@ "required_model_components":[ "AGCM" ], - "start_year":"1850", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, "piClim-histall":{ "activity_id":[ @@ -6779,13 +7871,11 @@ ], "additional_allowed_model_components":[ "AER", - "CHEM" + "CHEM", + "BGC" ], - "description":"Time-varying forcing. SST and sea ice fixed at preindustrial control. Interactive vegetation", - "end_year":"2100", "experiment":"transient effective radiative forcing", "experiment_id":"piClim-histall", - "min_number_yrs_per_sim":"251", "parent_activity_id":[ "CMIP" ], @@ -6795,11 +7885,9 @@ "required_model_components":[ "AGCM" ], - "start_year":"1850", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, "piClim-histghg":{ "activity_id":[ @@ -6807,13 +7895,11 @@ ], "additional_allowed_model_components":[ "AER", - "CHEM" + "CHEM", + "BGC" ], - "description":"Time-varying forcing by GHGs. SST and sea ice fixed at preindustrial control. Interactive vegetation", - "end_year":"2100", "experiment":"transient effective radiative forcing by greenhouse gases", "experiment_id":"piClim-histghg", - "min_number_yrs_per_sim":"251", "parent_activity_id":[ "CMIP" ], @@ -6823,11 +7909,9 @@ "required_model_components":[ "AGCM" ], - "start_year":"1850", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, "piClim-histnat":{ "activity_id":[ @@ -6835,13 +7919,11 @@ ], "additional_allowed_model_components":[ "AER", - "CHEM" + "CHEM", + "BGC" ], - "description":"Time-varying forcing from volcanos, solar variability, etc. SST and sea ice fixed at preindustrial control. Interactive vegetation", - "end_year":"2100", "experiment":"transient effective radiative forcing by natural perturbations", "experiment_id":"piClim-histnat", - "min_number_yrs_per_sim":"251", "parent_activity_id":[ "CMIP" ], @@ -6851,11 +7933,9 @@ "required_model_components":[ "AGCM" ], - "start_year":"1850", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, "piClim-lu":{ "activity_id":[ @@ -6863,13 +7943,11 @@ ], "additional_allowed_model_components":[ "AER", - "CHEM" + "CHEM", + "BGC" ], - "description":"As in RFMIP-ERF-PI-Cntrl but with present-day land use", - "end_year":"", "experiment":"effective radiative forcing by present-day land use", "experiment_id":"piClim-lu", - "min_number_yrs_per_sim":"30", "parent_activity_id":[ "CMIP" ], @@ -6879,22 +7957,19 @@ "required_model_components":[ "AGCM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, "piClim-spAer-aer":{ "activity_id":[ "RFMIP" ], - "additional_allowed_model_components":"", - "description":"Prescribed anthropogenic aerosol optical properties. Aerosol and ozone forcings", - "end_year":"", + "additional_allowed_model_components":[ + "" + ], "experiment":"effective radiative forcing at present day with specified anthropogenic aerosol optical properties, all forcings", "experiment_id":"piClim-spAer-aer", - "min_number_yrs_per_sim":"", "parent_activity_id":[ "CMIP" ], @@ -6904,22 +7979,19 @@ "required_model_components":[ "AGCM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, "piClim-spAer-anthro":{ "activity_id":[ "RFMIP" ], - "additional_allowed_model_components":"", - "description":"Prescribed anthropogenic aerosol optical properties. Anthropogenic forcings", - "end_year":"", + "additional_allowed_model_components":[ + "" + ], "experiment":"effective radiative forcing at present day with specified anthropogenic aerosol optical properties, anthropogenic forcings", "experiment_id":"piClim-spAer-anthro", - "min_number_yrs_per_sim":"", "parent_activity_id":[ "CMIP" ], @@ -6929,22 +8001,19 @@ "required_model_components":[ "AGCM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, "piClim-spAer-histaer":{ "activity_id":[ "RFMIP" ], - "additional_allowed_model_components":"", - "description":"Prescribed anthropogenic aerosol optical properties. Aerosol and ozone forcings", - "end_year":"2014", + "additional_allowed_model_components":[ + "" + ], "experiment":"transient effective radiative forcing with specified anthropogenic aerosol optical properties, aerosol forcing", "experiment_id":"piClim-spAer-histaer", - "min_number_yrs_per_sim":"165", "parent_activity_id":[ "CMIP" ], @@ -6954,22 +8023,19 @@ "required_model_components":[ "AGCM" ], - "start_year":"1850", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, "piClim-spAer-histall":{ "activity_id":[ "RFMIP" ], - "additional_allowed_model_components":"", - "description":"Prescribed anthropogenic aerosol optical properties. Aerosol and ozone forcings", - "end_year":"2014", + "additional_allowed_model_components":[ + "" + ], "experiment":"transient effective radiative forcing with specified anthropogenic aerosol optical properties, all forcings", "experiment_id":"piClim-spAer-histall", - "min_number_yrs_per_sim":"165", "parent_activity_id":[ "CMIP" ], @@ -6979,11 +8045,9 @@ "required_model_components":[ "AGCM" ], - "start_year":"1850", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, "piControl":{ "activity_id":[ @@ -6994,11 +8058,8 @@ "CHEM", "BGC" ], - "description":"DECK: control", - "end_year":"", "experiment":"pre-industrial control", "experiment_id":"piControl", - "min_number_yrs_per_sim":"500", "parent_activity_id":[ "CMIP" ], @@ -7008,11 +8069,9 @@ "required_model_components":[ "AOGCM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, "piControl-spinup":{ "activity_id":[ @@ -7023,11 +8082,8 @@ "CHEM", "BGC" ], - "description":"DECK: spin-up portion of the control", - "end_year":"", "experiment":"pre-industrial control (spin-up)", "experiment_id":"piControl-spinup", - "min_number_yrs_per_sim":"100", "parent_activity_id":[ "no parent" ], @@ -7037,11 +8093,9 @@ "required_model_components":[ "AOGCM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, "piControl-withism":{ "activity_id":[ @@ -7052,11 +8106,8 @@ "CHEM", "BGC" ], - "description":"Pre-industrial control simulation that includes interactive ice sheets", - "end_year":"", "experiment":"preindustrial control with interactive ice sheet", "experiment_id":"piControl-withism", - "min_number_yrs_per_sim":"500", "parent_activity_id":[ "no parent" ], @@ -7067,11 +8118,9 @@ "AOGCM", "ISM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, "piSST":{ "activity_id":[ @@ -7081,11 +8130,8 @@ "AER", "CHEM" ], - "description":"An AGCM experiment with monthly-varying SSTs, sea-ice, atmospheric constituents and any other necessary boundary conditions (e.g. vegetation if required) taken from each model's own piControl run (using the 30 years of piControl that are parallel to years 111-140 of its abrupt4xCO2 run). Dynamic vegetation should be turned off in all the piSST set of experiments", - "end_year":"", "experiment":"experiment forced with pre-industrial SSTs, sea ice and atmospheric constituents", "experiment_id":"piSST", - "min_number_yrs_per_sim":"30", "parent_activity_id":[ "CMIP" ], @@ -7095,11 +8141,9 @@ "required_model_components":[ "AGCM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, "piSST-4xCO2":{ "activity_id":[ @@ -7109,11 +8153,8 @@ "AER", "CHEM" ], - "description":"Same as piSST but CO2 is quadrupled. The increase in CO2 is seen by both the radiation scheme and vegetation", - "end_year":"", "experiment":"as piSST with radiation and vegetation seeing 4xCO2", "experiment_id":"piSST-4xCO2", - "min_number_yrs_per_sim":"30", "parent_activity_id":[ "CMIP" ], @@ -7123,11 +8164,9 @@ "required_model_components":[ "AGCM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, "piSST-4xCO2-rad":{ "activity_id":[ @@ -7137,11 +8176,8 @@ "AER", "CHEM" ], - "description":"Same as piSST but CO2 as seen by the radiation scheme is quadrupled", - "end_year":"", "experiment":"as piSST with radiation-only seeing 4xCO2", "experiment_id":"piSST-4xCO2-rad", - "min_number_yrs_per_sim":"30", "parent_activity_id":[ "CMIP" ], @@ -7151,11 +8187,9 @@ "required_model_components":[ "AGCM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, "piSST-4xCO2-solar":{ "activity_id":[ @@ -7165,11 +8199,8 @@ "AER", "CHEM" ], - "description":"Time slice at 1850 (picontrol) for G1ext to examine radiative forcing of abrupt4xCO2", - "end_year":"", "experiment":"preindustrial control SSTs with quadrupled CO2 and solar reduction", "experiment_id":"piSST-4xCO2-solar", - "min_number_yrs_per_sim":"10", "parent_activity_id":[ "CMIP" ], @@ -7179,11 +8210,57 @@ "required_model_components":[ "AGCM" ], - "start_year":"", "sub_experiment_id":[ "none" + ] + }, + "piSST-pdSIC":{ + "activity_id":[ + "PAMIP" + ], + "additional_allowed_model_components":[ + "AER", + "CHEM", + "BGC" + ], + "experiment":"Atmosphere time slice with pre-industrial SST and present day SIC", + "experiment_id":"piSST-pdSIC", + "parent_activity_id":[ + "CMIP" + ], + "parent_experiment_id":[ + "amip" + ], + "required_model_components":[ + "AGCM" + ], + "sub_experiment_id":[ + "none" + ] + }, + "piSST-piSIC":{ + "activity_id":[ + "PAMIP" + ], + "additional_allowed_model_components":[ + "AER", + "CHEM", + "BGC" + ], + "experiment":"Atmosphere time slice with pre-industrial SST and SIC", + "experiment_id":"piSST-piSIC", + "parent_activity_id":[ + "CMIP" + ], + "parent_experiment_id":[ + "amip" + ], + "required_model_components":[ + "AGCM" ], - "tier":"2" + "sub_experiment_id":[ + "none" + ] }, "piSST-pxK":{ "activity_id":[ @@ -7193,11 +8270,8 @@ "AER", "CHEM" ], - "description":"Same as piSST, but with a spatially and temporally uniform SST anomaly applied on top of the monthly-varying piSST SSTs. The magnitude of the uniform increase is taken from each model's global, climatological annual mean SST change between abrupt4xCO2 minus piControl (using the mean of years 111-140 of abrupt4xCO2, and the parallel 30-year section of piControl)", - "end_year":"", - "experiment":"as piSST with uniform SST increase with magnitude based on abrupt4xCO2 response", + "experiment":"as piSST with uniform SST increase with magnitude based on abrupt-4xCO2 response", "experiment_id":"piSST-pxK", - "min_number_yrs_per_sim":"20", "parent_activity_id":[ "CMIP" ], @@ -7207,22 +8281,19 @@ "required_model_components":[ "AGCM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, "rad-irf":{ "activity_id":[ "RFMIP" ], - "additional_allowed_model_components":"", - "description":"Offline radiation calculations", - "end_year":"", + "additional_allowed_model_components":[ + "" + ], "experiment":"offline assessment of radiative transfer parmeterizations in clear skies", "experiment_id":"rad-irf", - "min_number_yrs_per_sim":"", "parent_activity_id":[ "no parent" ], @@ -7232,11 +8303,9 @@ "required_model_components":[ "RAD" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, "spinup-1950":{ "activity_id":[ @@ -7245,11 +8314,8 @@ "additional_allowed_model_components":[ "AER" ], - "description":"Coupled integration from ocean rest state using recommended HighResMIP protocol spinup, starting from 1950 ocean temperature and salinity analysis EN4, using constant 1950s forcing. At least 30 years to satisfy near surface quasi-equilibrium", - "end_year":"", "experiment":"coupled spinup with fixed 1950s forcings from 1950 initial conditions (with ocean at rest) to provide initial condition for control-1950 and hist-1950", "experiment_id":"spinup-1950", - "min_number_yrs_per_sim":"30", "parent_activity_id":[ "no parent" ], @@ -7259,11 +8325,33 @@ "required_model_components":[ "AOGCM" ], - "start_year":"", "sub_experiment_id":[ "none" + ] + }, + "ssp119":{ + "activity_id":[ + "ScenarioMIP" + ], + "additional_allowed_model_components":[ + "AER", + "CHEM", + "BGC" + ], + "experiment":"low-end scenario reaching 1.9 W m-2, based on SSP1", + "experiment_id":"ssp119", + "parent_activity_id":[ + "CMIP" + ], + "parent_experiment_id":[ + "historical" + ], + "required_model_components":[ + "AOGCM" ], - "tier":"2" + "sub_experiment_id":[ + "none" + ] }, "ssp126":{ "activity_id":[ @@ -7274,11 +8362,8 @@ "CHEM", "BGC" ], - "description":"Future scenario with low radiative forcing by the end of century. Following approximately RCP2.6 global forcing pathway but with new forcing based on SSP1. Concentration-driven. As a tier 2 option, this simulation should be extended to year 2300", - "end_year":"2100 or 2300", "experiment":"update of RCP2.6 based on SSP1", "experiment_id":"ssp126", - "min_number_yrs_per_sim":"86", "parent_activity_id":[ "CMIP" ], @@ -7288,11 +8373,9 @@ "required_model_components":[ "AOGCM" ], - "start_year":"2015", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, "ssp126-ssp370Lu":{ "activity_id":[ @@ -7303,11 +8386,8 @@ "CHEM", "BGC" ], - "description":"Additional land use policy sensitivity simulation for low radiative forcing scenario, keep all forcings the same as ScenarioMIP SSP1-2.6 (afforestation scenario), but replace land use from SSP3-7 (afforestation) scenario; concentration-driven", - "end_year":"2100", "experiment":"SSP1-2.6 with SSP3-7.0 land use", "experiment_id":"ssp126-ssp370Lu", - "min_number_yrs_per_sim":"86", "parent_activity_id":[ "CMIP" ], @@ -7317,11 +8397,9 @@ "required_model_components":[ "AOGCM" ], - "start_year":"2015", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, "ssp245":{ "activity_id":[ @@ -7332,11 +8410,8 @@ "CHEM", "BGC" ], - "description":"Future scenario with medium radiative forcing by the end of century. Following approximately RCP4.5 global forcing pathway but with new forcing based on SSP2. Concentration-driven", - "end_year":"2100", "experiment":"update of RCP4.5 based on SSP2", "experiment_id":"ssp245", - "min_number_yrs_per_sim":"86", "parent_activity_id":[ "CMIP" ], @@ -7346,11 +8421,9 @@ "required_model_components":[ "AOGCM" ], - "start_year":"2015", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, "ssp245-GHG":{ "activity_id":[ @@ -7361,11 +8434,8 @@ "CHEM", "BGC" ], - "description":"Extension of well-mixed GHG-only run under SSP2-4.5. Models with interactive chemistry schemes should either turn off the chemistry or use a preindustrial climatology of stratospheric and tropospheric ozone in their radiation schemes", - "end_year":"2100", "experiment":"well-mixed GHG-only SSP2-4.5 run", "experiment_id":"ssp245-GHG", - "min_number_yrs_per_sim":"80", "parent_activity_id":[ "DAMIP" ], @@ -7375,11 +8445,9 @@ "required_model_components":[ "AOGCM" ], - "start_year":"2021", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, "ssp245-aer":{ "activity_id":[ @@ -7390,11 +8458,8 @@ "CHEM", "BGC" ], - "description":"Extension of aerosol-only run under SSP2-4.5", - "end_year":"2100", "experiment":"aerosol-only SSP2-4.5 run", "experiment_id":"ssp245-aer", - "min_number_yrs_per_sim":"80", "parent_activity_id":[ "DAMIP" ], @@ -7404,11 +8469,9 @@ "required_model_components":[ "AOGCM" ], - "start_year":"2021", "sub_experiment_id":[ "none" - ], - "tier":"3" + ] }, "ssp245-nat":{ "activity_id":[ @@ -7419,11 +8482,8 @@ "CHEM", "BGC" ], - "description":"Extension of natural-only run under SSP2-4.5", - "end_year":"2100", "experiment":"natural-only SSP2-4.5 run", "experiment_id":"ssp245-nat", - "min_number_yrs_per_sim":"80", "parent_activity_id":[ "DAMIP" ], @@ -7433,11 +8493,9 @@ "required_model_components":[ "AOGCM" ], - "start_year":"2021", "sub_experiment_id":[ "none" - ], - "tier":"3" + ] }, "ssp245-stratO3":{ "activity_id":[ @@ -7447,11 +8505,8 @@ "AER", "BGC" ], - "description":"Extension of stratospheric-ozone-only run under SSP2-4.5. In models with coupled chemistry, the chemistry scheme should be turned off, and the simulated ensemble mean monthly mean 3D stratospheric ozone concentrations from the SSP2-4.5 simulations should be prescribed. Tropospheric ozone should be fixed at 3D long-term monthly mean piControl values, with a value of 100 ppbv ozone concentration in this piControl climatology used to separate the troposphere from the stratosphere. In models without coupled chemistry the same stratospheric ozone prescribed in SSP2-4.5 should be prescribed. Stratospheric ozone concentrations will be provided by CCMI", - "end_year":"2100", "experiment":"stratospheric-ozone-only SSP2-4.5 run", "experiment_id":"ssp245-stratO3", - "min_number_yrs_per_sim":"80", "parent_activity_id":[ "DAMIP" ], @@ -7461,27 +8516,21 @@ "required_model_components":[ "AOGCM" ], - "start_year":"2021", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, "ssp370":{ "activity_id":[ - "ScenarioMIP", - "AerChemMIP" + "ScenarioMIP AerChemMIP" ], "additional_allowed_model_components":[ "AER", "CHEM", "BGC" ], - "description":"Future scenario with high radiative forcing by the end of century. Reaches about 7.0 W/m2 by 2100; fills gap in RCP forcing pathways between 6.0 and 8.5 W/m2. Concentration-driven", - "end_year":"2100", "experiment":"gap-filling scenario reaching 7.0 based on SSP3", "experiment_id":"ssp370", - "min_number_yrs_per_sim":"86", "parent_activity_id":[ "CMIP" ], @@ -7491,11 +8540,9 @@ "required_model_components":[ "AOGCM" ], - "start_year":"2015", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, "ssp370-lowNTCF":{ "activity_id":[ @@ -7505,11 +8552,8 @@ "CHEM", "BGC" ], - "description":"Future SSP3-7.0 with reduced NTCF emissions", - "end_year":"2055", "experiment":"SSP3-7.0, with low NTCF emissions", "experiment_id":"ssp370-lowNTCF", - "min_number_yrs_per_sim":"41", "parent_activity_id":[ "CMIP" ], @@ -7520,11 +8564,9 @@ "AOGCM", "AER" ], - "start_year":"2015", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, "ssp370-ssp126Lu":{ "activity_id":[ @@ -7535,11 +8577,8 @@ "CHEM", "BGC" ], - "description":"Additional land use policy sensitivity simulation for high radiative forcing scenario, keep all forcings the same as ScenarioMIP SSP3-7 (deforestation scenario), but replace land use from SSP1-2.6 (afforestation) scenario; concentration-driven", - "end_year":"2100", "experiment":"SSP3-7.0 with SSP1-2.6 land use", "experiment_id":"ssp370-ssp126Lu", - "min_number_yrs_per_sim":"86", "parent_activity_id":[ "CMIP" ], @@ -7549,24 +8588,20 @@ "required_model_components":[ "AOGCM" ], - "start_year":"2015", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, "ssp370SST":{ "activity_id":[ "AerChemMIP" ], "additional_allowed_model_components":[ - "CHEM" + "CHEM", + "BGC" ], - "description":"Future SSP3-7.0, with SSTs prescribed from ssp370", - "end_year":"2055", "experiment":"SSP3-7.0, with SSTs prescribed from ssp370", "experiment_id":"ssp370SST", - "min_number_yrs_per_sim":"41", "parent_activity_id":[ "ScenarioMIP" ], @@ -7577,24 +8612,20 @@ "AGCM", "AER" ], - "start_year":"2015", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, "ssp370SST-lowAer":{ "activity_id":[ "AerChemMIP" ], "additional_allowed_model_components":[ - "CHEM" + "CHEM", + "BGC" ], - "description":"Future SSP3-7.0 with reduced aerosol emissions (from ssp370-lowNTCF), prescribed SSTs", - "end_year":"2055", "experiment":"SSP3-7.0, prescribed SSTs, with low aerosol emissions", "experiment_id":"ssp370SST-lowAer", - "min_number_yrs_per_sim":"41", "parent_activity_id":[ "ScenarioMIP" ], @@ -7605,24 +8636,20 @@ "AGCM", "AER" ], - "start_year":"2015", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, "ssp370SST-lowBC":{ "activity_id":[ "AerChemMIP" ], "additional_allowed_model_components":[ - "CHEM" + "CHEM", + "BGC" ], - "description":"Future SSP3-7.0 with reduced black carbon emissions, prescribed SSTs", - "end_year":"2055", "experiment":"SSP3-7.0, prescribed SSTs, with low black carbon emissions", "experiment_id":"ssp370SST-lowBC", - "min_number_yrs_per_sim":"41", "parent_activity_id":[ "ScenarioMIP" ], @@ -7633,22 +8660,19 @@ "AGCM", "AER" ], - "start_year":"2015", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, "ssp370SST-lowCH4":{ "activity_id":[ "AerChemMIP" ], - "additional_allowed_model_components":"", - "description":"Future SSP3-7.0 with reduced CH4 concentrations, prescribed SSTs", - "end_year":"2055", + "additional_allowed_model_components":[ + "BGC" + ], "experiment":"SSP3-7.0, prescribed SSTs, with low methane concentrations", "experiment_id":"ssp370SST-lowCH4", - "min_number_yrs_per_sim":"41", "parent_activity_id":[ "ScenarioMIP" ], @@ -7660,11 +8684,9 @@ "AER", "CHEM" ], - "start_year":"2015", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, "ssp370SST-lowNTCF":{ "activity_id":[ @@ -7674,11 +8696,8 @@ "CHEM", "BGC" ], - "description":"Future SSP3-7.0 with reduced NTCF emissions, prescribed SSTs", - "end_year":"2055", "experiment":"SSP3-7.0, prescribed SSTs, with low NTCF emissions", "experiment_id":"ssp370SST-lowNTCF", - "min_number_yrs_per_sim":"41", "parent_activity_id":[ "ScenarioMIP" ], @@ -7689,22 +8708,19 @@ "AGCM", "AER" ], - "start_year":"2015", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, "ssp370SST-lowO3":{ "activity_id":[ "AerChemMIP" ], - "additional_allowed_model_components":"", - "description":"Future SSP3-7.0 with reduced ozone precursor emissions (from ssp370-lowNTCF), prescribed SSTs", - "end_year":"2055", + "additional_allowed_model_components":[ + "BGC" + ], "experiment":"SSP3-7.0, prescribed SSTs, with low ozone precursor emissions", "experiment_id":"ssp370SST-lowO3", - "min_number_yrs_per_sim":"41", "parent_activity_id":[ "ScenarioMIP" ], @@ -7716,24 +8732,20 @@ "AER", "CHEM" ], - "start_year":"2015", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, "ssp370SST-ssp126Lu":{ "activity_id":[ "AerChemMIP" ], "additional_allowed_model_components":[ - "CHEM" + "CHEM", + "BGC" ], - "description":"Future SSP3-7.0 with low land use change (from ssp126), prescribed SSTs", - "end_year":"2055", "experiment":"SSP3-7.0, prescribed SSTs, with SSP1-2.6 land use", "experiment_id":"ssp370SST-ssp126Lu", - "min_number_yrs_per_sim":"41", "parent_activity_id":[ "ScenarioMIP" ], @@ -7744,11 +8756,9 @@ "AGCM", "AER" ], - "start_year":"2015", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, "ssp434":{ "activity_id":[ @@ -7759,11 +8769,8 @@ "CHEM", "BGC" ], - "description":"Future scenario with low radiative forcing by the end of century. Reaches about 3.4 W/m2 by 2100; fills gap in RCP forcing pathways between 4.5 and 2.6 W/m2. Concentration-driven", - "end_year":"2100", "experiment":"gap-filling scenario reaching 3.4 based on SSP4", "experiment_id":"ssp434", - "min_number_yrs_per_sim":"86", "parent_activity_id":[ "CMIP" ], @@ -7773,11 +8780,9 @@ "required_model_components":[ "AOGCM" ], - "start_year":"2015", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, "ssp460":{ "activity_id":[ @@ -7788,11 +8793,8 @@ "CHEM", "BGC" ], - "description":"Future scenario with medium radiative forcing by the end of century. Following approximately RCP6.0 global forcing pathway but with new forcing based on SSP4. Concentration-driven", - "end_year":"2100", "experiment":"update of RCP6.0 based on SSP4", "experiment_id":"ssp460", - "min_number_yrs_per_sim":"86", "parent_activity_id":[ "CMIP" ], @@ -7802,11 +8804,9 @@ "required_model_components":[ "AOGCM" ], - "start_year":"2015", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, "ssp534-over":{ "activity_id":[ @@ -7817,11 +8817,8 @@ "CHEM", "BGC" ], - "description":"21st century overshoot scenario relative to SSP5_34. Branches from SS5_85 at 2040 with emissions reduced to zero by 2070 and negative thereafter. This simulation should optionally be extended to year 2300", - "end_year":"2100 or 2300", "experiment":"overshoot of 3.4 W/m**2 branching from ssp585 in 2040", "experiment_id":"ssp534-over", - "min_number_yrs_per_sim":"61", "parent_activity_id":[ "ScenarioMIP" ], @@ -7831,11 +8828,9 @@ "required_model_components":[ "AOGCM" ], - "start_year":"2040", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, "ssp534-over-bgc":{ "activity_id":[ @@ -7845,11 +8840,8 @@ "AER", "CHEM" ], - "description":"This simulation should optionally be extended to year 2300", - "end_year":"2100 or 2300", "experiment":"biogeochemically-coupled version of the RCP3.4-overshoot based on SSP5", "experiment_id":"ssp534-over-bgc", - "min_number_yrs_per_sim":"85", "parent_activity_id":[ "C4MIP" ], @@ -7860,11 +8852,9 @@ "AOGCM", "BGC" ], - "start_year":"2015", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, "ssp585":{ "activity_id":[ @@ -7875,11 +8865,8 @@ "CHEM", "BGC" ], - "description":"Future scenario with high radiative forcing by the end of century. Following approximately RCP8.5 global forcing pathway but with new forcing based on SSP5. Concentration-driven. As a tier 2 option, this simulation should be extended to year 2300", - "end_year":"2100 or 2300", "experiment":"update of RCP8.5 based on SSP5", "experiment_id":"ssp585", - "min_number_yrs_per_sim":"86", "parent_activity_id":[ "CMIP" ], @@ -7889,11 +8876,9 @@ "required_model_components":[ "AOGCM" ], - "start_year":"2015", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, "ssp585-bgc":{ "activity_id":[ @@ -7903,11 +8888,8 @@ "AER", "CHEM" ], - "description":"Concentration-driven future scenario simulation, biogeochemically-coupled. This simulation should optionally be extended to year 2300", - "end_year":"2100 or 2300", "experiment":"biogeochemically-coupled version of the RCP8.5 based on SSP5", "experiment_id":"ssp585-bgc", - "min_number_yrs_per_sim":"85", "parent_activity_id":[ "C4MIP" ], @@ -7918,11 +8900,9 @@ "AOGCM", "BGC" ], - "start_year":"2015", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, "ssp585-withism":{ "activity_id":[ @@ -7933,11 +8913,8 @@ "CHEM", "BGC" ], - "description":"Future climate from ScenarioMIP SSP5-8.5 simulation that includes interactive ice sheets. Set up follows the standard SSP5-8.5 experiment", - "end_year":"2300", "experiment":"ssp585 with interactive ice sheet", "experiment_id":"ssp585-withism", - "min_number_yrs_per_sim":"85", "parent_activity_id":[ "ISMIP6" ], @@ -7948,40 +8925,9 @@ "AOGCM", "ISM" ], - "start_year":"2015", - "sub_experiment_id":[ - "none" - ], - "tier":"2" - }, - "sspxy":{ - "activity_id":[ - "ScenarioMIP" - ], - "additional_allowed_model_components":[ - "AER", - "CHEM", - "BGC" - ], - "description":"Future scenario with low radiative forcing by the end of century. Following a forcing pathway below RCP2.6. Specific SSP and 2100 forcing level to be finalized with IAM groups within next few months. Concentration-driven", - "end_year":"2100", - "experiment":"low-end scenario informing 1.5C goal", - "experiment_id":"sspxy", - "min_number_yrs_per_sim":"86", - "parent_activity_id":[ - "CMIP" - ], - "parent_experiment_id":[ - "historical" - ], - "required_model_components":[ - "AOGCM" - ], - "start_year":"2015", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, "volc-cluster-21C":{ "activity_id":[ @@ -7992,11 +8938,8 @@ "CHEM", "BGC" ], - "description":"Parallel experiment to volc-cluster-ctrl, using restart files from the end of the historical simulation instead of from piControl, and boundary conditions from the 21st century SSP2-4.5 scenario experiment of ScenarioMIP", - "end_year":"2100", "experiment":"volcanic cluster experiment under 21st century SSP2-4.5 scenario", "experiment_id":"volc-cluster-21C", - "min_number_yrs_per_sim":"85", "parent_activity_id":[ "CMIP" ], @@ -8006,11 +8949,9 @@ "required_model_components":[ "AOGCM" ], - "start_year":"2015", "sub_experiment_id":[ "none" - ], - "tier":"3" + ] }, "volc-cluster-ctrl":{ "activity_id":[ @@ -8021,11 +8962,8 @@ "CHEM", "BGC" ], - "description":"Early 19th century cluster of strong tropical volcanic eruptions, including the 1809 event of unknown location, the 1815 Tambora and 1835 Cosigueina eruptions. Experiment initialized from PiControl", - "end_year":"", "experiment":"19th century volcanic cluster initialized from PiControl", "experiment_id":"volc-cluster-ctrl", - "min_number_yrs_per_sim":"50", "parent_activity_id":[ "CMIP" ], @@ -8035,11 +8973,9 @@ "required_model_components":[ "AOGCM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, "volc-cluster-mill":{ "activity_id":[ @@ -8050,11 +8986,8 @@ "CHEM", "BGC" ], - "description":"Parallel experiment to volc-cluster-ctrl but with initial conditions taken from last millennium simulation to account for the effects of a more realistic history of past natural forcing. All forcings except volcanic kept constant from year AD 1790 on", - "end_year":"1858", "experiment":"19th century volcanic cluster initialized from past1000", "experiment_id":"volc-cluster-mill", - "min_number_yrs_per_sim":"69", "parent_activity_id":[ "PMIP" ], @@ -8064,11 +8997,9 @@ "required_model_components":[ "AOGCM" ], - "start_year":"1790", "sub_experiment_id":[ "none" - ], - "tier":"3" + ] }, "volc-long-eq":{ "activity_id":[ @@ -8079,11 +9010,8 @@ "CHEM", "BGC" ], - "description":"Idealized equatorial eruption corresponding to an initial emission of 56.2 Tg of SO2. The eruption magnitude corresponds to recent estimates for the 1815 Tambora eruption (Sigl et al., 2015), the largest historical tropical eruption, which was linked to the so-called \"year without a summer\" in 1816. Experiment initialized from PiControl", - "end_year":"", "experiment":"idealized equatorial volcanic eruption emitting 56.2 Tg SO2", "experiment_id":"volc-long-eq", - "min_number_yrs_per_sim":"20", "parent_activity_id":[ "CMIP" ], @@ -8093,11 +9021,9 @@ "required_model_components":[ "AOGCM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, "volc-long-hlN":{ "activity_id":[ @@ -8108,11 +9034,8 @@ "CHEM", "BGC" ], - "description":"Idealized Northern Hemisphere high-latitude eruption emitting 28.1 Tg of SO2. Experiment initialized from PiControl", - "end_year":"", "experiment":"idealized Northern Hemisphere high-latitude eruption emitting 28.1 Tg of SO2", "experiment_id":"volc-long-hlN", - "min_number_yrs_per_sim":"20", "parent_activity_id":[ "CMIP" ], @@ -8122,11 +9045,9 @@ "required_model_components":[ "AOGCM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"2" + ] }, "volc-long-hlS":{ "activity_id":[ @@ -8137,11 +9058,8 @@ "CHEM", "BGC" ], - "description":"Idealized Southern Hemisphere high-latitude eruption emitting 28.1 Tg of SO2. Experiment initialized from PiControl", - "end_year":"", "experiment":"Idealized Southern Hemisphere high-latitude eruption emitting 28.1 Tg of SO2", "experiment_id":"volc-long-hlS", - "min_number_yrs_per_sim":"20", "parent_activity_id":[ "CMIP" ], @@ -8151,11 +9069,9 @@ "required_model_components":[ "AOGCM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"3" + ] }, "volc-pinatubo-full":{ "activity_id":[ @@ -8166,11 +9082,8 @@ "CHEM", "BGC" ], - "description":"1991 Pinatubo forcing as used in the CMIP6 historical simulations. Requires special diagnostics of radiative and latent heating rates. A large number of ensemble members is required to address internal atmospheric variability", - "end_year":"", "experiment":"Pinatubo experiment", "experiment_id":"volc-pinatubo-full", - "min_number_yrs_per_sim":"3", "parent_activity_id":[ "CMIP" ], @@ -8180,11 +9093,9 @@ "required_model_components":[ "AOGCM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, "volc-pinatubo-slab":{ "activity_id":[ @@ -8195,11 +9106,8 @@ "CHEM", "BGC" ], - "description":"As volc-pinatubo-full, but with a slab ocean", - "end_year":"", "experiment":"Pinatubo experiment with slab ocean", "experiment_id":"volc-pinatubo-slab", - "min_number_yrs_per_sim":"3", "parent_activity_id":[ "VolMIP" ], @@ -8210,11 +9118,9 @@ "AGCM", "SLAB" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"3" + ] }, "volc-pinatubo-strat":{ "activity_id":[ @@ -8225,11 +9131,8 @@ "CHEM", "BGC" ], - "description":"As volc-pinatubo-full, but with prescribed perturbation to the total (LW+SW) radiative heating rates", - "end_year":"", "experiment":"Pinatubo experiment with partial radiative forcing, includes only stratospheric warming", "experiment_id":"volc-pinatubo-strat", - "min_number_yrs_per_sim":"3", "parent_activity_id":[ "CMIP" ], @@ -8239,11 +9142,9 @@ "required_model_components":[ "AOGCM" ], - "start_year":"", "sub_experiment_id":[ "none" - ], - "tier":"1" + ] }, "volc-pinatubo-surf":{ "activity_id":[ @@ -8254,11 +9155,8 @@ "CHEM", "BGC" ], - "description":"As volc-pinatubo-full, but with prescribed perturbation to the shortwave flux to mimic the attenuation of solar radiation by volcanic aerosols", - "end_year":"", "experiment":"Pinatubo experiment with partial radiative forcing, solar radiation scattering only", "experiment_id":"volc-pinatubo-surf", - "min_number_yrs_per_sim":"3", "parent_activity_id":[ "CMIP" ], @@ -8268,11 +9166,33 @@ "required_model_components":[ "AOGCM" ], - "start_year":"", "sub_experiment_id":[ "none" + ] + }, + "yr2010CO2":{ + "activity_id":[ + "CDRMIP" ], - "tier":"1" + "additional_allowed_model_components":[ + "AER", + "CHEM" + ], + "experiment":"concentration-driven fixed 2010 forcing", + "experiment_id":"yr2010CO2", + "parent_activity_id":[ + "CMIP" + ], + "parent_experiment_id":[ + "historical" + ], + "required_model_components":[ + "AOGCM", + "BGC" + ], + "sub_experiment_id":[ + "none" + ] } }, "product":[ @@ -8282,7 +9202,7 @@ "hdl:21.14100/.*" ], "further_info_url":[ - "http://furtherinfo.es-doc.org/[[:alpha:]]\\{1,\\}" + "https://furtherinfo.es-doc.org/.*" ], "realization_index":[ "^\\[\\{0,\\}[[:digit:]]\\{1,\\}\\]\\{0,\\}$" @@ -8294,7 +9214,7 @@ "^[[:digit:]]\\{2,2\\}\\.[[:digit:]]\\{2,2\\}\\.[[:digit:]]\\{2,2\\}$" ], "Conventions":[ - "^CF-1.7 CMIP-6.0\\( UGRID-1.0\\)\\{0,\\}$" + "^CF-1.7 CMIP-6.[0-2]\\( UGRID-1.0\\)\\{0,\\}$" ], "forcing_index":[ "^\\[\\{0,\\}[[:digit:]]\\{1,\\}\\]\\{0,\\}$" diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_E1hr.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_E1hr.json index 86003a9d9d..8f32f30f5f 100644 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_E1hr.json +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_E1hr.json @@ -1,20 +1,21 @@ { "Header": { - "data_specs_version": "01.00.10", + "data_specs_version": "01.00.30", + "cmor_version": "3.4", "table_id": "Table E1hr", "realm": "atmos", - "frequency": "1hr", - "cmor_version": "3.2", - "table_date": "10 May 2017", + "table_date": "11 March 2019", "missing_value": "1e20", + "int_missing_value": "-999", "product": "model-output", - "approx_interval": "0.017361", + "approx_interval": "0.041667", "generic_levels": "", "mip_era": "CMIP6", - "Conventions": "CF-1.7 CMIP-6.0" + "Conventions": "CF-1.7 CMIP-6.2" }, "variable_entry": { "pr": { + "frequency": "1hr", "modeling_realm": "atmos", "standard_name": "precipitation_flux", "units": "kg m-2 s-1", @@ -24,7 +25,7 @@ "comment": "includes both liquid and solid phases", "dimensions": "longitude latitude time", "out_name": "pr", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -32,6 +33,7 @@ "ok_max_mean_abs": "" }, "prc": { + "frequency": "1hr", "modeling_realm": "atmos", "standard_name": "convective_precipitation_flux", "units": "kg m-2 s-1", @@ -49,8 +51,9 @@ "ok_max_mean_abs": "" }, "psl": { + "frequency": "1hrPt", "modeling_realm": "atmos", - "standard_name": "air_pressure_at_sea_level", + "standard_name": "air_pressure_at_mean_sea_level", "units": "Pa", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", @@ -66,16 +69,17 @@ "ok_max_mean_abs": "" }, "rlut": { + "frequency": "1hrPt", "modeling_realm": "atmos", "standard_name": "toa_outgoing_longwave_flux", "units": "W m-2", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "TOA Outgoing Longwave Radiatio", + "long_name": "TOA Outgoing Longwave Radiation", "comment": "at the top of the atmosphere (to be compared with satellite measurements)", "dimensions": "longitude latitude time1", "out_name": "rlut", - "type": "", + "type": "real", "positive": "up", "valid_min": "", "valid_max": "", @@ -83,6 +87,7 @@ "ok_max_mean_abs": "" }, "ta": { + "frequency": "1hrPt", "modeling_realm": "atmos", "standard_name": "air_temperature", "units": "K", @@ -92,7 +97,7 @@ "comment": "Air Temperature", "dimensions": "longitude latitude plev3 time1", "out_name": "ta", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -100,6 +105,7 @@ "ok_max_mean_abs": "" }, "ta27": { + "frequency": "1hrPt", "modeling_realm": "atmos", "standard_name": "air_temperature", "units": "K", @@ -109,7 +115,7 @@ "comment": "Air Temperature", "dimensions": "longitude latitude plev27 time1", "out_name": "ta", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -117,12 +123,13 @@ "ok_max_mean_abs": "" }, "tntr27": { + "frequency": "1hrPt", "modeling_realm": "atmos", "standard_name": "tendency_of_air_temperature_due_to_radiative_heating", "units": "K s-1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "Tendency of Air Temperature due to Radiative Heating", + "long_name": "Tendency of Air Temperature Due to Radiative Heating", "comment": "Tendency of Air Temperature due to Radiative Heating", "dimensions": "longitude latitude plev27 time1", "out_name": "tntr", @@ -134,16 +141,17 @@ "ok_max_mean_abs": "" }, "ua": { + "frequency": "1hrPt", "modeling_realm": "atmos", "standard_name": "eastward_wind", "units": "m s-1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", "long_name": "Eastward Wind", - "comment": "", + "comment": "Zonal wind (positive in a eastward direction).", "dimensions": "longitude latitude plev3 time1", "out_name": "ua", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -151,16 +159,17 @@ "ok_max_mean_abs": "" }, "ua27": { + "frequency": "1hrPt", "modeling_realm": "atmos", "standard_name": "eastward_wind", "units": "m s-1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", "long_name": "Eastward Wind", - "comment": "", + "comment": "Zonal wind (positive in a eastward direction).", "dimensions": "longitude latitude plev27 time1", "out_name": "ua", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -168,16 +177,17 @@ "ok_max_mean_abs": "" }, "utendnogw27": { + "frequency": "1hrPt", "modeling_realm": "atmos", "standard_name": "tendency_of_eastward_wind_due_to_nonorographic_gravity_wave_drag", "units": "m s-2", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "u-tendency nonorographic gravity wave drag", + "long_name": "Eastward Acceleration Due to Non-Orographic Gravity Wave Drag", "comment": "Tendency of the eastward wind by parameterized nonorographic gravity waves.", "dimensions": "longitude latitude plev27 time1", "out_name": "utendnogw", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -185,16 +195,17 @@ "ok_max_mean_abs": "" }, "va": { + "frequency": "1hrPt", "modeling_realm": "atmos", "standard_name": "northward_wind", "units": "m s-1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", "long_name": "Northward Wind", - "comment": "", + "comment": "Meridional wind (positive in a northward direction).", "dimensions": "longitude latitude plev3 time1", "out_name": "va", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -202,16 +213,17 @@ "ok_max_mean_abs": "" }, "va27": { + "frequency": "1hrPt", "modeling_realm": "atmos", "standard_name": "northward_wind", "units": "m s-1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", "long_name": "Northward Wind", - "comment": "", + "comment": "Meridional wind (positive in a northward direction).", "dimensions": "longitude latitude plev27 time1", "out_name": "va", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -219,16 +231,17 @@ "ok_max_mean_abs": "" }, "vtendnogw27": { + "frequency": "1hrPt", "modeling_realm": "atmos", "standard_name": "tendency_of_northward_wind_due_to_nonorographic_gravity_wave_drag", "units": "m s-2", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "v-tendency nonorographic gravity wave drag", + "long_name": "Northward Acceleration Due to Non-Orographic Gravity Wave Drag", "comment": "Tendency of the northward wind by parameterized nonorographic gravity waves. (Note that CF name tables only have a general northward tendency for all gravity waves, and we need it separated by type.)", "dimensions": "longitude latitude plev27 time1", "out_name": "vtendnogw", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -236,12 +249,13 @@ "ok_max_mean_abs": "" }, "wap": { + "frequency": "1hrPt", "modeling_realm": "atmos", "standard_name": "lagrangian_tendency_of_air_pressure", "units": "Pa s-1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "omega (=dp/dt)", + "long_name": "Omega (=dp/dt)", "comment": "Omega (vertical velocity in pressure coordinates, positive downwards)", "dimensions": "longitude latitude plev3 time1", "out_name": "wap", @@ -253,12 +267,13 @@ "ok_max_mean_abs": "" }, "wap27": { + "frequency": "1hrPt", "modeling_realm": "atmos", "standard_name": "lagrangian_tendency_of_air_pressure", "units": "Pa s-1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "omega (=dp/dt)", + "long_name": "Omega (=dp/dt)", "comment": "Omega (vertical velocity in pressure coordinates, positive downwards)", "dimensions": "longitude latitude plev27 time1", "out_name": "wap", @@ -270,16 +285,17 @@ "ok_max_mean_abs": "" }, "zg27": { + "frequency": "1hrPt", "modeling_realm": "atmos", "standard_name": "geopotential_height", "units": "m", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", "long_name": "Geopotential Height", - "comment": "", + "comment": "Geopotential is the sum of the specific gravitational potential energy relative to the geoid and the specific centripetal potential energy. Geopotential height is the geopotential divided by the standard acceleration due to gravity. It is numerically similar to the altitude (or geometric height) and not to the quantity with standard name height, which is relative to the surface.", "dimensions": "longitude latitude plev27 time1", "out_name": "zg", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_E1hrClimMon.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_E1hrClimMon.json index bcc0180038..ed61cb38fd 100644 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_E1hrClimMon.json +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_E1hrClimMon.json @@ -1,30 +1,31 @@ { "Header": { - "data_specs_version": "01.00.10", + "data_specs_version": "01.00.30", + "cmor_version": "3.4", "table_id": "Table E1hrClimMon", "realm": "atmos", - "frequency": "1hrClimMon", - "cmor_version": "3.2", - "table_date": "10 May 2017", + "table_date": "11 March 2019", "missing_value": "1e20", + "int_missing_value": "-999", "product": "model-output", - "approx_interval": "0.017361", + "approx_interval": "0.041667", "generic_levels": "", "mip_era": "CMIP6", - "Conventions": "CF-1.7 CMIP-6.0" + "Conventions": "CF-1.7 CMIP-6.2" }, "variable_entry": { "rlut": { + "frequency": "1hrCM", "modeling_realm": "atmos", "standard_name": "toa_outgoing_longwave_flux", "units": "W m-2", "cell_methods": "area: mean time: mean within days time: mean over days", "cell_measures": "area: areacella", - "long_name": "TOA Outgoing Longwave Radiatio", + "long_name": "TOA Outgoing Longwave Radiation", "comment": "at the top of the atmosphere (to be compared with satellite measurements)", "dimensions": "longitude latitude time3", "out_name": "rlut", - "type": "", + "type": "real", "positive": "up", "valid_min": "", "valid_max": "", @@ -32,16 +33,17 @@ "ok_max_mean_abs": "" }, "rlutcs": { + "frequency": "1hrCM", "modeling_realm": "atmos", "standard_name": "toa_outgoing_longwave_flux_assuming_clear_sky", "units": "W m-2", "cell_methods": "area: mean time: mean within days time: mean over days", "cell_measures": "area: areacella", - "long_name": "TOA Outgoing Clear-sky Longwave Radiation", - "comment": "", + "long_name": "TOA Outgoing Clear-Sky Longwave Radiation", + "comment": "Upwelling clear-sky longwave radiation at top of atmosphere", "dimensions": "longitude latitude time3", "out_name": "rlutcs", - "type": "", + "type": "real", "positive": "up", "valid_min": "", "valid_max": "", @@ -49,6 +51,7 @@ "ok_max_mean_abs": "" }, "rsdt": { + "frequency": "1hrCM", "modeling_realm": "atmos", "standard_name": "toa_incoming_shortwave_flux", "units": "W m-2", @@ -66,16 +69,17 @@ "ok_max_mean_abs": "" }, "rsut": { + "frequency": "1hrCM", "modeling_realm": "atmos", "standard_name": "toa_outgoing_shortwave_flux", "units": "W m-2", "cell_methods": "area: mean time: mean within days time: mean over days", "cell_measures": "area: areacella", - "long_name": "Top-of-Atmosphere Outgoing Shortwave Radiation", + "long_name": "TOA Outgoing Shortwave Radiation", "comment": "at the top of the atmosphere", "dimensions": "longitude latitude time3", "out_name": "rsut", - "type": "", + "type": "real", "positive": "up", "valid_min": "", "valid_max": "", @@ -83,6 +87,7 @@ "ok_max_mean_abs": "" }, "rsutcs": { + "frequency": "1hrCM", "modeling_realm": "atmos", "standard_name": "toa_outgoing_shortwave_flux_assuming_clear_sky", "units": "W m-2", @@ -92,7 +97,7 @@ "comment": "Calculated in the absence of clouds.", "dimensions": "longitude latitude time3", "out_name": "rsutcs", - "type": "", + "type": "real", "positive": "up", "valid_min": "", "valid_max": "", diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_E3hr.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_E3hr.json index 9c418f0829..74dcc10f29 100644 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_E3hr.json +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_E3hr.json @@ -1,39 +1,23 @@ { "Header": { - "data_specs_version": "01.00.10", + "data_specs_version": "01.00.30", + "cmor_version": "3.4", "table_id": "Table E3hr", - "realm": "atmos", - "frequency": "3hr", - "cmor_version": "3.2", - "table_date": "10 May 2017", + "realm": "land", + "table_date": "11 March 2019", "missing_value": "1e20", + "int_missing_value": "-999", "product": "model-output", "approx_interval": "0.125000", - "generic_levels": "alevel", + "generic_levels": "alevel alevhalf", "mip_era": "CMIP6", - "Conventions": "CF-1.7 CMIP-6.0" + "Conventions": "CF-1.7 CMIP-6.2" }, "variable_entry": { - "clisccp": { - "modeling_realm": "atmos", - "standard_name": "cloud_area_fraction_in_atmosphere_layer", - "units": "%", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "ISCCP Percentage Cloud Area", - "comment": "Percentage cloud cover in optical depth categories.", - "dimensions": "longitude latitude plev7c tau time", - "out_name": "clisccp", - "type": "real", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, "clivi": { + "frequency": "3hr", "modeling_realm": "atmos", - "standard_name": "atmosphere_cloud_ice_content", + "standard_name": "atmosphere_mass_content_of_cloud_ice", "units": "kg m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", @@ -41,7 +25,7 @@ "comment": "mass of ice water in the column divided by the area of the column (not just the area of the cloudy portion of the column). Includes precipitating frozen hydrometeors ONLY if the precipitating hydrometeor affects the calculation of radiative transfer in model.", "dimensions": "longitude latitude time", "out_name": "clivi", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -49,8 +33,9 @@ "ok_max_mean_abs": "" }, "clwvi": { + "frequency": "3hr", "modeling_realm": "atmos", - "standard_name": "atmosphere_cloud_condensed_water_content", + "standard_name": "atmosphere_mass_content_of_cloud_condensed_water", "units": "kg m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", @@ -66,25 +51,27 @@ "ok_max_mean_abs": "" }, "gpp": { + "frequency": "3hr", "modeling_realm": "land", "standard_name": "gross_primary_productivity_of_biomass_expressed_as_carbon", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Carbon Mass Flux out of Atmosphere due to Gross Primary Production on Land", - "comment": "", + "long_name": "Carbon Mass Flux out of Atmosphere Due to Gross Primary Production on Land", + "comment": "The rate of synthesis of biomass from inorganic precursors by autotrophs ('producers') expressed as the mass of carbon which it contains. For example, photosynthesis in plants or phytoplankton. The producers also respire some of this biomass and the difference is referred to as the net primary production. ", "dimensions": "longitude latitude time", "out_name": "gpp", "type": "real", - "positive": "down", + "positive": "", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "prcsh": { + "frequency": "3hr", "modeling_realm": "atmos", - "standard_name": "hallow_convective_precipitation_flux", + "standard_name": "shallow_convective_precipitation_flux", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", @@ -92,7 +79,7 @@ "comment": "Convection precipitation from shallow convection", "dimensions": "longitude latitude time", "out_name": "prcsh", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -100,13 +87,14 @@ "ok_max_mean_abs": "" }, "prra": { + "frequency": "3hr", "modeling_realm": "atmos", "standard_name": "rainfall_flux", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Rainfall Flux where Ice Free Ocean over Sea", - "comment": "", + "long_name": "Rainfall Flux", + "comment": "In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions": "longitude latitude time", "out_name": "prra", "type": "real", @@ -117,16 +105,17 @@ "ok_max_mean_abs": "" }, "prrc": { + "frequency": "3hr", "modeling_realm": "atmos", "standard_name": "convective_rainfall_flux", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Convective Rainfall rate", - "comment": "", + "long_name": "Convective Rainfall Rate", + "comment": "In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions": "longitude latitude time", "out_name": "prrc", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -134,6 +123,7 @@ "ok_max_mean_abs": "" }, "prsnc": { + "frequency": "3hr", "modeling_realm": "atmos", "standard_name": "convective_snowfall_flux", "units": "kg m-2 s-1", @@ -151,8 +141,9 @@ "ok_max_mean_abs": "" }, "prw": { + "frequency": "3hr", "modeling_realm": "atmos", - "standard_name": "atmosphere_water_vapor_content", + "standard_name": "atmosphere_mass_content_of_water_vapor", "units": "kg m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", @@ -168,8 +159,9 @@ "ok_max_mean_abs": "" }, "psl": { + "frequency": "3hr", "modeling_realm": "atmos", - "standard_name": "air_pressure_at_sea_level", + "standard_name": "air_pressure_at_mean_sea_level", "units": "Pa", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", @@ -185,12 +177,13 @@ "ok_max_mean_abs": "" }, "ra": { + "frequency": "3hr", "modeling_realm": "land", - "standard_name": "plant_respiration_carbon_flux", + "standard_name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Carbon Mass Flux into Atmosphere due to Autotrophic (Plant) Respiration on Land", + "long_name": "Carbon Mass Flux into Atmosphere Due to Autotrophic (Plant) Respiration on Land", "comment": "Carbon mass flux per unit area into atmosphere due to autotrophic respiration on land (respiration by producers) [see rh for heterotrophic production]", "dimensions": "longitude latitude time", "out_name": "ra", @@ -202,12 +195,13 @@ "ok_max_mean_abs": "" }, "rh": { + "frequency": "3hr", "modeling_realm": "land", - "standard_name": "heterotrophic_respiration_carbon_flux", + "standard_name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_heterotrophic_respiration", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Carbon Mass Flux into Atmosphere due to Heterotrophic Respiration on Land", + "long_name": "Carbon Mass Flux into Atmosphere Due to Heterotrophic Respiration on Land", "comment": "Carbon mass flux per unit area into atmosphere due to heterotrophic respiration on land (respiration by consumers)", "dimensions": "longitude latitude time", "out_name": "rh", @@ -219,16 +213,17 @@ "ok_max_mean_abs": "" }, "rlut": { + "frequency": "3hr", "modeling_realm": "atmos", "standard_name": "toa_outgoing_longwave_flux", "units": "W m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "TOA Outgoing Longwave Radiatio", + "long_name": "TOA Outgoing Longwave Radiation", "comment": "at the top of the atmosphere (to be compared with satellite measurements)", "dimensions": "longitude latitude time", "out_name": "rlut", - "type": "", + "type": "real", "positive": "up", "valid_min": "", "valid_max": "", @@ -236,16 +231,17 @@ "ok_max_mean_abs": "" }, "rlutcs": { + "frequency": "3hr", "modeling_realm": "atmos", "standard_name": "toa_outgoing_longwave_flux_assuming_clear_sky", "units": "W m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "TOA Outgoing Clear-sky Longwave Radiation", - "comment": "", + "long_name": "TOA Outgoing Clear-Sky Longwave Radiation", + "comment": "Upwelling clear-sky longwave radiation at top of atmosphere", "dimensions": "longitude latitude time", "out_name": "rlutcs", - "type": "", + "type": "real", "positive": "up", "valid_min": "", "valid_max": "", @@ -253,6 +249,7 @@ "ok_max_mean_abs": "" }, "rsdt": { + "frequency": "3hr", "modeling_realm": "atmos", "standard_name": "toa_incoming_shortwave_flux", "units": "W m-2", @@ -270,16 +267,17 @@ "ok_max_mean_abs": "" }, "rsut": { + "frequency": "3hr", "modeling_realm": "atmos", "standard_name": "toa_outgoing_shortwave_flux", "units": "W m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Top-of-Atmosphere Outgoing Shortwave Radiation", + "long_name": "TOA Outgoing Shortwave Radiation", "comment": "at the top of the atmosphere", "dimensions": "longitude latitude time", "out_name": "rsut", - "type": "", + "type": "real", "positive": "up", "valid_min": "", "valid_max": "", @@ -287,6 +285,7 @@ "ok_max_mean_abs": "" }, "rsutcs": { + "frequency": "3hr", "modeling_realm": "atmos", "standard_name": "toa_outgoing_shortwave_flux_assuming_clear_sky", "units": "W m-2", @@ -296,7 +295,7 @@ "comment": "Calculated in the absence of clouds.", "dimensions": "longitude latitude time", "out_name": "rsutcs", - "type": "", + "type": "real", "positive": "up", "valid_min": "", "valid_max": "", @@ -304,6 +303,7 @@ "ok_max_mean_abs": "" }, "sfcWind": { + "frequency": "3hr", "modeling_realm": "atmos", "standard_name": "wind_speed", "units": "m s-1", @@ -321,6 +321,7 @@ "ok_max_mean_abs": "" }, "uas": { + "frequency": "3hr", "modeling_realm": "atmos", "standard_name": "eastward_wind", "units": "m s-1", @@ -330,7 +331,7 @@ "comment": "Eastward component of the near-surface (usually, 10 meters) wind", "dimensions": "longitude latitude time height10m", "out_name": "uas", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -338,6 +339,7 @@ "ok_max_mean_abs": "" }, "vas": { + "frequency": "3hr", "modeling_realm": "atmos", "standard_name": "northward_wind", "units": "m s-1", diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_E3hrPt.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_E3hrPt.json index 692c55224d..1ea0a892bf 100644 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_E3hrPt.json +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_E3hrPt.json @@ -1,30 +1,31 @@ { "Header": { - "data_specs_version": "01.00.10", + "data_specs_version": "01.00.30", + "cmor_version": "3.4", "table_id": "Table E3hrPt", "realm": "atmos", - "frequency": "3hr", - "cmor_version": "3.2", - "table_date": "10 May 2017", + "table_date": "11 March 2019", "missing_value": "1e20", + "int_missing_value": "-999", "product": "model-output", "approx_interval": "0.125000", - "generic_levels": "alevel", + "generic_levels": "alevel alevhalf", "mip_era": "CMIP6", - "Conventions": "CF-1.7 CMIP-6.0" + "Conventions": "CF-1.7 CMIP-6.2" }, "variable_entry": { "aerasymbnd": { + "frequency": "3hrPt", "modeling_realm": "atmos", - "standard_name": "band_aerosol_asymmetry_parameter", + "standard_name": "asymmetry_factor_of_ambient_aerosol_particles", "units": "1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "Aerosol level asymmetry parameter for each band", - "comment": "", + "long_name": "Aerosol Level Asymmetry Parameter for Each Band", + "comment": "The asymmetry factor is the angular integral of the aerosol scattering phase function weighted by the cosine of the angle with the incident radiation flux. The asymmetry coefficient is here an integral over all wavelength bands.", "dimensions": "longitude latitude alevel spectband time1", "out_name": "aerasymbnd", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -32,16 +33,17 @@ "ok_max_mean_abs": "" }, "aeroptbnd": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "atmosphere_absorption_optical_thickness_due_to_ambient_aerosol_particles", "units": "1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "Aerosol level extinction optical depth for each band", - "comment": "", + "long_name": "Aerosol Level Absorption Optical Thickness for Each Band", + "comment": "Optical thickness of atmospheric aerosols in wavelength bands.", "dimensions": "longitude latitude alevel spectband time1", "out_name": "aeroptbnd", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -49,16 +51,17 @@ "ok_max_mean_abs": "" }, "aerssabnd": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "single_scattering_albedo_in_air_due_to_ambient_aerosol_particles", "units": "1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "Aerosol level single-scattering albedo for each band", - "comment": "", + "long_name": "Aerosol Level Single Scattering Albedo for Each Band", + "comment": "The single scattering albedo is the fraction of radiation in an incident light beam scattered by the particles of an aerosol reference volume for a given wavelength. It is the ratio of the scattering and the extinction coefficients of the aerosol particles in the reference volume. ", "dimensions": "longitude latitude alevel spectband time1", "out_name": "aerssabnd", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -66,16 +69,17 @@ "ok_max_mean_abs": "" }, "albdiffbnd": { + "frequency": "3hrPt", "modeling_realm": "atmos", - "standard_name": "band_diffuse_albedo", - "units": "1.0", + "standard_name": "surface_diffuse_shortwave_hemispherical_reflectance", + "units": "1", "cell_methods": "time: point", "cell_measures": "area: areacella", - "long_name": "Diffuse surface albedo for each band", - "comment": "", + "long_name": "Diffuse Surface Albedo for Each Band", + "comment": "The fraction of the surface diffuse downwelling shortwave radiation flux which is reflected. If the diffuse radiation is isotropic, this term is equivalent to the integral of surface bidirectional reflectance over all incident angles and over all outgoing angles in the hemisphere above the surface. Reported in spectral frequency bands.", "dimensions": "longitude latitude spectband time1", "out_name": "albdiffbnd", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -83,16 +87,17 @@ "ok_max_mean_abs": "" }, "albdirbnd": { + "frequency": "3hrPt", "modeling_realm": "atmos", - "standard_name": "band_direct_albedo", - "units": "1.0", + "standard_name": "surface_direct_shortwave_hemispherical_reflectance", + "units": "1", "cell_methods": "time: point", "cell_measures": "area: areacella", - "long_name": "Direct surface albedo for each band", - "comment": "", + "long_name": "Direct Surface Albedo for Each Band", + "comment": "The fraction of the surface direct downwelling shortwave radiation flux which is reflected. It is equivalent to the surface bidirectional reflectance at the incident angle of the incoming solar radiation and integrated over all outgoing angles in the hemisphere above the surface. Reported in spectral frequency bands.", "dimensions": "longitude latitude spectband time1", "out_name": "albdirbnd", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -100,12 +105,13 @@ "ok_max_mean_abs": "" }, "cfadDbze94": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "histogram_of_equivalent_reflectivity_factor_over_height_above_reference_ellipsoid", - "units": "1.0", + "units": "1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "CloudSat Radar Reflectivity", + "long_name": "CloudSat Radar Reflectivity CFAD", "comment": "CFAD (Cloud Frequency Altitude Diagrams) are frequency distributions of radar reflectivity (or lidar scattering ratio) as a function of altitude. The variable cfadDbze94 is defined as the simulated relative frequency of occurrence of radar reflectivity in sampling volumes defined by altitude bins. The radar is observing at a frequency of 94GHz.", "dimensions": "longitude latitude alt40 dbze time1", "out_name": "cfadDbze94", @@ -117,12 +123,13 @@ "ok_max_mean_abs": "" }, "cfadLidarsr532": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "histogram_of_backscattering_ratio_over_height_above_reference_ellipsoid", - "units": "1.0", + "units": "1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "CALIPSO Scattering Ratio", + "long_name": "CALIPSO Scattering Ratio CFAD", "comment": "CFAD (Cloud Frequency Altitude Diagrams) are frequency distributions of radar reflectivity (or lidar scattering ratio) as a function of altitude. The variable cfadLidarsr532 is defined as the simulated relative frequency of lidar scattering ratio in sampling volumes defined by altitude bins. The lidar is observing at a wavelength of 532nm.", "dimensions": "longitude latitude alt40 scatratio time1", "out_name": "cfadLidarsr532", @@ -134,16 +141,17 @@ "ok_max_mean_abs": "" }, "ch4": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "mole_fraction_of_methane_in_air", "units": "mol mol-1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "CH4 volume mixing ratio", - "comment": "", + "long_name": "Mole Fraction of CH4", + "comment": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", "dimensions": "longitude latitude alevel time1", "out_name": "ch4", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -151,13 +159,14 @@ "ok_max_mean_abs": "" }, "clcalipso": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "cloud_area_fraction_in_atmosphere_layer", "units": "%", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "CALIPSO Cloud Fraction", - "comment": "Percentage cloud cover at CALIPSO standard heights.", + "long_name": "CALIPSO Percentage Cloud Cover", + "comment": "Percentage cloud cover in CALIPSO standard atmospheric layers.", "dimensions": "longitude latitude alt40 time1", "out_name": "clcalipso", "type": "real", @@ -168,12 +177,13 @@ "ok_max_mean_abs": "" }, "clcalipso2": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "cloud_area_fraction_in_atmosphere_layer", "units": "%", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "CALIPSO Cloud Fraction Undetected by CloudSat", + "long_name": "CALIPSO Cloud Cover Percentage Undetected by CloudSat (as Percentage of Area Covered)", "comment": "Clouds detected by CALIPSO but below the detectability threshold of CloudSat", "dimensions": "longitude latitude alt40 time1", "out_name": "clcalipso2", @@ -185,12 +195,13 @@ "ok_max_mean_abs": "" }, "clhcalipso": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "cloud_area_fraction_in_atmosphere_layer", "units": "%", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "CALIPSO High Level Cloud Fraction", + "long_name": "CALIPSO High Level Cloud Area Percentage", "comment": "Percentage cloud cover in layer centred on 220hPa", "dimensions": "longitude latitude time1 p220", "out_name": "clhcalipso", @@ -201,13 +212,32 @@ "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, + "clisccp": { + "frequency": "3hrPt", + "modeling_realm": "atmos", + "standard_name": "cloud_area_fraction_in_atmosphere_layer", + "units": "%", + "cell_methods": "area: mean time: point", + "cell_measures": "area: areacella", + "long_name": "ISCCP Cloud Area Percentage", + "comment": "Percentage cloud cover in optical depth categories.", + "dimensions": "longitude latitude plev7c tau time1", + "out_name": "clisccp", + "type": "real", + "positive": "", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, "cllcalipso": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "cloud_area_fraction_in_atmosphere_layer", "units": "%", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "CALIPSO Percentage Low Level Cloud", + "long_name": "CALIPSO Low Level Cloud Cover Percentage", "comment": "Percentage cloud cover in layer centred on 840hPa", "dimensions": "longitude latitude time1 p840", "out_name": "cllcalipso", @@ -219,12 +249,13 @@ "ok_max_mean_abs": "" }, "clmcalipso": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "cloud_area_fraction_in_atmosphere_layer", "units": "%", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "CALIPSO Mid Level Cloud Fraction", + "long_name": "CALIPSO Mid Level Cloud Cover Percentage", "comment": "Percentage cloud cover in layer centred on 560hPa", "dimensions": "longitude latitude time1 p560", "out_name": "clmcalipso", @@ -236,16 +267,17 @@ "ok_max_mean_abs": "" }, "clmisr": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "cloud_area_fraction_in_atmosphere_layer", "units": "%", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "Percentage Cloud Cover as Calculated by the MISR Simulator", - "comment": "Cloud percentage in spectral bands and layers as observed by the Multi-angle Imaging SpectroRadiometer (MISR) instrument.", + "long_name": "Percentage Cloud Cover as Calculated by the MISR Simulator (Including Error Flag)", + "comment": "Cloud percentage in spectral bands and layers as observed by the Multi-angle Imaging SpectroRadiometer (MISR) instrument. The first layer in each profile is reserved for a retrieval error flag.", "dimensions": "longitude latitude alt16 tau time1", "out_name": "clmisr", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -253,13 +285,14 @@ "ok_max_mean_abs": "" }, "cltcalipso": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "cloud_area_fraction", "units": "%", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "CALIPSO Total Cloud Fraction", - "comment": "", + "long_name": "CALIPSO Total Cloud Cover Percentage", + "comment": "Total cloud area fraction (reported as a percentage) for the whole atmospheric column, as seen by the Cloud-Aerosol Lidar and Infrared Pathfinder Satellite Observation (CALIPSO) instrument. Includes both large-scale and convective cloud.", "dimensions": "longitude latitude time1", "out_name": "cltcalipso", "type": "real", @@ -270,16 +303,17 @@ "ok_max_mean_abs": "" }, "co2": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "mole_fraction_of_carbon_dioxide_in_air", "units": "mol mol-1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "CO2 volume mixing ratio", - "comment": "", + "long_name": "Mole Fraction of CO2", + "comment": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", "dimensions": "longitude latitude alevel time1", "out_name": "co2", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -287,16 +321,17 @@ "ok_max_mean_abs": "" }, "hus": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "specific_humidity", - "units": "1.0", + "units": "1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", "long_name": "Specific Humidity", - "comment": "", + "comment": "Specific humidity is the mass fraction of water vapor in (moist) air.", "dimensions": "longitude latitude alevel time1", "out_name": "hus", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -304,16 +339,17 @@ "ok_max_mean_abs": "" }, "hus7h": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "specific_humidity", - "units": "1.0", + "units": "1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", "long_name": "Specific Humidity", - "comment": "", + "comment": "Specific humidity is the mass fraction of water vapor in (moist) air.", "dimensions": "longitude latitude plev7h time1", "out_name": "hus", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -321,16 +357,17 @@ "ok_max_mean_abs": "" }, "jpdftaureicemodis": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "cloud_area_fraction_in_atmosphere_layer", "units": "%", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "MODIS Optical Thickness-Particle Size joint distribution, ice", - "comment": "", - "dimensions": "longitude latitude plev7c effectRadIc tau time1", + "long_name": "MODIS Joint Distribution of Optical Thickness and Particle Size, Ice", + "comment": "Joint probability distribution function, giving probability of cloud as a function of optical thickness and particle size, as measured by MODIS. For cloud ice particles.", + "dimensions": "longitude latitude effectRadIc tau time1", "out_name": "jpdftaureicemodis", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -338,16 +375,17 @@ "ok_max_mean_abs": "" }, "jpdftaureliqmodis": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "cloud_area_fraction_in_atmosphere_layer", "units": "%", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "MODIS Optical Thickness-Particle Size joint distribution, liquid", - "comment": "", - "dimensions": "longitude latitude plev7c effectRadLi tau time1", + "long_name": "MODIS Optical Thickness-Particle Size Joint Distribution, Liquid", + "comment": "Joint probability distribution function, giving probability of cloud as a function of optical thickness and particle size, as measured by MODIS. For liquid cloud particles.", + "dimensions": "longitude latitude effectRadLi tau time1", "out_name": "jpdftaureliqmodis", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -355,16 +393,17 @@ "ok_max_mean_abs": "" }, "n2o": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "mole_fraction_of_nitrous_oxide_in_air", "units": "mol mol-1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "N2O volume mixing ratio", - "comment": "", + "long_name": "Mole Fraction of N2O", + "comment": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. The chemical formula of nitrous oxide is N2O.", "dimensions": "longitude latitude alevel time1", "out_name": "n2o", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -372,16 +411,17 @@ "ok_max_mean_abs": "" }, "o3": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "mole_fraction_of_ozone_in_air", "units": "mol mol-1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "Ozone volume mixing ratio", - "comment": "", + "long_name": "Mole Fraction of O3", + "comment": "Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", "dimensions": "longitude latitude alevel time1", "out_name": "o3", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -389,10 +429,11 @@ "ok_max_mean_abs": "" }, "parasolRefl": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "toa_bidirectional_reflectance", - "units": "1.0", - "cell_methods": "area: mean (global) time: point", + "units": "1", + "cell_methods": "area: mean where sea time: point", "cell_measures": "area: areacella", "long_name": "PARASOL Reflectance", "comment": "Simulated reflectance from PARASOL as seen at the top of the atmosphere for 5 solar zenith angles. Valid only over ocean and for one viewing direction (viewing zenith angle of 30 degrees and relative azimuth angle 320 degrees).", @@ -406,32 +447,16 @@ "ok_max_mean_abs": "" }, "ps": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "surface_air_pressure", "units": "Pa", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "Surface Pressure", + "long_name": "Surface Air Pressure", "comment": "surface pressure (not mean sea-level pressure), 2-D field to calculate the 3-D pressure field from hybrid coordinates", "dimensions": "longitude latitude time1", "out_name": "ps", - "type": "float", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "psl": { - "modeling_realm": "atmos", - "standard_name": "air_pressure_at_sea_level", - "units": "Pa", - "cell_methods": "area: mean time: point", - "cell_measures": "area: areacella", - "long_name": "Sea Level Pressure", - "comment": "Sea Level Pressure", - "dimensions": "longitude latitude time1", - "out_name": "psl", "type": "real", "positive": "", "valid_min": "", @@ -440,6 +465,7 @@ "ok_max_mean_abs": "" }, "rsdcs": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "downwelling_shortwave_flux_in_air_assuming_clear_sky", "units": "W m-2", @@ -447,7 +473,7 @@ "cell_measures": "area: areacella", "long_name": "Downwelling Clear-Sky Shortwave Radiation", "comment": "Downwelling clear-sky shortwave radiation (includes the fluxes at the surface and top-of-atmosphere)", - "dimensions": "longitude latitude alevel time1", + "dimensions": "longitude latitude alevhalf time1", "out_name": "rsdcs", "type": "real", "positive": "down", @@ -457,59 +483,63 @@ "ok_max_mean_abs": "" }, "rsdcsaf": { - "modeling_realm": "atmos", - "standard_name": "downwelling_shortwave_flux_assuming_clean_clear_sky", + "frequency": "3hrPt", + "modeling_realm": "aerosol", + "standard_name": "downwelling_shortwave_flux_in_air_assuming_clear_sky_and_no_aerosol", "units": "W m-2", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "Downwelling Clean-Clear-Sky Shortwave Radiation at each level", + "long_name": "Downwelling Clear-Sky, Aerosol-Free Shortwave Radiation", "comment": "Calculated in the absence of aerosols and clouds (following Ghan). This requires a double-call in the radiation code with precisely the same meteorology.", - "dimensions": "longitude latitude alevel time1", + "dimensions": "longitude latitude alevhalf time1", "out_name": "rsdcsaf", - "type": "", - "positive": "", + "type": "real", + "positive": "down", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "rsdcsafbnd": { - "modeling_realm": "atmos", - "standard_name": "band_downwelling_shortwave_flux_assuming_clean_clear_sky", + "frequency": "3hrPt", + "modeling_realm": "aerosol", + "standard_name": "downwelling_shortwave_flux_in_air_assuming_clear_sky_and_no_aerosol", "units": "W m-2", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", "long_name": "Downwelling Clear-Sky, Aerosol-Free, Shortwave Radiation in Bands", "comment": "Calculated in the absence of aerosols and clouds (following Ghan). This requires a double-call in the radiation code with precisely the same meteorology.", - "dimensions": "longitude latitude alevel spectband time1", + "dimensions": "longitude latitude alevhalf spectband time1", "out_name": "rsdcsafbnd", - "type": "", - "positive": "", + "type": "real", + "positive": "down", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "rsdcsbnd": { + "frequency": "3hrPt", "modeling_realm": "atmos", - "standard_name": "band_downwelling_shortwave_flux_assuming_clear_sky", + "standard_name": "downwelling_shortwave_flux_in_air_assuming_clear_sky", "units": "W m-2", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "Downwelling Clear-Sky Shortwave Radiation at each level for each band", + "long_name": "Downwelling Clear-Sky Shortwave Radiation at Each Level for Each Band", "comment": "Calculated with aerosols but without clouds. This is a standard clear-sky calculation", - "dimensions": "longitude latitude alevel spectband time1", + "dimensions": "longitude latitude alevhalf spectband time1", "out_name": "rsdcsbnd", - "type": "", - "positive": "", + "type": "real", + "positive": "down", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "rsdscsaf": { - "modeling_realm": "atmos", - "standard_name": "surface_downwelling_shortwave_flux_in_air_assuming_clean_clear_sky", + "frequency": "3hrPt", + "modeling_realm": "aerosol", + "standard_name": "surface_downwelling_shortwave_flux_in_air_assuming_clear_sky_and_no_aerosol", "units": "W m-2", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", @@ -517,16 +547,17 @@ "comment": "Calculated in the absence of aerosols and clouds.", "dimensions": "longitude latitude time1", "out_name": "rsdscsaf", - "type": "", - "positive": "", + "type": "real", + "positive": "down", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "rsdscsafbnd": { - "modeling_realm": "atmos", - "standard_name": "surface_downwelling_shortwave_flux_in_air_assuming_clean_clear_sky", + "frequency": "3hrPt", + "modeling_realm": "aerosol", + "standard_name": "surface_downwelling_shortwave_flux_in_air_assuming_clear_sky_and_no_aerosol", "units": "W m-2", "cell_methods": "time: point", "cell_measures": "area: areacella", @@ -534,31 +565,33 @@ "comment": "Calculated in the absence of aerosols and clouds, following Ghan (2013, ACP). This requires a double-call in the radiation code with precisely the same meteorology.", "dimensions": "longitude latitude spectband time1", "out_name": "rsdscsafbnd", - "type": "", - "positive": "", + "type": "real", + "positive": "down", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "rsdscsbnd": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "surface_downwelling_shortwave_flux_in_air_assuming_clear_sky", "units": "W m-2", "cell_methods": "time: point", "cell_measures": "area: areacella", - "long_name": "Surface Downwelling Clear-Sky Shortwave Radiation for each band", + "long_name": "Surface Downwelling Clear-Sky Shortwave Radiation for Each Band", "comment": "Calculated with aerosols but without clouds. This is a standard clear-sky calculation", "dimensions": "longitude latitude spectband time1", "out_name": "rsdscsbnd", - "type": "", - "positive": "", + "type": "real", + "positive": "down", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "rsucs": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "upwelling_shortwave_flux_in_air_assuming_clear_sky", "units": "W m-2", @@ -566,7 +599,7 @@ "cell_measures": "area: areacella", "long_name": "Upwelling Clear-Sky Shortwave Radiation", "comment": "Upwelling clear-sky shortwave radiation (includes the fluxes at the surface and TOA)", - "dimensions": "longitude latitude alevel time1", + "dimensions": "longitude latitude alevhalf time1", "out_name": "rsucs", "type": "real", "positive": "up", @@ -576,66 +609,52 @@ "ok_max_mean_abs": "" }, "rsucsaf": { - "modeling_realm": "atmos", - "standard_name": "upwelling_shortwave_flux_assuming_clean_clear_sky", + "frequency": "3hrPt", + "modeling_realm": "aerosol", + "standard_name": "upwelling_shortwave_flux_in_air_assuming_clear_sky_and_no_aerosol", "units": "W m-2", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "Upwelling Clean-Clear-Sky Shortwave Radiation at each level", + "long_name": "Upwelling Clear-Sky, Aerosol-Free Shortwave Radiation", "comment": "Calculated in the absence of aerosols and clouds (following Ghan). This requires a double-call in the radiation code with precisely the same meteorology.", - "dimensions": "longitude latitude alevel time1", + "dimensions": "longitude latitude alevhalf time1", "out_name": "rsucsaf", - "type": "", - "positive": "", + "type": "real", + "positive": "up", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "rsucsafbnd": { - "modeling_realm": "atmos", - "standard_name": "band_upwelling_shortwave_flux_assuming_clean_clear_sky", + "frequency": "3hrPt", + "modeling_realm": "aerosol", + "standard_name": "upwelling_shortwave_flux_in_air_assuming_clear_sky_and_no_aerosol", "units": "W m-2", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", "long_name": "Upwelling Clear-Sky, Aerosol-Free Shortwave Radiation in Bands", "comment": "Calculated in the absence of aerosols and clouds (following Ghan). This requires a double-call in the radiation code with precisely the same meteorology.", - "dimensions": "longitude latitude alevel spectband time1", + "dimensions": "longitude latitude alevhalf spectband time1", "out_name": "rsucsafbnd", - "type": "", - "positive": "", + "type": "real", + "positive": "up", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "rsucsbnd": { + "frequency": "3hrPt", "modeling_realm": "atmos", - "standard_name": "band_upwelling_shortwave_flux_assuming_clear_sky", + "standard_name": "upwelling_shortwave_flux_in_air_assuming_clear_sky", "units": "W m-2", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "Upwelling Clear-Sky Shortwave Radiation at each level for each band", + "long_name": "Upwelling Clear-Sky Shortwave Radiation at Each Level for Each Band", "comment": "Calculated with aerosols but without clouds. This is a standard clear-sky calculation", - "dimensions": "longitude latitude alevel spectband time1", + "dimensions": "longitude latitude alevhalf spectband time1", "out_name": "rsucsbnd", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "rsuscs": { - "modeling_realm": "atmos", - "standard_name": "surface_upwelling_shortwave_flux_in_air_assuming_clear_sky", - "units": "W m-2", - "cell_methods": "area: mean time: point", - "cell_measures": "area: areacella", - "long_name": "Surface Upwelling Clear-Sky Shortwave Radiation", - "comment": "Surface Upwelling Clear-sky Shortwave Radiation", - "dimensions": "longitude latitude time1", - "out_name": "rsuscs", "type": "real", "positive": "up", "valid_min": "", @@ -644,8 +663,9 @@ "ok_max_mean_abs": "" }, "rsuscsaf": { - "modeling_realm": "atmos", - "standard_name": "surface_upwelling_shortwave_flux_in_air_assuming_clean_clear_sky", + "frequency": "3hrPt", + "modeling_realm": "aerosol", + "standard_name": "surface_upwelling_shortwave_flux_in_air_assuming_clear_sky_and_no_aerosol", "units": "W m-2", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", @@ -653,16 +673,17 @@ "comment": "Surface Upwelling Clear-sky, Aerosol Free Shortwave Radiation", "dimensions": "longitude latitude time1", "out_name": "rsuscsaf", - "type": "", - "positive": "", + "type": "real", + "positive": "up", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "rsuscsafbnd": { - "modeling_realm": "atmos", - "standard_name": "surface_upwelling_shortwave_flux_in_air_assuming_clean_clear_sky", + "frequency": "3hrPt", + "modeling_realm": "aerosol", + "standard_name": "surface_upwelling_shortwave_flux_in_air_assuming_clear_sky_and_no_aerosol", "units": "W m-2", "cell_methods": "time: point", "cell_measures": "area: areacella", @@ -670,50 +691,53 @@ "comment": "Calculated in the absence of aerosols and clouds, following Ghan (ACP, 2013). This requires a double-call in the radiation code with precisely the same meteorology.", "dimensions": "longitude latitude spectband time1", "out_name": "rsuscsafbnd", - "type": "", - "positive": "", + "type": "real", + "positive": "up", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "rsuscsbnd": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "surface_upwelling_shortwave_flux_in_air_assuming_clear_sky", "units": "W m-2", "cell_methods": "time: point", "cell_measures": "area: areacella", - "long_name": "Surface Upwelling Clear-Sky Shortwave Radiation for each band", + "long_name": "Surface Upwelling Clear-Sky Shortwave Radiation for Each Band", "comment": "Calculated with aerosols but without clouds. This is a standard clear-sky calculation", "dimensions": "longitude latitude spectband time1", "out_name": "rsuscsbnd", - "type": "", - "positive": "", + "type": "real", + "positive": "up", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "rsutcsaf": { + "frequency": "3hrPt", "modeling_realm": "aerosol", - "standard_name": "toa_outgoing_shortwave_flux_assuming_clear_sky", + "standard_name": "toa_outgoing_shortwave_flux_assuming_clear_sky_and_no_aerosol", "units": "W m-2", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "toa outgoing clear-sky shortwave radiation", - "comment": "Flux corresponding to rsutcs resulting fom aerosol-free call to radiation, following Ghan (ACP, 2013)", + "long_name": "TOA Outgoing Clear-Sky, Aerosol-Free Shortwave Radiation", + "comment": "Flux corresponding to rsutcs resulting from aerosol-free call to radiation, following Ghan (ACP, 2013)", "dimensions": "longitude latitude time1", "out_name": "rsutcsaf", - "type": "float", - "positive": "", + "type": "real", + "positive": "up", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "rsutcsafbnd": { + "frequency": "3hrPt", "modeling_realm": "atmos", - "standard_name": "band_toa_outgoing_shortwave_flux_assuming_clean_clear_sky", + "standard_name": "toa_outgoing_shortwave_flux_assuming_clear_sky_and_no_aerosol", "units": "W m-2", "cell_methods": "time: point", "cell_measures": "area: areacella", @@ -721,41 +745,43 @@ "comment": "Calculated in the absence of aerosols and clouds, following Ghan (2013, ACP). This requires a double-call in the radiation code with precisely the same meteorology.", "dimensions": "longitude latitude spectband time1", "out_name": "rsutcsafbnd", - "type": "", - "positive": "", + "type": "real", + "positive": "up", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "rsutcsbnd": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "toa_outgoing_shortwave_flux_assuming_clear_sky", "units": "W m-2", "cell_methods": "time: point", "cell_measures": "area: areacella", - "long_name": "TOA Outgoing Clear-Sky Shortwave Radiation for each band", + "long_name": "TOA Outgoing Clear-Sky Shortwave Radiation for Each Band", "comment": "Calculated with aerosols but without clouds. This is a standard clear-sky calculation", "dimensions": "longitude latitude spectband time1", "out_name": "rsutcsbnd", - "type": "", - "positive": "", + "type": "real", + "positive": "up", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "solbnd": { + "frequency": "3hrPt", "modeling_realm": "atmos", - "standard_name": "band_solar_insolation", + "standard_name": "toa_incoming_shortwave_flux", "units": "W m-2", "cell_methods": "time: point", "cell_measures": "area: areacella", - "long_name": "Top-of-Atmosphere Solar Insolation for each band", - "comment": "", + "long_name": "TOA Solar Irradiance for Each Band", + "comment": "Solar irradiance at a horizontal surface at top of atmosphere.", "dimensions": "longitude latitude spectband time1", "out_name": "solbnd", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -763,6 +789,7 @@ "ok_max_mean_abs": "" }, "sza": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "solar_zenith_angle", "units": "degree", @@ -772,7 +799,7 @@ "comment": "The angle between the line of sight to the sun and the local vertical", "dimensions": "longitude latitude time1", "out_name": "sza", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -780,6 +807,7 @@ "ok_max_mean_abs": "" }, "ta7h": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "air_temperature", "units": "K", @@ -789,23 +817,6 @@ "comment": "Air Temperature", "dimensions": "longitude latitude plev7h time1", "out_name": "ta", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "ts": { - "modeling_realm": "atmos", - "standard_name": "surface_temperature", - "units": "K", - "cell_methods": "area: mean time: point", - "cell_measures": "area: areacella", - "long_name": "Surface Temperature", - "comment": "Temperature of the lower boundary of the atmosphere", - "dimensions": "longitude latitude time1", - "out_name": "ts", "type": "real", "positive": "", "valid_min": "", @@ -814,33 +825,17 @@ "ok_max_mean_abs": "" }, "ua7h": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "eastward_wind", "units": "m s-1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", "long_name": "Eastward Wind", - "comment": "", + "comment": "Zonal wind (positive in a eastward direction).", "dimensions": "longitude latitude plev7h time1", "out_name": "ua", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "ua850": { - "modeling_realm": "atmos", - "standard_name": "eastward_wind", - "units": "m s-1", - "cell_methods": "time: point", - "cell_measures": "area: areacella", - "long_name": "Eastward Wind", - "comment": "", - "dimensions": "longitude latitude time1 p850", - "out_name": "ua", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -848,33 +843,17 @@ "ok_max_mean_abs": "" }, "va7h": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "northward_wind", "units": "m s-1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", "long_name": "Northward Wind", - "comment": "", + "comment": "Meridional wind (positive in a northward direction).", "dimensions": "longitude latitude plev7h time1", "out_name": "va", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "va850": { - "modeling_realm": "atmos", - "standard_name": "northward_wind", - "units": "m s-1", - "cell_methods": "time: point", - "cell_measures": "area: areacella", - "long_name": "Northward Wind", - "comment": "", - "dimensions": "longitude latitude time1 p850", - "out_name": "va", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -882,12 +861,13 @@ "ok_max_mean_abs": "" }, "wap7h": { + "frequency": "3hrPt", "modeling_realm": "atmos", "standard_name": "lagrangian_tendency_of_air_pressure", "units": "Pa s-1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "omega (=dp/dt)", + "long_name": "Omega (=dp/dt)", "comment": "Omega (vertical velocity in pressure coordinates, positive downwards)", "dimensions": "longitude latitude plev7h time1", "out_name": "wap", diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_E6hrZ.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_E6hrZ.json index e7eaf5890e..dd3f404102 100644 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_E6hrZ.json +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_E6hrZ.json @@ -1,30 +1,31 @@ { "Header": { - "data_specs_version": "01.00.10", + "data_specs_version": "01.00.30", + "cmor_version": "3.4", "table_id": "Table E6hrZ", "realm": "atmos", - "frequency": "6hr", - "cmor_version": "3.2", - "table_date": "10 May 2017", + "table_date": "11 March 2019", "missing_value": "1e20", + "int_missing_value": "-999", "product": "model-output", "approx_interval": "0.250000", - "generic_levels": "alevel", + "generic_levels": "alevel alevhalf", "mip_era": "CMIP6", - "Conventions": "CF-1.7 CMIP-6.0" + "Conventions": "CF-1.7 CMIP-6.2" }, "variable_entry": { "ps": { + "frequency": "6hr", "modeling_realm": "atmos", "standard_name": "surface_air_pressure", "units": "Pa", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", - "long_name": "Surface Pressure", + "cell_measures": "", + "long_name": "Surface Air Pressure", "comment": "surface pressure (not mean sea-level pressure), 2-D field to calculate the 3-D pressure field from hybrid coordinates", "dimensions": "latitude time", "out_name": "ps", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -32,16 +33,17 @@ "ok_max_mean_abs": "" }, "zmlwaero": { + "frequency": "6hrPt", "modeling_realm": "atmos", - "standard_name": "longwave_heating_rate_due_to_volcanic_aerosols", + "standard_name": "tendency_of_air_temperature_due_to_longwave_heating_from_volcanic_ambient_aerosol_particles", "units": "K s-1", "cell_methods": "longitude: mean time: point", - "cell_measures": "area: areacella", - "long_name": "Zonal mean longwave heating rate due to volcanic aerosols", + "cell_measures": "", + "long_name": "Zonal Mean Longwave Heating Rate Due to Volcanic Aerosols", "comment": "longwave heating rate due to volcanic aerosols to be diagnosed through double radiation call, zonal average values required", "dimensions": "latitude alevel time1", "out_name": "zmlwaero", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -49,16 +51,17 @@ "ok_max_mean_abs": "" }, "zmswaero": { + "frequency": "6hrPt", "modeling_realm": "atmos", - "standard_name": "shortwave_heating_rate_due_to_volcanic_aerosols", + "standard_name": "tendency_of_air_temperature_due_to_shortwave_heating_from_volcanic_ambient_aerosol_particles", "units": "K s-1", "cell_methods": "longitude: mean time: point", - "cell_measures": "area: areacella", - "long_name": "Zonal mean shortwave heating rate due to volcanic aerosols", + "cell_measures": "", + "long_name": "Zonal Mean Shortwave Heating Rate Due to Volcanic Aerosols", "comment": "shortwave heating rate due to volcanic aerosols to be diagnosed through double radiation call, zonal average values required", "dimensions": "latitude alevel time1", "out_name": "zmswaero", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Eday.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Eday.json index fa7cc11c81..355e861b35 100644 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Eday.json +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Eday.json @@ -1,26 +1,27 @@ { "Header": { - "data_specs_version": "01.00.10", + "data_specs_version": "01.00.30", + "cmor_version": "3.4", "table_id": "Table Eday", - "realm": "aerosol", - "frequency": "day", - "cmor_version": "3.2", - "table_date": "10 May 2017", + "realm": "land", + "table_date": "11 March 2019", "missing_value": "1e20", + "int_missing_value": "-999", "product": "model-output", "approx_interval": "1.00000", "generic_levels": "", "mip_era": "CMIP6", - "Conventions": "CF-1.7 CMIP-6.0" + "Conventions": "CF-1.7 CMIP-6.2" }, "variable_entry": { "agesno": { + "frequency": "day", "modeling_realm": "landIce land", "standard_name": "age_of_surface_snow", "units": "day", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Snow Age", + "long_name": "Mean Age of Snow", "comment": "Age of Snow (when computing the time-mean here, the time samples, weighted by the mass of snow on the land portion of the grid cell, are accumulated and then divided by the sum of the weights. Reported as missing data in regions free of snow on land.", "dimensions": "longitude latitude time", "out_name": "agesno", @@ -32,33 +33,17 @@ "ok_max_mean_abs": "" }, "albc": { + "frequency": "day", "modeling_realm": "land", "standard_name": "canopy_albedo", - "units": "1.0", + "units": "1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", "long_name": "Canopy Albedo", - "comment": "", + "comment": "Albedo of the vegetation: fraction of incoming solar radiation which is reflected before reaching the ground.", "dimensions": "longitude latitude time", "out_name": "albc", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "albs": { - "modeling_realm": "aerosol", - "standard_name": "surface_albedo", - "units": "1.0", - "cell_methods": "area: mean where land time: mean", - "cell_measures": "area: areacella", - "long_name": "planetary albedo", - "comment": "Grid cell average albedo for all wavelengths.", - "dimensions": "longitude latitude time", - "out_name": "albs", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -66,16 +51,17 @@ "ok_max_mean_abs": "" }, "albsn": { + "frequency": "day", "modeling_realm": "land", - "standard_name": "snow_and_ice_albedo", - "units": "1.0", - "cell_methods": "area: mean where land time: mean", + "standard_name": "surface_albedo", + "units": "1", + "cell_methods": "area: time: mean where snow (comment: mask=snc)", "cell_measures": "area: areacella", "long_name": "Snow Albedo", "comment": "Albedo of the snow-covered surface, averaged over the grid cell.", "dimensions": "longitude latitude time", "out_name": "albsn", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -83,16 +69,17 @@ "ok_max_mean_abs": "" }, "aod550volso4": { + "frequency": "day", "modeling_realm": "atmos", - "standard_name": "aerosol_optical_depth_due_to_stratospheric_volcanic_aerosols", + "standard_name": "stratosphere_optical_thickness_due_to_volcanic_ambient_aerosol_particles", "units": "1e-09", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Aerosol optical depth at 550 nm due to stratospheric volcanic aerosols", - "comment": "aerosol optical depth at 550 nm due to stratospheric volcanic aerosols", - "dimensions": "longitude latitude time", + "long_name": "Aerosol Optical Depth at 550nm Due to Stratospheric Volcanic Aerosols", + "comment": "Aerosol optical depth at 550nm due to stratospheric volcanic aerosols", + "dimensions": "longitude latitude time lambda550nm", "out_name": "aod550volso4", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -100,16 +87,17 @@ "ok_max_mean_abs": "" }, "ares": { + "frequency": "day", "modeling_realm": "land", "standard_name": "aerodynamic_resistance", "units": "s m-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Aerodynamic resistance", - "comment": "", + "long_name": "Aerodynamic Resistance", + "comment": "The 'aerodynamic_resistance' is the resistance to mixing through the boundary layer toward the surface by means of the dominant process, turbulent transport. Reference: Wesely, M. L., 1989, doi:10.1016/0004-6981(89)90153-4.", "dimensions": "longitude latitude time", "out_name": "ares", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -117,8 +105,9 @@ "ok_max_mean_abs": "" }, "ccldncl": { + "frequency": "day", "modeling_realm": "atmos", - "standard_name": "number_concentration_of_convective_cloud_liquid_water_particles_in_air_at_liquid_water_cloud_top", + "standard_name": "number_concentration_of_convective_cloud_liquid_water_particle_at_convective_liquid_water_cloud_top", "units": "m-3", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", @@ -126,7 +115,7 @@ "comment": "Droplets are liquid only. Report concentration 'as seen from space' over convective liquid cloudy portion of grid cell. This is the value from uppermost model layer with liquid cloud or, if available, it is better to sum over all liquid cloud tops, no matter where they occur, as long as they are seen from the top of the atmosphere. Weight by total liquid cloud top fraction of (as seen from TOA) each time sample when computing monthly mean.", "dimensions": "longitude latitude time", "out_name": "ccldncl", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -134,6 +123,7 @@ "ok_max_mean_abs": "" }, "cldnci": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "number_concentration_of_ice_crystals_in_air_at_ice_cloud_top", "units": "m-3", @@ -143,7 +133,7 @@ "comment": "Concentration 'as seen from space' over ice-cloud portion of grid cell. This is the value from uppermost model layer with ice cloud or, if available, it is the sum over all ice cloud tops, no matter where they occur, as long as they are seen from the top of the atmosphere. Weight by total ice cloud top fraction (as seen from TOA) of each time sample when computing monthly mean.", "dimensions": "longitude latitude time", "out_name": "cldnci", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -151,6 +141,7 @@ "ok_max_mean_abs": "" }, "cldnvi": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "atmosphere_number_content_of_cloud_droplets", "units": "m-2", @@ -160,7 +151,7 @@ "comment": "Droplets are liquid only. Values are weighted by liquid cloud fraction in each layer when vertically integrating, and for monthly means the samples are weighted by total liquid cloud fraction (as seen from TOA).", "dimensions": "longitude latitude time", "out_name": "cldnvi", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -168,8 +159,9 @@ "ok_max_mean_abs": "" }, "clivic": { + "frequency": "day", "modeling_realm": "atmos", - "standard_name": "atmosphere_convective_cloud_ice_content", + "standard_name": "atmosphere_mass_content_of_convective_cloud_ice", "units": "kg m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", @@ -177,7 +169,7 @@ "comment": "calculate mass of convective ice water in the column divided by the area of the column (not just the area of the cloudy portion of the column). This includes precipitating frozen hydrometeors ONLY if the precipitating hydrometeors affect the calculation of radiative transfer in model.", "dimensions": "longitude latitude time", "out_name": "clivic", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -185,13 +177,14 @@ "ok_max_mean_abs": "" }, "clt": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "cloud_area_fraction", "units": "%", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Total Cloud Fraction", - "comment": "Total cloud area fraction for the whole atmospheric column, as seen from the surface or the top of the atmosphere. Includes both large-scale and convective cloud.", + "long_name": "Total Cloud Cover Percentage", + "comment": "Total cloud area fraction (reported as a percentage) for the whole atmospheric column, as seen from the surface or the top of the atmosphere. Includes both large-scale and convective cloud.", "dimensions": "longitude latitude time", "out_name": "clt", "type": "real", @@ -202,8 +195,9 @@ "ok_max_mean_abs": "" }, "clwvic": { + "frequency": "day", "modeling_realm": "atmos", - "standard_name": "atmosphere_convective_cloud_condensed_water_content", + "standard_name": "atmosphere_mass_content_of_convective_cloud_condensed_water", "units": "kg m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", @@ -211,7 +205,7 @@ "comment": "calculate mass of convective condensed (liquid + ice) water in the column divided by the area of the column (not just the area of the cloudy portion of the column). This includes precipitating hydrometeors ONLY if the precipitating hydrometeors affect the calculation of radiative transfer in model.", "dimensions": "longitude latitude time", "out_name": "clwvic", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -219,101 +213,17 @@ "ok_max_mean_abs": "" }, "cnc": { + "frequency": "day", "modeling_realm": "land", "standard_name": "vegetation_area_fraction", "units": "%", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Canopy covered area percentage", - "comment": "", + "long_name": "Canopy Covered Area Percentage", + "comment": "Percentage of area covered by vegetation.", "dimensions": "longitude latitude time", "out_name": "cnc", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "concbb": { - "modeling_realm": "atmos", - "standard_name": "mass_concentration_of_biomass_burning_dry_aerosol_in_air", - "units": "kg m-3", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "Concentration of Biomass Burning Aerosol", - "comment": "", - "dimensions": "longitude latitude time", - "out_name": "concbb", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "conccmcn": { - "modeling_realm": "atmos", - "standard_name": "number_concentration_of_coarse_mode_ambient_aerosol_in_air", - "units": "m-3", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "Number Concentration Coarse Mode Aerosol", - "comment": "includes all particles with diameter larger than 1 micron", - "dimensions": "longitude latitude time", - "out_name": "conccmcn", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "conccn": { - "modeling_realm": "atmos", - "standard_name": "number_concentration_of_ambient_aerosol_in_air", - "units": "m-3", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "Aerosol Number Concentration", - "comment": "", - "dimensions": "longitude latitude time", - "out_name": "conccn", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "concnmcn": { - "modeling_realm": "atmos", - "standard_name": "number_concentration_of_nucleation_mode_ambient_aerosol_in_air", - "units": "m-3", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "Number Concentration of Nucleation Mode Aerosol", - "comment": "includes all particles with diameter smaller than 3 nm", - "dimensions": "longitude latitude time", - "out_name": "concnmcn", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "concpoa": { - "modeling_realm": "atmos", - "standard_name": "mass_concentration_of_primary_particulate_organic_matter_dry_aerosol_in_air", - "units": "kg m-3", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "Concentration of Dry Aerosol Primary Organic Matter", - "comment": "", - "dimensions": "longitude latitude time", - "out_name": "concpoa", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -321,16 +231,17 @@ "ok_max_mean_abs": "" }, "cw": { + "frequency": "day", "modeling_realm": "land", "standard_name": "canopy_water_amount", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", "long_name": "Total Canopy Water Storage", - "comment": "", + "comment": "'Amount' means mass per unit area. 'Water' means water in all phases, including frozen i.e. ice and snow. 'Canopy' means the plant or vegetation canopy. The canopy water is the water on the canopy.", "dimensions": "longitude latitude time", "out_name": "cw", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -338,33 +249,17 @@ "ok_max_mean_abs": "" }, "dcw": { + "frequency": "day", "modeling_realm": "land", "standard_name": "change_over_time_in_canopy_water_amount", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", "long_name": "Change in Interception Storage", - "comment": "", + "comment": "The phrase 'change_over_time_in_X' means change in a quantity X over a time-interval, which should be defined by the bounds of the time coordinate. 'Canopy' means the plant or vegetation canopy. Canopy water is the water on the canopy. 'Water' means water in all phases, including frozen, i.e. ice and snow. 'Amount' means mass per unit area.", "dimensions": "longitude latitude time", "out_name": "dcw", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "dfr": { - "modeling_realm": "land", - "standard_name": "depth_of_frozen_soil", - "units": "m", - "cell_methods": "area: mean where land time: mean", - "cell_measures": "area: areacella", - "long_name": "Frozen Soil Depth", - "comment": "Depth from surface to the first zero degree isotherm. Above this isotherm T < 0o, and below this line T > 0o.", - "dimensions": "longitude latitude time", - "out_name": "dfr", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -372,16 +267,17 @@ "ok_max_mean_abs": "" }, "dgw": { + "frequency": "day", "modeling_realm": "land", - "standard_name": "change_over_time_in_groundwater", + "standard_name": "change_over_time_in_groundwater_amount", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", - "cell_measures": "area: areacella", + "cell_measures": "area: areacellr", "long_name": "Change in Groundwater", - "comment": "", + "comment": "Groundwater is subsurface water below the depth of the water table.", "dimensions": "longitude latitude time", "out_name": "dgw", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -389,16 +285,17 @@ "ok_max_mean_abs": "" }, "dmlt": { + "frequency": "day", "modeling_realm": "land", - "standard_name": "depth_of_subsurface_melting", + "standard_name": "depth_at_shallowest_isotherm_defined_by_soil_temperature", "units": "m", - "cell_methods": "area: mean where land time: mean", + "cell_methods": "area: time: mean where unfrozen_soil", "cell_measures": "area: areacella", - "long_name": "Depth to soil thaw", - "comment": "Depth from surface to the zero degree isotherm. Above this isotherm T > 0o, and below this line T < 0o.", - "dimensions": "longitude latitude time", + "long_name": "Depth to Soil Thaw", + "comment": "Depth from surface to the zero degree isotherm. Above this isotherm T > 0o, and below this line T < 0o. Missing if surface is frozen or if soil is unfrozen at all depths.", + "dimensions": "longitude latitude time stempzero", "out_name": "dmlt", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -406,16 +303,17 @@ "ok_max_mean_abs": "" }, "drivw": { + "frequency": "day", "modeling_realm": "land", "standard_name": "change_over_time_in_river_water_amount", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", - "cell_measures": "area: areacella", + "cell_measures": "area: areacellr", "long_name": "Change in River Storage", - "comment": "", + "comment": "Change over time of the mass of water per unit area in the fluvial system (stream and floodplain).", "dimensions": "longitude latitude time", "out_name": "drivw", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -423,16 +321,17 @@ "ok_max_mean_abs": "" }, "dslw": { + "frequency": "day", "modeling_realm": "land", - "standard_name": "change_over_time_in_water_content_of_soil_layer", + "standard_name": "change_over_time_in_mass_content_of_water_in_soil", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Change in soil moisture", - "comment": "", + "long_name": "Change in Soil Moisture", + "comment": "The phrase 'change_over_time_in_X' means change in a quantity X over a time-interval, which should be defined by the bounds of the time coordinate. 'Content' indicates a quantity per unit area. The mass content of water in soil refers to the vertical integral from the surface down to the bottom of the soil model. For the content between specified levels in the soil, standard names including 'content_of_soil_layer' are used. 'Water' means water in all phases.", "dimensions": "longitude latitude time", "out_name": "dslw", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -440,16 +339,17 @@ "ok_max_mean_abs": "" }, "dsn": { + "frequency": "day", "modeling_realm": "land", - "standard_name": "change_over_time_in_surface_snow_and_ice_amount", + "standard_name": "change_over_time_in_amount_of_ice_and_snow_on_land", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Change in snow water equivalent", - "comment": "", + "long_name": "Change in Snow Water Equivalent", + "comment": "Change in time of the mass per unit area of ice in glaciers, ice caps, ice sheets and shelves, river and lake ice, any other ice on a land surface, such as frozen flood water, and snow lying on such ice or on the land surface.", "dimensions": "longitude latitude time", "out_name": "dsn", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -457,16 +357,17 @@ "ok_max_mean_abs": "" }, "dsw": { + "frequency": "day", "modeling_realm": "land", - "standard_name": "change_over_time_in_surface_water_amount", + "standard_name": "change_over_time_in_land_water_amount", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", "long_name": "Change in Surface Water Storage", - "comment": "", + "comment": "The phrase 'land_water_amount', often known as 'Terrestrial Water Storage', includes: surface liquid water (water in rivers, wetlands, lakes, reservoirs, rainfall intercepted by the canopy); surface ice and snow (glaciers, ice caps, grounded ice sheets not displacing sea water, river and lake ice, other surface ice such as frozen flood water, snow lying on the surface and intercepted by the canopy); subsurface water (liquid and frozen soil water, groundwater).", "dimensions": "longitude latitude time", "out_name": "dsw", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -474,16 +375,17 @@ "ok_max_mean_abs": "" }, "dtes": { + "frequency": "day", "modeling_realm": "land", - "standard_name": "change_over_time_in_thermal_energy_content_of_surface", + "standard_name": "change_over_time_in_thermal_energy_content_of_vegetation_and_litter_and_soil", "units": "J m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Change in surface heat storage", + "long_name": "Change in Surface Heat Storage", "comment": "Change in heat storage over the soil layer and the vegetation for which the energy balance is calculated, accumulated over the sampling time interval.", "dimensions": "longitude latitude time", "out_name": "dtes", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -491,16 +393,17 @@ "ok_max_mean_abs": "" }, "dtesn": { + "frequency": "day", "modeling_realm": "land", - "standard_name": "change_over_time_in_thermal_energy_content_of_surface_snow_and_ice", + "standard_name": "change_over_time_in_thermal_energy_content_of_ice_and_snow_on_land", "units": "J m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Change in snow/ice cold content", + "long_name": "Change in Snow and Ice Cold Content", "comment": "Change in cold content over the snow layer for which the energy balance is calculated, accumulated over the sampling time interval. This should also include the energy contained in the liquid water in the snow pack.", "dimensions": "longitude latitude time", "out_name": "dtesn", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -508,33 +411,17 @@ "ok_max_mean_abs": "" }, "ec": { + "frequency": "day", "modeling_realm": "land", - "standard_name": "liquid_water_evaporation_flux_from_canopy", + "standard_name": "water_evaporation_flux_from_canopy", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Interception evaporation", - "comment": "", + "long_name": "Interception Evaporation", + "comment": "'Water' means water in all phases. 'Canopy' means the plant or vegetation canopy. Evaporation is the conversion of liquid or solid into vapor. (The conversion of solid alone into vapor is called 'sublimation'.) In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. Unless indicated in the cell_methods attribute, a quantity is assumed to apply to the whole area of each horizontal grid box. Previously, the qualifier where_type was used to specify that the quantity applies only to the part of the grid box of the named type. Names containing the where_type qualifier are deprecated and newly created data should use the cell_methods attribute to indicate the horizontal area to which the quantity applies.", "dimensions": "longitude latitude time", "out_name": "ec", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "ec550aer": { - "modeling_realm": "aerosol", - "standard_name": "volume_extinction_coefficient_in_air_due_to_ambient_aerosol_particles", - "units": "m-1", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "Aerosol extinction coefficient", - "comment": "Aerosol Extinction @550nm", - "dimensions": "longitude latitude time", - "out_name": "ec550aer", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -542,16 +429,17 @@ "ok_max_mean_abs": "" }, "eow": { + "frequency": "day", "modeling_realm": "land", - "standard_name": "liquid_water_evaporation_flux_from_open_water", + "standard_name": "surface_water_evaporation_flux", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", "long_name": "Open Water Evaporation", - "comment": "", + "comment": "Evaporation (conversion of liquid or solid into vapor) from open water. ", "dimensions": "longitude latitude time", "out_name": "eow", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -559,16 +447,17 @@ "ok_max_mean_abs": "" }, "es": { + "frequency": "day", "modeling_realm": "land", - "standard_name": "liquid_water_evaporation_flux_from_soil", + "standard_name": "water_evaporation_flux_from_soil", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Bare soil evaporation", - "comment": "", + "long_name": "Bare Soil Evaporation", + "comment": "Water here means water in all phases. Evaporation is the conversion of liquid or solid into vapor. (The conversion of solid alone into vapor is called 'sublimation'.) In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions": "longitude latitude time", "out_name": "es", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -576,33 +465,53 @@ "ok_max_mean_abs": "" }, "esn": { + "frequency": "day", "modeling_realm": "land", - "standard_name": "liquid_water_evaporation_flux_from_surface_snow", + "standard_name": "water_evapotranspiration_flux", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", "long_name": "Snow Evaporation", - "comment": "", + "comment": "Water here means water in all phases. Evaporation is the conversion of liquid or solid into vapor. (The conversion of solid alone into vapor is called 'sublimation'.) In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. Unless indicated in the cell_methods attribute, a quantity is assumed to apply to the whole area of each horizontal grid box. Previously, the qualifier where_type was used to specify that the quantity applies only to the part of the grid box of the named type. Names containing the where_type qualifier are deprecated and newly created data should use the cell_methods attribute to indicate the horizontal area to which the quantity applies.", "dimensions": "longitude latitude time", "out_name": "esn", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, - "et": { + "evspsbl": { + "frequency": "day", "modeling_realm": "land", - "standard_name": "surface_evapotranspiration", + "standard_name": "water_evapotranspiration_flux", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Total Evapotranspiration", - "comment": "", + "long_name": "Evaporation Including Sublimation and Transpiration", + "comment": "Evaporation at surface (also known as evapotranspiration): flux of water into the atmosphere due to conversion of both liquid and solid phases to vapor (from underlying surface and vegetation)", "dimensions": "longitude latitude time", - "out_name": "et", - "type": "", + "out_name": "evspsbl", + "type": "real", + "positive": "", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, + "evspsblpot": { + "frequency": "day", + "modeling_realm": "land", + "standard_name": "water_potential_evaporation_flux", + "units": "kg m-2 s-1", + "cell_methods": "area: mean where land time: mean", + "cell_measures": "area: areacella", + "long_name": "Potential Evapotranspiration", + "comment": "at surface; potential flux of water into the atmosphere due to conversion of both liquid and solid phases to vapor (from underlying surface and vegetation)", + "dimensions": "longitude latitude time", + "out_name": "evspsblpot", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -610,23 +519,25 @@ "ok_max_mean_abs": "" }, "hfdsl": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "surface_downward_heat_flux_in_air", "units": "W m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", "long_name": "Downward Heat Flux at Land Surface", - "comment": "", + "comment": "The surface called 'surface' means the lower boundary of the atmosphere. 'Downward' indicates a vector component which is positive when directed downward (negative upward). The vertical heat flux in air is the sum of all heat fluxes i.e. radiative, latent and sensible. In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions": "longitude latitude time", "out_name": "hfdsl", - "type": "", - "positive": "", + "type": "real", + "positive": "down", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "hfdsn": { + "frequency": "day", "modeling_realm": "landIce land", "standard_name": "surface_downward_heat_flux_in_snow", "units": "W m-2", @@ -644,30 +555,32 @@ "ok_max_mean_abs": "" }, "hfdsnb": { + "frequency": "day", "modeling_realm": "atmos", - "standard_name": "missing", + "standard_name": "downward_heat_flux_at_ground_level_in_snow", "units": "W m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Downward heat flux at snow base", + "long_name": "Downward Heat Flux at Snow Base", "comment": "Heat flux from snow into the ice or land under the snow.", "dimensions": "longitude latitude time", "out_name": "hfdsnb", - "type": "", - "positive": "", + "type": "real", + "positive": "down", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "hfls": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "surface_upward_latent_heat_flux", "units": "W m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", "long_name": "Surface Upward Latent Heat Flux", - "comment": "", + "comment": "The surface called 'surface' means the lower boundary of the atmosphere. 'Upward' indicates a vector component which is positive when directed upward (negative downward). The surface latent heat flux is the exchange of heat between the surface and the air on account of evaporation (including sublimation). In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions": "longitude latitude time", "out_name": "hfls", "type": "real", @@ -678,16 +591,17 @@ "ok_max_mean_abs": "" }, "hfmlt": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "surface_snow_and_ice_melt_heat_flux", "units": "W m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Energy of fusion", + "long_name": "Energy of Fusion", "comment": "Energy consumed or released during liquid/solid phase changes.", "dimensions": "longitude latitude time", "out_name": "hfmlt", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -695,33 +609,35 @@ "ok_max_mean_abs": "" }, "hfrs": { + "frequency": "day", "modeling_realm": "atmos", - "standard_name": "temperature_flux_due_to_rainfall_expressed_as_heat_flux_onto_snow_and_ice", + "standard_name": "tendency_of_thermal_energy_content_of_surface_snow_due_to_rainfall_temperature_excess_above_freezing", "units": "W m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Heat transferred to snowpack by rainfall", + "long_name": "Heat Transferred to Snowpack by Rainfall", "comment": "Heat transferred to a snow cover by rain..", "dimensions": "longitude latitude time", "out_name": "hfrs", - "type": "", - "positive": "", + "type": "real", + "positive": "down", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "hfsbl": { + "frequency": "day", "modeling_realm": "atmos", - "standard_name": "surface_snow_and_ice_sublimation_heat_flux", + "standard_name": "surface_upward_latent_heat_flux_due_to_sublimation", "units": "W m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Energy of sublimation", + "long_name": "Energy of Sublimation", "comment": "Energy consumed or released during vapor/solid phase changes.", "dimensions": "longitude latitude time", "out_name": "hfsbl", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -729,13 +645,14 @@ "ok_max_mean_abs": "" }, "hfss": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "surface_upward_sensible_heat_flux", "units": "W m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", "long_name": "Surface Upward Sensible Heat Flux", - "comment": "", + "comment": "The surface sensible heat flux, also called turbulent heat flux, is the exchange of heat between the surface and the air by motion of air.", "dimensions": "longitude latitude time", "out_name": "hfss", "type": "real", @@ -746,16 +663,17 @@ "ok_max_mean_abs": "" }, "hursminCrop": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "relative_humidity", "units": "%", - "cell_methods": "area: mean time: minimum", + "cell_methods": "area: mean where crops time: minimum", "cell_measures": "area: areacella", "long_name": "Daily Minimum Near-Surface Relative Humidity over Crop Tile", - "comment": "minimum near-surface (usually, 2 meter) relative humidity (add cell_method attribute 'time: min')", + "comment": "The relative humidity with respect to liquid water for T> 0 C, and with respect to ice for T<0 C.", "dimensions": "longitude latitude time height2m", "out_name": "hursminCrop", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -763,16 +681,17 @@ "ok_max_mean_abs": "" }, "hus": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "specific_humidity", - "units": "1.0", + "units": "1", "cell_methods": "time: mean", "cell_measures": "area: areacella", "long_name": "Specific Humidity", - "comment": "", + "comment": "Specific humidity is the mass fraction of water vapor in (moist) air.", "dimensions": "longitude latitude plev19 time", "out_name": "hus", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -780,33 +699,17 @@ "ok_max_mean_abs": "" }, "hus850": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "specific_humidity", - "units": "1.0", + "units": "1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Specific Humidity", - "comment": "", + "comment": "Specific humidity is the mass fraction of water vapor in (moist) air.", "dimensions": "longitude latitude time p850", "out_name": "hus850", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "inc": { - "modeling_realm": "atmos", - "standard_name": "number_concentration_of_ice_crystals_in_air", - "units": "m-3", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "Ice Crystal Number Concentration", - "comment": "Ice Crystal number concentration in ice clouds", - "dimensions": "longitude latitude time", - "out_name": "inc", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -814,16 +717,17 @@ "ok_max_mean_abs": "" }, "jpdftaureicemodis": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "cloud_area_fraction_in_atmosphere_layer", "units": "%", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "MODIS Optical Thickness-Particle Size joint distribution, ice", - "comment": "", - "dimensions": "longitude latitude plev7c effectRadLi tau time", + "long_name": "MODIS Joint Distribution of Optical Thickness and Particle Size, Ice", + "comment": "Joint probability distribution function, giving probability of cloud as a function of optical thickness and particle size, as measured by MODIS. For cloud ice particles.", + "dimensions": "longitude latitude effectRadIc tau time", "out_name": "jpdftaureicemodis", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -831,16 +735,17 @@ "ok_max_mean_abs": "" }, "jpdftaureliqmodis": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "cloud_area_fraction_in_atmosphere_layer", "units": "%", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "MODIS Optical Thickness-Particle Size joint distribution, liquid", - "comment": "", - "dimensions": "longitude latitude plev7c effectRadLi tau time", + "long_name": "MODIS Optical Thickness-Particle Size Joint Distribution, Liquid", + "comment": "Joint probability distribution function, giving probability of cloud as a function of optical thickness and particle size, as measured by MODIS. For liquid cloud particles.", + "dimensions": "longitude latitude effectRadLi tau time", "out_name": "jpdftaureliqmodis", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -848,16 +753,17 @@ "ok_max_mean_abs": "" }, "lai": { + "frequency": "day", "modeling_realm": "land", "standard_name": "leaf_area_index", - "units": "1.0", + "units": "1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", "long_name": "Leaf Area Index", - "comment": "", + "comment": "A ratio obtained by dividing the total upper leaf surface area of vegetation by the (horizontal) surface area of the land on which it grows.", "dimensions": "longitude latitude time", "out_name": "lai", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -865,16 +771,17 @@ "ok_max_mean_abs": "" }, "loadbc": { + "frequency": "day", "modeling_realm": "atmos", - "standard_name": "atmosphere_mass_content_of_black_carbon_dry_aerosol", + "standard_name": "atmosphere_mass_content_of_elemental_carbon_dry_aerosol_particles", "units": "kg m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Load of Black Carbon Aerosol", - "comment": "", + "comment": "The total dry mass of black carbon aerosol particles per unit area.", "dimensions": "longitude latitude time", "out_name": "loadbc", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -882,16 +789,17 @@ "ok_max_mean_abs": "" }, "loaddust": { + "frequency": "day", "modeling_realm": "atmos", - "standard_name": "atmosphere_mass_content_of_dust_dry_aerosol", + "standard_name": "atmosphere_mass_content_of_dust_dry_aerosol_particles", "units": "kg m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Load of Dust", - "comment": "", + "comment": "The total dry mass of dust aerosol particles per unit area.", "dimensions": "longitude latitude time", "out_name": "loaddust", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -899,16 +807,17 @@ "ok_max_mean_abs": "" }, "loadnh4": { + "frequency": "day", "modeling_realm": "atmos", - "standard_name": "atmosphere_mass_content_of_ammonium_dry_aerosol", + "standard_name": "atmosphere_mass_content_of_ammonium_dry_aerosol_particles", "units": "kg m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Load of NH4", - "comment": "", + "comment": "The total dry mass of ammonium aerosol particles per unit area.", "dimensions": "longitude latitude time", "out_name": "loadnh4", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -916,16 +825,17 @@ "ok_max_mean_abs": "" }, "loadno3": { + "frequency": "day", "modeling_realm": "atmos", - "standard_name": "atmosphere_mass_content_of_nitrate_dry_aerosol", + "standard_name": "atmosphere_mass_content_of_nitrate_dry_aerosol_particles", "units": "kg m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Load of NO3", - "comment": "", + "comment": "The total dry mass of nitrate aerosol particles per unit area.", "dimensions": "longitude latitude time", "out_name": "loadno3", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -933,8 +843,9 @@ "ok_max_mean_abs": "" }, "loadoa": { + "frequency": "day", "modeling_realm": "atmos", - "standard_name": "atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol", + "standard_name": "atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_particles", "units": "kg m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", @@ -942,7 +853,7 @@ "comment": "atmosphere dry organic content: This is the vertically integrated sum of atmosphere_primary_organic_content and atmosphere_secondary_organic_content (see next two table entries).", "dimensions": "longitude latitude time", "out_name": "loadoa", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -950,16 +861,17 @@ "ok_max_mean_abs": "" }, "loadpoa": { + "frequency": "day", "modeling_realm": "atmos", - "standard_name": "atmosphere_mass_content_of_primary_particulate_organic_matter_dry_aerosol", + "standard_name": "atmosphere_mass_content_of_primary_particulate_organic_matter_dry_aerosol_particles", "units": "kg m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Load of Dry Aerosol Primary Organic Matter", - "comment": "", + "comment": "The total dry mass of primary particulate organic aerosol particles per unit area.", "dimensions": "longitude latitude time", "out_name": "loadpoa", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -967,16 +879,17 @@ "ok_max_mean_abs": "" }, "loadso4": { + "frequency": "day", "modeling_realm": "atmos", - "standard_name": "atmosphere_mass_content_of_sulfate_dry_aerosol", + "standard_name": "atmosphere_mass_content_of_sulfate_dry_aerosol_particles", "units": "kg m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Load of SO4", - "comment": "", + "comment": "The total dry mass of sulfate aerosol particles per unit area.", "dimensions": "longitude latitude time", "out_name": "loadso4", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -984,16 +897,17 @@ "ok_max_mean_abs": "" }, "loadsoa": { + "frequency": "day", "modeling_realm": "atmos", - "standard_name": "atmosphere_mass_content_of_secondary_particulate_organic_matter_dry_aerosol", + "standard_name": "atmosphere_mass_content_of_secondary_particulate_organic_matter_dry_aerosol_particles", "units": "kg m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Load of Dry Aerosol Secondary Organic Matter", - "comment": "", + "comment": "The total dry mass of secondary particulate organic aerosol particles per unit area.", "dimensions": "longitude latitude time", "out_name": "loadsoa", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1001,16 +915,17 @@ "ok_max_mean_abs": "" }, "loadss": { + "frequency": "day", "modeling_realm": "atmos", - "standard_name": "atmosphere_mass_content_of_seasalt_dry_aerosol", + "standard_name": "atmosphere_mass_content_of_sea_salt_dry_aerosol_particles", "units": "kg m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Load of Seasalt", - "comment": "", + "long_name": "Load of Sea-Salt Aerosol", + "comment": "The total dry mass of sea salt aerosol particles per unit area.", "dimensions": "longitude latitude time", "out_name": "loadss", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1018,8 +933,9 @@ "ok_max_mean_abs": "" }, "lwsnl": { + "frequency": "day", "modeling_realm": "landIce land", - "standard_name": "liquid_water_content_of_snow_layer", + "standard_name": "liquid_water_content_of_surface_snow", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", @@ -1035,11 +951,12 @@ "ok_max_mean_abs": "" }, "mlotst": { + "frequency": "day", "modeling_realm": "ocean", "standard_name": "ocean_mixed_layer_thickness_defined_by_sigma_t", "units": "m", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", + "cell_methods": "area: mean where sea time: mean", + "cell_measures": "area: areacello", "long_name": "Ocean Mixed Layer Thickness Defined by Sigma T", "comment": "Sigma T is potential density referenced to ocean surface.", "dimensions": "longitude latitude time", @@ -1052,16 +969,17 @@ "ok_max_mean_abs": "" }, "mrfsofr": { + "frequency": "day", "modeling_realm": "land", "standard_name": "mass_fraction_of_frozen_water_in_soil_moisture", - "units": "1.0", + "units": "1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Average layer fraction of frozen moisture", + "long_name": "Average Layer Fraction of Frozen Moisture", "comment": "Fraction of soil moisture mass in the solid phase in each user-defined soil layer (3D variable)", "dimensions": "longitude latitude sdepth time", "out_name": "mrfsofr", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1069,32 +987,16 @@ "ok_max_mean_abs": "" }, "mrlqso": { + "frequency": "day", "modeling_realm": "land", "standard_name": "mass_fraction_of_unfrozen_water_in_soil_moisture", - "units": "1.0", + "units": "1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Average layer fraction of liquid moisture", + "long_name": "Average Layer Fraction of Liquid Moisture", "comment": "Fraction of soil moisture mass in the liquid phase in each user-defined soil layer (3D variable)", "dimensions": "longitude latitude sdepth time", "out_name": "mrlqso", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "mrlsl": { - "modeling_realm": "land", - "standard_name": "moisture_content_of_soil_layer", - "units": "kg m-2", - "cell_methods": "area: mean where land time: mean", - "cell_measures": "area: areacella", - "long_name": "Water Content of Soil Layer", - "comment": "The mass of water in all phases, including ice, in soil layers. Report as missing for grid cells with no land.", - "dimensions": "longitude latitude sdepth time", - "out_name": "mrlsl", "type": "real", "positive": "", "valid_min": "", @@ -1103,16 +1005,17 @@ "ok_max_mean_abs": "" }, "mrrob": { + "frequency": "day", "modeling_realm": "land", "standard_name": "subsurface_runoff_flux", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Subsurface runoff", - "comment": "", + "long_name": "Subsurface Runoff", + "comment": "Runoff is the liquid water which drains from land. If not specified, 'runoff' refers to the sum of surface runoff and subsurface drainage. In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions": "longitude latitude time", "out_name": "mrrob", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1120,6 +1023,7 @@ "ok_max_mean_abs": "" }, "mrros": { + "frequency": "day", "modeling_realm": "land", "standard_name": "surface_runoff_flux", "units": "kg m-2 s-1", @@ -1137,16 +1041,17 @@ "ok_max_mean_abs": "" }, "mrsfl": { + "frequency": "day", "modeling_realm": "land", - "standard_name": "frozen_moisture_content_of_soil_layer", + "standard_name": "frozen_water_content_of_soil_layer", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Frozen water content of soil layer", + "long_name": "Frozen Water Content of Soil Layer", "comment": "in each soil layer, the mass of water in ice phase. Reported as 'missing' for grid cells occupied entirely by 'sea'", "dimensions": "longitude latitude sdepth time", "out_name": "mrsfl", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1154,16 +1059,17 @@ "ok_max_mean_abs": "" }, "mrsll": { + "frequency": "day", "modeling_realm": "land", - "standard_name": "liquid_moisture_content_of_soil_layer", + "standard_name": "liquid_water_content_of_soil_layer", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Liquid water content of soil layer", + "long_name": "Liquid Water Content of Soil Layer", "comment": "in each soil layer, the mass of water in liquid phase. Reported as 'missing' for grid cells occupied entirely by 'sea'", "dimensions": "longitude latitude sdepth time", "out_name": "mrsll", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1171,16 +1077,17 @@ "ok_max_mean_abs": "" }, "mrsol": { + "frequency": "day", "modeling_realm": "land", - "standard_name": "moisture_content_of_soil_layer", + "standard_name": "mass_content_of_water_in_soil_layer", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Total water content of soil layer", + "long_name": "Total Water Content of Soil Layer", "comment": "in each soil layer, the mass of water in all phases, including ice. Reported as 'missing' for grid cells occupied entirely by 'sea'", "dimensions": "longitude latitude sdepth time", "out_name": "mrsol", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1188,16 +1095,35 @@ "ok_max_mean_abs": "" }, "mrsow": { + "frequency": "day", "modeling_realm": "land", "standard_name": "volume_fraction_of_condensed_water_in_soil_at_field_capacity", - "units": "1.0", + "units": "1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", "long_name": "Total Soil Wetness", "comment": "Vertically integrated soil moisture divided by maximum allowable soil moisture above wilting point.", "dimensions": "longitude latitude time", "out_name": "mrsow", - "type": "", + "type": "real", + "positive": "", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, + "mrtws": { + "frequency": "day", + "modeling_realm": "land", + "standard_name": "land_water_amount", + "units": "kg m-2", + "cell_methods": "area: mean where land time: mean", + "cell_measures": "area: areacella", + "long_name": "Terrestrial Water Storage", + "comment": "Mass of water in all phases and in all components including soil, canopy, vegetation, ice sheets, rivers and ground water.", + "dimensions": "longitude latitude time", + "out_name": "mrtws", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1205,16 +1131,17 @@ "ok_max_mean_abs": "" }, "nudgincsm": { + "frequency": "day", "modeling_realm": "land", - "standard_name": "nudging_increment_in_water_content_of_soil_layer", + "standard_name": "nudging_increment_in_mass_content_of_water_in_soil", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Nudging Increment of Water in Soil Mositure", - "comment": "", + "long_name": "Nudging Increment of Water in Soil Moisture", + "comment": "A nudging increment refers to an amount added to parts of a model system. The phrase 'nudging_increment_in_X' refers to an increment in quantity X over a time period which should be defined in the bounds of the time coordinate. 'Content' indicates a quantity per unit area. 'Water' means water in all phases. The mass content of water in soil refers to the vertical integral from the surface down to the bottom of the soil model. The 'soil content' of a quantity refers to the vertical integral from the surface down to the bottom of the soil model. For the content between specified levels in the soil, standard names including 'content_of_soil_layer' are used.", "dimensions": "longitude latitude time", "out_name": "nudgincsm", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1222,16 +1149,17 @@ "ok_max_mean_abs": "" }, "nudgincswe": { + "frequency": "day", "modeling_realm": "land", - "standard_name": "nudging_increment_in_surface_snow_and_ice_amount", + "standard_name": "nudging_increment_in_snow_and_ice_amount_on_land", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", "long_name": "Nudging Increment of Water in Snow", - "comment": "", + "comment": "A nudging increment refers to an amount added to parts of a model system. The phrase 'nudging_increment_in_X' refers to an increment in quantity X over a time period which should be defined in the bounds of the time coordinate. The surface called 'surface' means the lower boundary of the atmosphere. 'Amount' means mass per unit area. 'Snow and ice on land' means ice in glaciers, ice caps, ice sheets & shelves, river and lake ice, any other ice on a land surface, such as frozen flood water, and snow lying on such ice or on the land surface.", "dimensions": "longitude latitude time", "out_name": "nudgincswe", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1239,9 +1167,10 @@ "ok_max_mean_abs": "" }, "parasolRefl": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "toa_bidirectional_reflectance", - "units": "1.0", + "units": "1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacella", "long_name": "PARASOL Reflectance", @@ -1256,6 +1185,7 @@ "ok_max_mean_abs": "" }, "pflw": { + "frequency": "day", "modeling_realm": "landIce land", "standard_name": "liquid_water_content_of_permafrost_layer", "units": "kg m-2", @@ -1272,34 +1202,18 @@ "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, - "potet": { - "modeling_realm": "land", - "standard_name": "water_potential_evapotranspiration_flux", - "units": "kg m-2 s-1", - "cell_methods": "area: mean where land time: mean", - "cell_measures": "area: areacella", - "long_name": "Potential Evapotranspiration", - "comment": "", - "dimensions": "longitude latitude time", - "out_name": "potet", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, "prCrop": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "precipitation_flux", "units": "kg m-2 s-1", - "cell_methods": "area: time: mean", + "cell_methods": "area: time: mean where crops (comment: mask=cropFrac)", "cell_measures": "area: areacella", "long_name": "Precipitation over Crop Tile", "comment": "includes both liquid and solid phases", "dimensions": "longitude latitude time", "out_name": "prCrop", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1307,16 +1221,17 @@ "ok_max_mean_abs": "" }, "prhmax": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "precipitation_flux", "units": "kg m-2 s-1", - "cell_methods": "area: time: mean", + "cell_methods": "area: mean time: mean within hours time: maximum over hours", "cell_measures": "area: areacella", "long_name": "Maximum Hourly Precipitation Rate", - "comment": "", + "comment": "In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions": "longitude latitude time", "out_name": "prhmax", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1324,13 +1239,14 @@ "ok_max_mean_abs": "" }, "prra": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "rainfall_flux", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Rainfall Flux where Ice Free Ocean over Sea", - "comment": "", + "long_name": "Rainfall Flux over Land", + "comment": "In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions": "longitude latitude time", "out_name": "prra", "type": "real", @@ -1341,16 +1257,17 @@ "ok_max_mean_abs": "" }, "prrc": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "convective_rainfall_flux", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Convective Rainfall rate", - "comment": "", + "long_name": "Convective Rainfall Rate", + "comment": "In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions": "longitude latitude time", "out_name": "prrc", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1358,16 +1275,17 @@ "ok_max_mean_abs": "" }, "prrsn": { + "frequency": "day", "modeling_realm": "atmos", - "standard_name": "mass_fraction_of_rainfall_onto_snow", + "standard_name": "mass_fraction_of_rainfall_falling_onto_surface_snow", "units": "1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Fraction of rainfall on snow.", + "long_name": "Fraction of Rainfall on Snow", "comment": "The fraction of the grid averaged rainfall which falls on the snow pack", "dimensions": "longitude latitude time", "out_name": "prrsn", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1375,6 +1293,7 @@ "ok_max_mean_abs": "" }, "prsnc": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "convective_snowfall_flux", "units": "kg m-2 s-1", @@ -1392,16 +1311,17 @@ "ok_max_mean_abs": "" }, "prsnsn": { + "frequency": "day", "modeling_realm": "atmos", - "standard_name": "mass_fraction_of_snowfall_onto_snow", + "standard_name": "mass_fraction_of_solid_precipitation_falling_onto_surface_snow", "units": "1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Fraction of snowfall on snow.", + "long_name": "Fraction of Snowfall (Including Hail and Graupel) on Snow", "comment": "The fraction of the snowfall which falls on the snow pack", "dimensions": "longitude latitude time", "out_name": "prsnsn", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1409,6 +1329,7 @@ "ok_max_mean_abs": "" }, "prveg": { + "frequency": "day", "modeling_realm": "land", "standard_name": "precipitation_flux_onto_canopy", "units": "kg m-2 s-1", @@ -1426,8 +1347,9 @@ "ok_max_mean_abs": "" }, "prw": { + "frequency": "day", "modeling_realm": "atmos", - "standard_name": "atmosphere_water_vapor_content", + "standard_name": "atmosphere_mass_content_of_water_vapor", "units": "kg m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", @@ -1443,16 +1365,17 @@ "ok_max_mean_abs": "" }, "qgwr": { + "frequency": "day", "modeling_realm": "land", - "standard_name": "water_flux_from_soil_layer_to_groundwater", + "standard_name": "downward_liquid_water_mass_flux_into_groundwater", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", - "cell_measures": "area: areacella", - "long_name": "Groundwater recharge from soil layer", - "comment": "", + "cell_measures": "area: areacellr", + "long_name": "Groundwater Recharge from Soil Layer", + "comment": "Mass flux of water from the soil layer into ground water.", "dimensions": "longitude latitude time", "out_name": "qgwr", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1460,49 +1383,16 @@ "ok_max_mean_abs": "" }, "reffcclwtop": { + "frequency": "day", "modeling_realm": "atmos", - "standard_name": "effective_radius_of_convective_cloud_liquid_water_particle_at_liquid_water_cloud_top", + "standard_name": "effective_radius_of_convective_cloud_liquid_water_particle_at_convective_liquid_water_cloud_top", "units": "m", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Cloud-Top Effective Droplet Radius In Convective Cloud", + "long_name": "Cloud-Top Effective Droplet Radius in Convective Cloud", "comment": "Droplets are liquid only. This is the effective radius 'as seen from space' over convective liquid cloudy portion of grid cell. This is the value from uppermost model layer with liquid cloud or, if available, or for some models it is the sum over all liquid cloud tops, no matter where they occur, as long as they are seen from the top of the atmosphere. Reported values are weighted by total liquid cloud top fraction of (as seen from TOA) each time sample when computing monthly mean.daily data, separated to large-scale clouds, convective clouds. If any of the cloud is from more than one process (i.e. shallow convection), please provide them separately.", "dimensions": "longitude latitude time", "out_name": "reffcclwtop", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "reffclwc": { - "modeling_realm": "atmos", - "standard_name": "effective_radius_of_convective_cloud_liquid_water_particle", - "units": "m", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "Hydrometeor Effective Radius of Convective Cloud Liquid Water", - "comment": "Droplets are liquid. The effective radius is defined as the ratio of the third moment over the second moment of the particle size distribution and the time-mean should be calculated, weighting the individual samples by the cloudy fraction of the grid cell.", - "dimensions": "longitude latitude time", - "out_name": "reffclwc", - "type": "real", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "reffclws": { - "modeling_realm": "atmos", - "standard_name": "effective_radius_of_stratiform_cloud_liquid_water_particle", - "units": "m", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "Hydrometeor Effective Radius of Stratiform Cloud Liquid Water", - "comment": "Droplets are liquid. The effective radius is defined as the ratio of the third moment over the second moment of the particle size distribution and the time-mean should be calculated, weighting the individual samples by the cloudy fraction of the grid cell.", - "dimensions": "longitude latitude time", - "out_name": "reffclws", "type": "real", "positive": "", "valid_min": "", @@ -1511,16 +1401,17 @@ "ok_max_mean_abs": "" }, "reffsclwtop": { + "frequency": "day", "modeling_realm": "atmos", - "standard_name": "effective_radius_of_stratiform_cloud_liquid_water_particle_at_liquid_water_cloud_top", + "standard_name": "effective_radius_of_stratiform_cloud_liquid_water_particle_at_stratiform_liquid_water_cloud_top", "units": "m", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Cloud-Top Effective Droplet Radius In Stratiform Cloud", + "long_name": "Cloud-Top Effective Droplet Radius in Stratiform Cloud", "comment": "Droplets are liquid only. This is the effective radius 'as seen from space' over liquid stratiform cloudy portion of grid cell. This is the value from uppermost model layer with liquid cloud or, if available, or for some models it is the sum over all liquid cloud tops, no matter where they occur, as long as they are seen from the top of the atmosphere. Reported values are weighted by total liquid cloud top fraction of (as seen from TOA) each time sample when computing monthly mean.daily data, separated to large-scale clouds, convective clouds. If any of the cloud is from more than one process (i.e. shallow convection), please provide them separately.", "dimensions": "longitude latitude time", "out_name": "reffsclwtop", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1528,16 +1419,17 @@ "ok_max_mean_abs": "" }, "rivi": { + "frequency": "day", "modeling_realm": "land", - "standard_name": "water_flux_from_upstream", + "standard_name": "incoming_water_volume_transport_along_river_channel", "units": "m3 s-1", "cell_methods": "area: mean where land time: mean", - "cell_measures": "area: areacella", + "cell_measures": "area: areacellr", "long_name": "River Inflow", "comment": "Inflow of River Water into Cell", "dimensions": "longitude latitude time", "out_name": "rivi", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1545,16 +1437,17 @@ "ok_max_mean_abs": "" }, "rivo": { + "frequency": "day", "modeling_realm": "land", - "standard_name": "water_flux_to_downstream", + "standard_name": "outgoing_water_volume_transport_along_river_channel", "units": "m3 s-1", "cell_methods": "area: mean where land time: mean", - "cell_measures": "area: areacella", + "cell_measures": "area: areacellr", "long_name": "River Discharge", "comment": "Outflow of River Water from Cell", "dimensions": "longitude latitude time", "out_name": "rivo", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1562,6 +1455,7 @@ "ok_max_mean_abs": "" }, "rls": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "surface_net_downward_longwave_flux", "units": "W m-2", @@ -1571,48 +1465,51 @@ "comment": "Net longwave surface radiation", "dimensions": "longitude latitude time", "out_name": "rls", - "type": "", - "positive": "", + "type": "real", + "positive": "down", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "rsdscsdiff": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "surface_diffuse_downwelling_shortwave_flux_in_air_assuming_clear_sky", "units": "W m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Surface Diffuse Downwelling Clear Sky Shortwave Radiation", - "comment": "", + "comment": "Surface downwelling solar irradiance from diffuse radiation for UV calculations in clear sky conditions", "dimensions": "longitude latitude time", "out_name": "rsdscsdiff", - "type": "", - "positive": "", + "type": "real", + "positive": "down", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "rsdsdiff": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "surface_diffuse_downwelling_shortwave_flux_in_air", "units": "W m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Surface Diffuse Downwelling Shortwave Radiation", - "comment": "", + "comment": "Surface downwelling solar irradiance from diffuse radiation for UV calculations.", "dimensions": "longitude latitude time", "out_name": "rsdsdiff", "type": "real", - "positive": "", + "positive": "down", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "rss": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "surface_net_downward_shortwave_flux", "units": "W m-2", @@ -1622,24 +1519,25 @@ "comment": "Net downward shortwave radiation at the surface", "dimensions": "longitude latitude time", "out_name": "rss", - "type": "", - "positive": "", + "type": "real", + "positive": "down", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "rzwc": { + "frequency": "day", "modeling_realm": "land", - "standard_name": "water_content_of_root_zone", + "standard_name": "mass_content_of_water_in_soil_layer_defined_by_root_depth", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Root zone soil moisture", - "comment": "", + "long_name": "Root Zone Soil Moisture", + "comment": "'Content' indicates a quantity per unit area. The content of a soil layer is the vertical integral of the specified quantity within the layer. The quantity with standard name mass_content_of_water_in_soil_layer_defined_by_root_depth is the vertical integral between the surface and the depth to which plant roots penetrate. A coordinate variable or scalar coordinate variable with standard name root_depth can be used to specify the extent of the layer. 'Water' means water in all phases.", "dimensions": "longitude latitude time", "out_name": "rzwc", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1647,8 +1545,9 @@ "ok_max_mean_abs": "" }, "sbl": { + "frequency": "day", "modeling_realm": "landIce", - "standard_name": "surface_snow_and_ice_sublimation_flux", + "standard_name": "tendency_of_atmosphere_mass_content_of_water_vapor_due_to_sublimation_of_surface_snow_and_ice", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", @@ -1663,34 +1562,36 @@ "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, - "scldncl": { + "sblnosn": { + "frequency": "day", "modeling_realm": "atmos", - "standard_name": "number_concentration_of_stratiform_cloud_liquid_water_particles_in_air_at_liquid_water_cloud_top", - "units": "m-3", - "cell_methods": "area: time: mean", + "standard_name": "tendency_of_atmosphere_mass_content_of_water_vapor_due_to_sublimation_of_surface_ice", + "units": "kg m-2 s-1", + "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Cloud Droplet Number Concentration of Stratiform Cloud Tops", - "comment": "Droplets are liquid only. Report concentration 'as seen from space' over stratiform liquid cloudy portion of grid cell. This is the value from uppermost model layer with liquid cloud or, if available, it is better to sum over all liquid cloud tops, no matter where they occur, as long as they are seen from the top of the atmosphere. Weight by total liquid cloud top fraction of (as seen from TOA) each time sample when computing monthly mean.", + "long_name": "Sublimation of the Snow Free Area", + "comment": "Rate of sublimation of ice into the atmosphere from areas with no snow.", "dimensions": "longitude latitude time", - "out_name": "scldncl", - "type": "", + "out_name": "sblnosn", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, - "slbnosn": { + "scldncl": { + "frequency": "day", "modeling_realm": "atmos", - "standard_name": "sublimation_amount_assuming_no_snow", - "units": "kg m-2 s-1", - "cell_methods": "area: mean where land time: mean", + "standard_name": "number_concentration_of_stratiform_cloud_liquid_water_particle_at_stratiform_liquid_water_cloud_top", + "units": "m-3", + "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Sublimation of the snow free area", - "comment": "", + "long_name": "Cloud Droplet Number Concentration of Stratiform Cloud Tops", + "comment": "Droplets are liquid only. Report concentration 'as seen from space' over stratiform liquid cloudy portion of grid cell. This is the value from uppermost model layer with liquid cloud or, if available, it is better to sum over all liquid cloud tops, no matter where they occur, as long as they are seen from the top of the atmosphere. Weight by total liquid cloud top fraction of (as seen from TOA) each time sample when computing monthly mean.", "dimensions": "longitude latitude time", - "out_name": "slbnosn", - "type": "", + "out_name": "scldncl", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1698,6 +1599,7 @@ "ok_max_mean_abs": "" }, "snd": { + "frequency": "day", "modeling_realm": "landIce land", "standard_name": "surface_snow_thickness", "units": "m", @@ -1715,6 +1617,7 @@ "ok_max_mean_abs": "" }, "snm": { + "frequency": "day", "modeling_realm": "landIce land", "standard_name": "surface_snow_melt_flux", "units": "kg m-2 s-1", @@ -1732,16 +1635,17 @@ "ok_max_mean_abs": "" }, "snmsl": { + "frequency": "day", "modeling_realm": "atmos", - "standard_name": "surface_snow_melt_flux_into_soil_layer", + "standard_name": "liquid_water_mass_flux_into_soil_due_to_surface_snow_melt", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Water flowing out of snowpack", - "comment": "", + "long_name": "Water Flowing out of Snowpack", + "comment": "Mass flow rate of water draining out of the snow pack.", "dimensions": "longitude latitude time", "out_name": "snmsl", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1749,16 +1653,17 @@ "ok_max_mean_abs": "" }, "snrefr": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "surface_snow_and_ice_refreezing_flux", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Re-freezing of water in the snow", - "comment": "", + "long_name": "Refreezing of Water in the Snow", + "comment": "In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. The surface called 'surface' means the lower boundary of the atmosphere. 'Surface snow and ice refreezing flux' means the mass flux of surface meltwater which refreezes within the snow or firn.", "dimensions": "longitude latitude time", "out_name": "snrefr", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1766,16 +1671,17 @@ "ok_max_mean_abs": "" }, "snwc": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "canopy_snow_amount", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "SWE intercepted by the vegetation", - "comment": "Total water mass of the snowpack (liquid or frozen), averaged over a grid cell and interecepted by the canopy.", + "long_name": " snow water equivalent intercepted by the vegetation", + "comment": "Total water mass of the snowpack (liquid or frozen), averaged over a grid cell and intercepted by the canopy.", "dimensions": "longitude latitude time", "out_name": "snwc", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1783,6 +1689,7 @@ "ok_max_mean_abs": "" }, "sootsn": { + "frequency": "day", "modeling_realm": "landIce land", "standard_name": "soot_content_of_surface_snow", "units": "kg m-2", @@ -1800,8 +1707,9 @@ "ok_max_mean_abs": "" }, "sw": { + "frequency": "day", "modeling_realm": "land", - "standard_name": "surface_water_amount_assuming_no_snow", + "standard_name": "land_surface_liquid_water_amount", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", @@ -1809,7 +1717,7 @@ "comment": "Total liquid water storage, other than soil, snow or interception storage (i.e. lakes, river channel or depression storage).", "dimensions": "longitude latitude time", "out_name": "sw", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1817,16 +1725,17 @@ "ok_max_mean_abs": "" }, "t20d": { + "frequency": "day", "modeling_realm": "ocean", "standard_name": "depth_of_isosurface_of_sea_water_potential_temperature", "units": "m", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "20C isotherm depth", - "comment": "", + "cell_methods": "area: mean where sea time: mean", + "cell_measures": "area: areacello", + "long_name": "Depth of 20 degree Celsius Isotherm", + "comment": "This quantity, sometimes called the 'isotherm depth', is the depth (if it exists) at which the sea water potential temperature equals some specified value. This value should be specified in a scalar coordinate variable. Depth is the vertical distance below the surface. Potential temperature is the temperature a parcel of air or sea water would have if moved adiabatically to sea level pressure.", "dimensions": "longitude latitude time", "out_name": "t20d", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1834,6 +1743,7 @@ "ok_max_mean_abs": "" }, "ta": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "air_temperature", "units": "K", @@ -1843,7 +1753,7 @@ "comment": "Air Temperature", "dimensions": "longitude latitude plev19 time", "out_name": "ta", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1851,6 +1761,7 @@ "ok_max_mean_abs": "" }, "ta500": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "air_temperature", "units": "K", @@ -1860,7 +1771,7 @@ "comment": "Temperature on the 500 hPa surface", "dimensions": "longitude latitude time p500", "out_name": "ta500", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1868,6 +1779,7 @@ "ok_max_mean_abs": "" }, "ta850": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "air_temperature", "units": "K", @@ -1877,7 +1789,7 @@ "comment": "Air temperature at 850hPa", "dimensions": "longitude latitude time p850", "out_name": "ta850", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1885,16 +1797,17 @@ "ok_max_mean_abs": "" }, "tasmaxCrop": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "air_temperature", "units": "K", - "cell_methods": "area: mean time: maximum", + "cell_methods": "area: mean where crops time: maximum", "cell_measures": "area: areacella", "long_name": "Daily Maximum Near-Surface Air Temperature over Crop Tile", "comment": "maximum near-surface (usually, 2 meter) air temperature (add cell_method attribute 'time: max')", "dimensions": "longitude latitude time height2m", "out_name": "tasmaxCrop", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1902,16 +1815,17 @@ "ok_max_mean_abs": "" }, "tasminCrop": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "air_temperature", "units": "K", - "cell_methods": "area: mean time: minimum", + "cell_methods": "area: mean where crops time: minimum", "cell_measures": "area: areacella", "long_name": "Daily Minimum Near-Surface Air Temperature over Crop Tile", "comment": "minimum near-surface (usually, 2 meter) air temperature (add cell_method attribute 'time: min')", "dimensions": "longitude latitude time height2m", "out_name": "tasminCrop", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1919,16 +1833,17 @@ "ok_max_mean_abs": "" }, "tau": { + "frequency": "day", "modeling_realm": "atmos", - "standard_name": "surface_downward_stress", + "standard_name": "magnitude_of_surface_downward_stress", "units": "N m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Momentum flux", + "long_name": "Momentum Flux", "comment": "module of the momentum lost by the atmosphere to the surface.", "dimensions": "longitude latitude time", "out_name": "tau", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1936,6 +1851,7 @@ "ok_max_mean_abs": "" }, "tauu": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "surface_downward_eastward_stress", "units": "Pa", @@ -1953,16 +1869,17 @@ "ok_max_mean_abs": "" }, "tauupbl": { + "frequency": "day", "modeling_realm": "atmos", - "standard_name": "surface_downward_eastward_stress_due_to_planetary_boundary_layer", + "standard_name": "surface_downward_eastward_stress_due_to_boundary_layer_mixing", "units": "Pa", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "eastward surface stress from planetary boundary layer scheme", - "comment": "The downward eastward stress associated with the models parameterization of the plantary boundary layer. (This request is related to a WGNE effort to understand how models parameterize the surface stresses.)", + "long_name": "Eastward Surface Stress from Planetary Boundary Layer Scheme", + "comment": "The downward eastward stress associated with the models parameterization of the planetary boundary layer. (This request is related to a WGNE effort to understand how models parameterize the surface stresses.)", "dimensions": "longitude latitude time", "out_name": "tauupbl", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1970,6 +1887,7 @@ "ok_max_mean_abs": "" }, "tauv": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "surface_downward_northward_stress", "units": "Pa", @@ -1987,16 +1905,17 @@ "ok_max_mean_abs": "" }, "tauvpbl": { + "frequency": "day", "modeling_realm": "atmos", - "standard_name": "surface_downward_northward_stress_due_to_planetary_boundary_layer", + "standard_name": "surface_downward_northward_stress_due_to_boundary_layer_mixing", "units": "Pa", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "northward surface stress from planetary boundary layer scheme", - "comment": "The downward northward stress associated with the models parameterization of the plantary boundary layer. (This request is related to a WGNE effort to understand how models parameterize the surface stresses.)", + "long_name": "Northward Surface Stress from Planetary Boundary Layer Scheme", + "comment": "The downward northward stress associated with the models parameterization of the planetary boundary layer. (This request is related to a WGNE effort to understand how models parameterize the surface stresses.)", "dimensions": "longitude latitude time", "out_name": "tauvpbl", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2004,6 +1923,7 @@ "ok_max_mean_abs": "" }, "tcs": { + "frequency": "day", "modeling_realm": "land", "standard_name": "canopy_temperature", "units": "K", @@ -2013,7 +1933,7 @@ "comment": "Vegetation temperature, averaged over all vegetation types", "dimensions": "longitude latitude time", "out_name": "tcs", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2021,16 +1941,17 @@ "ok_max_mean_abs": "" }, "tdps": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "dew_point_temperature", "units": "K", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "2m dewpoint temperature", - "comment": "", + "long_name": "2m Dewpoint Temperature", + "comment": "Dew point temperature is the temperature at which a parcel of air reaches saturation upon being cooled at constant pressure and specific humidity.", "dimensions": "longitude latitude time", "out_name": "tdps", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2038,16 +1959,17 @@ "ok_max_mean_abs": "" }, "tgs": { + "frequency": "day", "modeling_realm": "land", "standard_name": "surface_temperature", "units": "K", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Temperature of bare soil", + "long_name": "Temperature of Bare Soil", "comment": "Surface bare soil temperature", "dimensions": "longitude latitude time", "out_name": "tgs", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2055,6 +1977,7 @@ "ok_max_mean_abs": "" }, "tpf": { + "frequency": "day", "modeling_realm": "landIce land", "standard_name": "permafrost_layer_thickness", "units": "m", @@ -2072,6 +1995,7 @@ "ok_max_mean_abs": "" }, "tr": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "surface_temperature", "units": "K", @@ -2081,7 +2005,7 @@ "comment": "Effective radiative surface temperature, averaged over the grid cell", "dimensions": "longitude latitude time", "out_name": "tr", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2089,6 +2013,7 @@ "ok_max_mean_abs": "" }, "tran": { + "frequency": "day", "modeling_realm": "land", "standard_name": "transpiration_flux", "units": "kg m-2 s-1", @@ -2106,6 +2031,7 @@ "ok_max_mean_abs": "" }, "ts": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "surface_temperature", "units": "K", @@ -2123,13 +2049,14 @@ "ok_max_mean_abs": "" }, "tsl": { + "frequency": "day", "modeling_realm": "land", "standard_name": "soil_temperature", "units": "K", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", "long_name": "Temperature of Soil", - "comment": "Temperature of each soil layer. Reported as missing for grid cells with no land.", + "comment": "Temperature of soil. Reported as missing for grid cells with no land.", "dimensions": "longitude latitude sdepth time", "out_name": "tsl", "type": "real", @@ -2139,51 +2066,54 @@ "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, - "tsnl": { - "modeling_realm": "land", - "standard_name": "snow_temperature", + "tsland": { + "frequency": "day", + "modeling_realm": "atmos", + "standard_name": "surface_temperature", "units": "K", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Temperature profile in the snow", - "comment": "Temperature in the snow pack present in the grid-cell. 3D variable for multi-layer snow schemes.", + "long_name": "Land Surface Temperature", + "comment": "Temperature of the lower boundary of the atmosphere", "dimensions": "longitude latitude time", - "out_name": "tsnl", - "type": "", + "out_name": "tsland", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, - "tsns": { - "modeling_realm": "atmos", - "standard_name": "surface_temperature", + "tsn": { + "frequency": "day", + "modeling_realm": "landIce land", + "standard_name": "temperature_in_surface_snow", "units": "K", - "cell_methods": "area: mean where land time: mean", + "cell_methods": "area: mean where land time: mean (with samples weighted by snow mass)", "cell_measures": "area: areacella", - "long_name": "Snow Surface Temperature", - "comment": "Temperature of the snow surface as it interacts with the atmosphere, averaged over a grid cell.", + "long_name": "Snow Internal Temperature", + "comment": "This temperature is averaged over all the snow in the grid cell that rests on land or land ice. When computing the time-mean here, the time samples, weighted by the mass of snow on the land portion of the grid cell, are accumulated and then divided by the sum of the weights. Reported as missing in regions free of snow on land.", "dimensions": "longitude latitude time", - "out_name": "tsns", - "type": "", + "out_name": "tsn", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, - "tws": { - "modeling_realm": "land", - "standard_name": "canopy_and_surface_and_subsurface_water_amount", - "units": "kg m-2", + "tsns": { + "frequency": "day", + "modeling_realm": "atmos", + "standard_name": "surface_temperature", + "units": "K", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Terrestrial Water Storage", - "comment": "", + "long_name": "Snow Surface Temperature", + "comment": "Temperature of the snow surface as it interacts with the atmosphere, averaged over a grid cell.", "dimensions": "longitude latitude time", - "out_name": "tws", - "type": "", + "out_name": "tsns", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2191,50 +2121,17 @@ "ok_max_mean_abs": "" }, "ua": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "eastward_wind", "units": "m s-1", "cell_methods": "time: mean", "cell_measures": "area: areacella", "long_name": "Eastward Wind", - "comment": "", + "comment": "Zonal wind (positive in a eastward direction).", "dimensions": "longitude latitude plev19 time", "out_name": "ua", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "ua200": { - "modeling_realm": "atmos", - "standard_name": "eastward_wind", - "units": "m s-1", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "Eastward Wind at 200hPa", - "comment": "Zonal wind (positive eastwards) at 200hPa", - "dimensions": "longitude latitude time p200", - "out_name": "ua200", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "ua850": { - "modeling_realm": "atmos", - "standard_name": "eastward_wind", - "units": "m s-1", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "Eastward Wind at 850 hPa", - "comment": "Zonal wind on the 850 hPa surface", - "dimensions": "longitude latitude time p850", - "out_name": "ua850", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2242,50 +2139,17 @@ "ok_max_mean_abs": "" }, "va": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "northward_wind", "units": "m s-1", "cell_methods": "time: mean", "cell_measures": "area: areacella", "long_name": "Northward Wind", - "comment": "", + "comment": "Meridional wind (positive in a northward direction).", "dimensions": "longitude latitude plev19 time", "out_name": "va", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "va200": { - "modeling_realm": "atmos", - "standard_name": "northward_wind", - "units": "m s-1", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "Northward Wind", - "comment": "Northward component of the wind", - "dimensions": "longitude latitude time p200", - "out_name": "va200", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "va850": { - "modeling_realm": "atmos", - "standard_name": "northward_wind", - "units": "m s-1", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "Northward Wind", - "comment": "Northward component of the wind at 850hPa", - "dimensions": "longitude latitude time p850", - "out_name": "va850", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2293,12 +2157,13 @@ "ok_max_mean_abs": "" }, "wap": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "lagrangian_tendency_of_air_pressure", "units": "Pa s-1", "cell_methods": "time: mean", "cell_measures": "area: areacella", - "long_name": "omega (=dp/dt)", + "long_name": "Omega (=dp/dt)", "comment": "Omega (vertical velocity in pressure coordinates, positive downwards)", "dimensions": "longitude latitude plev19 time", "out_name": "wap", @@ -2310,16 +2175,17 @@ "ok_max_mean_abs": "" }, "wtd": { + "frequency": "day", "modeling_realm": "land", - "standard_name": "depth_of_soil_moisture_saturation", + "standard_name": "water_table_depth", "units": "m", "cell_methods": "area: mean where land time: mean", - "cell_measures": "area: areacella", - "long_name": "Water table depth", - "comment": "", + "cell_measures": "area: areacellr", + "long_name": "Water Table Depth", + "comment": "Depth is the vertical distance below the surface. The water table is the surface below which the soil is saturated with water such that all pore spaces are filled.", "dimensions": "longitude latitude time", "out_name": "wtd", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2327,16 +2193,17 @@ "ok_max_mean_abs": "" }, "zg": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "geopotential_height", "units": "m", "cell_methods": "time: mean", "cell_measures": "area: areacella", "long_name": "Geopotential Height", - "comment": "", + "comment": "Geopotential is the sum of the specific gravitational potential energy relative to the geoid and the specific centripetal potential energy. Geopotential height is the geopotential divided by the standard acceleration due to gravity. It is numerically similar to the altitude (or geometric height) and not to the quantity with standard name height, which is relative to the surface.", "dimensions": "longitude latitude plev19 time", "out_name": "zg", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2344,16 +2211,17 @@ "ok_max_mean_abs": "" }, "zmla": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "atmosphere_boundary_layer_thickness", "units": "m", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Height of Boundary Layer", - "comment": "", + "comment": "The atmosphere boundary layer thickness is the 'depth' or 'height' of the (atmosphere) planetary boundary layer.", "dimensions": "longitude latitude time", "out_name": "zmla", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_EdayZ.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_EdayZ.json index 6b4a253394..89a9bf6cd5 100644 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_EdayZ.json +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_EdayZ.json @@ -1,30 +1,31 @@ { "Header": { - "data_specs_version": "01.00.10", + "data_specs_version": "01.00.30", + "cmor_version": "3.4", "table_id": "Table EdayZ", "realm": "atmos", - "frequency": "day", - "cmor_version": "3.2", - "table_date": "10 May 2017", + "table_date": "11 March 2019", "missing_value": "1e20", + "int_missing_value": "-999", "product": "model-output", "approx_interval": "1.00000", "generic_levels": "", "mip_era": "CMIP6", - "Conventions": "CF-1.7 CMIP-6.0" + "Conventions": "CF-1.7 CMIP-6.2" }, "variable_entry": { "epfy": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "northward_eliassen_palm_flux_in_air", "units": "m3 s-2", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", + "cell_measures": "", "long_name": "Northward Component of the Eliassen-Palm Flux", "comment": "Transformed Eulerian Mean Diagnostics Meridional component Fy of Eliassen-Palm (EP) flux (Fy, Fz) derived from 6hr or higher frequency fields (use daily fields or 12 hr fields if the 6 hr are not available). Please use the definitions given by equation 3.5.3a of Andrews, Holton and Leovy text book, but scaled by density to have units m3 s-2.", "dimensions": "latitude plev39 time", "out_name": "epfy", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -32,33 +33,35 @@ "ok_max_mean_abs": "" }, "epfz": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "upward_eliassen_palm_flux_in_air", "units": "m3 s-2", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", + "cell_measures": "", "long_name": "Upward Component of the Eliassen-Palm Flux", "comment": "Transformed Eulerian Mean Diagnostics Meridional component Fz of the Eliassen-Palm (EP) flux (Fy, Fz) derived from 6hr or higher frequency fields (use daily fields or 12 hr fields if the 6 hr are not available). Please use the definitions given by equation 3.5.3b of Andrews, Holton and Leovy text book, but scaled by density to have units m3 s-2.", "dimensions": "latitude plev39 time", "out_name": "epfz", - "type": "", - "positive": "", + "type": "real", + "positive": "up", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "hus": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "specific_humidity", - "units": "1.0", + "units": "1", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", + "cell_measures": "", "long_name": "Specific Humidity", - "comment": "", + "comment": "Specific humidity is the mass fraction of water vapor in (moist) air.", "dimensions": "latitude plev19 time", "out_name": "hus", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -66,16 +69,17 @@ "ok_max_mean_abs": "" }, "psitem": { + "frequency": "day", "modeling_realm": "atmos", - "standard_name": "meridional_streamfunction_transformed_eulerian_mean", - "units": "kg s^-1", + "standard_name": "atmosphere_transformed_eulerian_mean_meridional_overturning_mass_streamfunction", + "units": "kg s-1", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", - "long_name": "Transformed Eulerian Mean mass stramfunction", - "comment": "Residual mass streamfunction, computed from vstar and integrated from the top of the atmosphere (on the native model grid). Reference: Andrews et al (1987): Middle Atmospheric Dynamics. Accademic Press.", + "cell_measures": "", + "long_name": "Transformed Eulerian Mean Mass Streamfunction", + "comment": "Residual mass streamfunction, computed from vstar and integrated from the top of the atmosphere (on the native model grid). Reference: Andrews et al (1987): Middle Atmospheric Dynamics. Academic Press.", "dimensions": "latitude plev39 time", "out_name": "psitem", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -83,16 +87,17 @@ "ok_max_mean_abs": "" }, "ta": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "air_temperature", "units": "K", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", + "cell_measures": "", "long_name": "Air Temperature", "comment": "Air Temperature", "dimensions": "latitude plev19 time", "out_name": "ta", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -100,16 +105,17 @@ "ok_max_mean_abs": "" }, "ua": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "eastward_wind", "units": "m s-1", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", + "cell_measures": "", "long_name": "Eastward Wind", - "comment": "", + "comment": "Zonal wind (positive in a eastward direction).", "dimensions": "latitude plev39 time", "out_name": "ua", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -117,16 +123,17 @@ "ok_max_mean_abs": "" }, "utendepfd": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "tendency_of_eastward_wind_due_to_eliassen_palm_flux_divergence", "units": "m s-2", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", - "long_name": "Tendency of eastward wind due to Eliassen-Palm Flux divergence", + "cell_measures": "", + "long_name": "Tendency of Eastward Wind Due to Eliassen-Palm Flux Divergence", "comment": "Tendency of the zonal mean zonal wind due to the divergence of the Eliassen-Palm flux.", "dimensions": "latitude plev39 time", "out_name": "utendepfd", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -134,16 +141,17 @@ "ok_max_mean_abs": "" }, "utendnogw": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "tendency_of_eastward_wind_due_to_nonorographic_gravity_wave_drag", "units": "m s-2", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", - "long_name": "u-tendency nonorographic gravity wave drag", + "cell_measures": "", + "long_name": "Eastward Acceleration Due to Non-Orographic Gravity Wave Drag", "comment": "Tendency of the eastward wind by parameterized nonorographic gravity waves.", "dimensions": "latitude plev39 time", "out_name": "utendnogw", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -151,16 +159,17 @@ "ok_max_mean_abs": "" }, "utendogw": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "tendency_of_eastward_wind_due_to_orographic_gravity_wave_drag", "units": "m s-2", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", - "long_name": "u-tendency orographic gravity wave drag", + "cell_measures": "", + "long_name": "Eastward Acceleration Due to Orographic Gravity Wave Drag", "comment": "Tendency of the eastward wind by parameterized orographic gravity waves.", "dimensions": "latitude plev39 time", "out_name": "utendogw", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -168,16 +177,17 @@ "ok_max_mean_abs": "" }, "utendvtem": { + "frequency": "day", "modeling_realm": "atmos", - "standard_name": "u-tendency_by_wstar_advection", + "standard_name": "tendency_of_eastward_wind_due_to_advection_by_northward_transformed_eulerian_mean_air_velocity", "units": "m s-1 d-1", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", - "long_name": "Rendency of eastward wind due to TEM northward advection and Coriolis term", - "comment": "Tendency of zonally averaged eastward wind, by the residual upward wind advection (on the native model grid). Reference: Andrews et al (1987): Middle Atmospheric Dynamics. Accademic Press.", + "cell_measures": "", + "long_name": "Tendency of Eastward Wind Due to TEM Northward Advection and Coriolis Term", + "comment": "Tendency of zonally averaged eastward wind, by the residual upward wind advection (on the native model grid). Reference: Andrews et al (1987): Middle Atmospheric Dynamics. Academic Press.", "dimensions": "latitude plev39 time", "out_name": "utendvtem", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -185,16 +195,17 @@ "ok_max_mean_abs": "" }, "utendwtem": { + "frequency": "day", "modeling_realm": "atmos", - "standard_name": "u-tendency_by_vstar_advection", + "standard_name": "tendency_of_eastward_wind_due_to_advection_by_upward_transformed_eulerian_mean_air_velocity", "units": "m s-1 d-1", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", - "long_name": "Rendency of eastward wind due to TEM upward advection", - "comment": "Tendency of zonally averaged eastward wind, by the residual northward wind advection (on the native model grid). Reference: Andrews et al (1987): Middle Atmospheric Dynamics. Accademic Press.", + "cell_measures": "", + "long_name": "Tendency of Eastward Wind Due to TEM Upward Advection", + "comment": "Tendency of zonally averaged eastward wind, by the residual northward wind advection (on the native model grid). Reference: Andrews et al (1987): Middle Atmospheric Dynamics. Academic Press.", "dimensions": "latitude plev39 time", "out_name": "utendwtem", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -202,16 +213,17 @@ "ok_max_mean_abs": "" }, "va": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "northward_wind", "units": "m s-1", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", + "cell_measures": "", "long_name": "Northward Wind", - "comment": "", + "comment": "Meridional wind (positive in a northward direction).", "dimensions": "latitude plev19 time", "out_name": "va", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -219,16 +231,17 @@ "ok_max_mean_abs": "" }, "vtem": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "northward_transformed_eulerian_mean_air_velocity", "units": "m s-1", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", - "long_name": "Transformed Eulerian Mean northward wind", + "cell_measures": "", + "long_name": "Transformed Eulerian Mean Northward Wind", "comment": "Transformed Eulerian Mean Diagnostics v*, meridional component of the residual meridional circulation (v*, w*) derived from 6 hr or higher frequency data fields (use instantaneous daily fields or 12 hr fields if the 6 hr data are not available).", "dimensions": "latitude plev39 time", "out_name": "vtem", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -236,16 +249,17 @@ "ok_max_mean_abs": "" }, "wtem": { + "frequency": "day", "modeling_realm": "atmos", - "standard_name": "unset", + "standard_name": "upward_transformed_eulerian_mean_air_velocity", "units": "m s-1", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", - "long_name": "Transformed Eulerian Mean upward wind", + "cell_measures": "", + "long_name": "Transformed Eulerian Mean Upward Wind", "comment": "Transformed Eulerian Mean Diagnostics w*, meridional component of the residual meridional circulation (v*, w*) derived from 6 hr or higher frequency data fields (use instantaneous daily fields or 12 hr fields if the 6 hr data are not available). Scale height: 6950 m", "dimensions": "latitude plev39 time", "out_name": "wtem", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -253,16 +267,17 @@ "ok_max_mean_abs": "" }, "zg": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "geopotential_height", "units": "m", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", + "cell_measures": "", "long_name": "Geopotential Height", - "comment": "", + "comment": "Geopotential is the sum of the specific gravitational potential energy relative to the geoid and the specific centripetal potential energy. Geopotential height is the geopotential divided by the standard acceleration due to gravity. It is numerically similar to the altitude (or geometric height) and not to the quantity with standard name height, which is relative to the surface.", "dimensions": "latitude plev19 time", "out_name": "zg", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Efx.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Efx.json index 7b41669e8b..d9e185c218 100644 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Efx.json +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Efx.json @@ -1,30 +1,31 @@ { "Header": { - "data_specs_version": "01.00.10", + "data_specs_version": "01.00.30", + "cmor_version": "3.4", "table_id": "Table Efx", "realm": "land", - "frequency": "fx", - "cmor_version": "3.2", - "table_date": "10 May 2017", + "table_date": "11 March 2019", "missing_value": "1e20", + "int_missing_value": "-999", "product": "model-output", "approx_interval": "0.00000", - "generic_levels": "alevel olevel", + "generic_levels": "alevhalf", "mip_era": "CMIP6", - "Conventions": "CF-1.7 CMIP-6.0" + "Conventions": "CF-1.7 CMIP-6.2" }, "variable_entry": { "clayfrac": { - "modeling_realm": "atmos", - "standard_name": "missing", - "units": "1.0", + "frequency": "fx", + "modeling_realm": "land", + "standard_name": "volume_fraction_of_clay_in_soil", + "units": "1", "cell_methods": "area: mean where land", "cell_measures": "area: areacella", "long_name": "Clay Fraction", - "comment": "", + "comment": "'Volume fraction' is used in the construction volume_fraction_of_X_in_Y, where X is a material constituent of Y.", "dimensions": "longitude latitude sdepth", "out_name": "clayfrac", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -32,16 +33,17 @@ "ok_max_mean_abs": "" }, "fldcapacity": { + "frequency": "fx", "modeling_realm": "land", - "standard_name": "missing", + "standard_name": "volume_fraction_of_condensed_water_in_soil_at_field_capacity", "units": "%", "cell_methods": "area: mean where land", "cell_measures": "area: areacella", "long_name": "Field Capacity", - "comment": "", + "comment": "The field capacity of soil is the maximum content of water it can retain against gravitational drainage. Provide as a percentage of the soil volume.", "dimensions": "longitude latitude sdepth", "out_name": "fldcapacity", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -49,16 +51,17 @@ "ok_max_mean_abs": "" }, "ksat": { + "frequency": "fx", "modeling_realm": "land", - "standard_name": "missing", - "units": "1e-6 m s-1", + "standard_name": "soil_hydraulic_conductivity_at_saturation", + "units": "micron s-1", "cell_methods": "area: mean where land", "cell_measures": "area: areacella", "long_name": "Saturated Hydraulic Conductivity", - "comment": "", + "comment": "Hydraulic conductivity is the constant k in Darcy's Law q=-k grad h for fluid flow q (volume transport per unit area i.e. velocity) through a porous medium, where h is the hydraulic head (pressure expressed as an equivalent depth of water).", "dimensions": "longitude latitude sdepth", "out_name": "ksat", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -66,16 +69,17 @@ "ok_max_mean_abs": "" }, "ps": { + "frequency": "fx", "modeling_realm": "atmos", "standard_name": "surface_air_pressure", "units": "Pa", "cell_methods": "area: mean", "cell_measures": "area: areacella", - "long_name": "Surface Pressure", + "long_name": "Surface Air Pressure", "comment": "surface pressure (not mean sea-level pressure), 2-D field to calculate the 3-D pressure field from hybrid coordinates", "dimensions": "longitude latitude", "out_name": "ps", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -83,6 +87,7 @@ "ok_max_mean_abs": "" }, "rld": { + "frequency": "fx", "modeling_realm": "atmos", "standard_name": "downwelling_longwave_flux_in_air", "units": "W m-2", @@ -90,7 +95,7 @@ "cell_measures": "", "long_name": "Downwelling Longwave Radiation", "comment": "Downwelling Longwave Radiation (includes the fluxes at the surface and TOA)", - "dimensions": "alevel spectband", + "dimensions": "alevhalf spectband", "out_name": "rld", "type": "real", "positive": "down", @@ -100,6 +105,7 @@ "ok_max_mean_abs": "" }, "rlu": { + "frequency": "fx", "modeling_realm": "atmos", "standard_name": "upwelling_longwave_flux_in_air", "units": "W m-2", @@ -107,7 +113,7 @@ "cell_measures": "", "long_name": "Upwelling Longwave Radiation", "comment": "Upwelling longwave radiation (includes the fluxes at the surface and TOA)", - "dimensions": "alevel spectband", + "dimensions": "alevhalf spectband", "out_name": "rlu", "type": "real", "positive": "up", @@ -117,16 +123,17 @@ "ok_max_mean_abs": "" }, "rootdsl": { + "frequency": "fx", "modeling_realm": "land", - "standard_name": "missing", - "units": "kg m-3", + "standard_name": "root_mass_content_of_carbon", + "units": "kg m-2", "cell_methods": "area: mean where land", "cell_measures": "area: areacella", "long_name": "Root Distribution", - "comment": "", + "comment": "Mass of carbon in roots.", "dimensions": "longitude latitude sdepth", "out_name": "rootdsl", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -134,6 +141,7 @@ "ok_max_mean_abs": "" }, "rsd": { + "frequency": "fx", "modeling_realm": "atmos", "standard_name": "downwelling_shortwave_flux_in_air", "units": "W m-2", @@ -141,7 +149,7 @@ "cell_measures": "", "long_name": "Downwelling Shortwave Radiation", "comment": "Downwelling shortwave radiation (includes the fluxes at the surface and top-of-atmosphere)", - "dimensions": "alevel spectband", + "dimensions": "alevhalf spectband", "out_name": "rsd", "type": "real", "positive": "down", @@ -151,6 +159,7 @@ "ok_max_mean_abs": "" }, "rsu": { + "frequency": "fx", "modeling_realm": "atmos", "standard_name": "upwelling_shortwave_flux_in_air", "units": "W m-2", @@ -158,7 +167,7 @@ "cell_measures": "", "long_name": "Upwelling Shortwave Radiation", "comment": "Upwelling shortwave radiation (includes also the fluxes at the surface and top of atmosphere)", - "dimensions": "alevel spectband", + "dimensions": "alevhalf spectband", "out_name": "rsu", "type": "real", "positive": "up", @@ -168,16 +177,17 @@ "ok_max_mean_abs": "" }, "sandfrac": { - "modeling_realm": "atmos", - "standard_name": "missing", - "units": "1.0", + "frequency": "fx", + "modeling_realm": "land", + "standard_name": "volume_fraction_of_sand_in_soil", + "units": "1", "cell_methods": "area: mean where land", "cell_measures": "area: areacella", "long_name": "Sand Fraction", - "comment": "", + "comment": "'Volume fraction' is used in the construction volume_fraction_of_X_in_Y, where X is a material constituent of Y.", "dimensions": "longitude latitude sdepth", "out_name": "sandfrac", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -185,16 +195,17 @@ "ok_max_mean_abs": "" }, "sftflf": { + "frequency": "fx", "modeling_realm": "landIce", "standard_name": "floating_ice_shelf_area_fraction", "units": "%", "cell_methods": "area: mean", "cell_measures": "area: areacella", - "long_name": "Floating Ice Shelf Area Fraction", - "comment": "Fraction of grid cell covered by floating ice shelf, the component of the ice sheet that is flowing over seawater", - "dimensions": "longitude latitude typefis", + "long_name": "Floating Ice Shelf Area Percentage", + "comment": "Percentage of grid cell covered by floating ice shelf, the component of the ice sheet that is flowing over sea water", + "dimensions": "longitude latitude", "out_name": "sftflf", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -202,16 +213,17 @@ "ok_max_mean_abs": "" }, "sftgrf": { + "frequency": "fx", "modeling_realm": "landIce", "standard_name": "grounded_ice_sheet_area_fraction", "units": "%", "cell_methods": "area: mean", "cell_measures": "area: areacella", - "long_name": "Grounded Ice Sheet Area Fraction", - "comment": "Fraction of grid cell covered by grounded ice sheet", - "dimensions": "longitude latitude typegis", + "long_name": "Grounded Ice Sheet Area Percentage", + "comment": "Percentage of grid cell covered by grounded ice sheet", + "dimensions": "longitude latitude", "out_name": "sftgrf", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -219,16 +231,17 @@ "ok_max_mean_abs": "" }, "siltfrac": { + "frequency": "fx", "modeling_realm": "atmos", - "standard_name": "missing", - "units": "1.0", + "standard_name": "volume_fraction_of_silt_in_soil", + "units": "1", "cell_methods": "area: mean where land", "cell_measures": "area: areacella", "long_name": "Silt Fraction", - "comment": "", + "comment": "Volume fraction of silt in soil", "dimensions": "longitude latitude sdepth", "out_name": "siltfrac", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -236,16 +249,17 @@ "ok_max_mean_abs": "" }, "slthick": { + "frequency": "fx", "modeling_realm": "land", - "standard_name": "missing", + "standard_name": "cell_thickness", "units": "m", "cell_methods": "area: mean where land", "cell_measures": "area: areacella", "long_name": "Thickness of Soil Layers", - "comment": "", + "comment": "'Thickness' means the vertical extent of a layer. 'Cell' refers to a model grid cell.", "dimensions": "longitude latitude sdepth", "out_name": "slthick", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -253,16 +267,17 @@ "ok_max_mean_abs": "" }, "vegHeight": { + "frequency": "fx", "modeling_realm": "land", "standard_name": "canopy_height", "units": "m", "cell_methods": "area: mean where land", "cell_measures": "area: areacella", - "long_name": "canopy height", - "comment": "", + "long_name": "Height of the Vegetation Canopy", + "comment": "Vegetation height averaged over all vegetation types and over the vegetated fraction of a grid cell.", "dimensions": "longitude latitude", "out_name": "vegHeight", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -270,16 +285,17 @@ "ok_max_mean_abs": "" }, "wilt": { + "frequency": "fx", "modeling_realm": "land", - "standard_name": "missing", + "standard_name": "volume_fraction_of_condensed_water_in_soil_at_wilting_point", "units": "%", "cell_methods": "area: mean where land", "cell_measures": "area: areacella", "long_name": "Wilting Point", - "comment": "", + "comment": "Percentage water content of soil by volume at the wilting point. The wilting point of soil is the water content below which plants cannot extract sufficient water to balance their loss through transpiration. ", "dimensions": "longitude latitude sdepth", "out_name": "wilt", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Emon.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Emon.json index 63b8168e25..f72076fa71 100644 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Emon.json +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Emon.json @@ -1,200 +1,31 @@ { "Header": { - "data_specs_version": "01.00.10", + "data_specs_version": "01.00.30", + "cmor_version": "3.4", "table_id": "Table Emon", - "realm": "atmos", - "frequency": "mon", - "cmor_version": "3.2", - "table_date": "10 May 2017", + "realm": "land", + "table_date": "11 March 2019", "missing_value": "1e20", + "int_missing_value": "-999", "product": "model-output", "approx_interval": "30.00000", "generic_levels": "alevel olevel", "mip_era": "CMIP6", - "Conventions": "CF-1.7 CMIP-6.0" + "Conventions": "CF-1.7 CMIP-6.2" }, "variable_entry": { - "H2p": { - "modeling_realm": "atmos", - "standard_name": "missing", - "units": "", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "2H in total precipitation", - "comment": "Roche - LSCE", - "dimensions": "longitude latitude time", - "out_name": "H2p", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "H2s": { - "modeling_realm": "atmos", - "standard_name": "missing", - "units": "", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "2H in solid precipitation", - "comment": "Roche - LSCE", - "dimensions": "longitude latitude time", - "out_name": "H2s", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "H2wv": { - "modeling_realm": "atmos", - "standard_name": "missing", - "units": "", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "H2 in water vapor", - "comment": "Roche - LSCE", - "dimensions": "longitude latitude alevel time", - "out_name": "H2wv", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "O17p": { - "modeling_realm": "atmos", - "standard_name": "missing", - "units": "", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "17O in total precipitation", - "comment": "Roche - LSCE", - "dimensions": "longitude latitude time", - "out_name": "O17p", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "O17s": { - "modeling_realm": "atmos", - "standard_name": "missing", - "units": "", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "17O in solid precipitation", - "comment": "Roche - LSCE", - "dimensions": "longitude latitude time", - "out_name": "O17s", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "O17wv": { - "modeling_realm": "atmos", - "standard_name": "missing", - "units": "", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "O17 in water vapor", - "comment": "Roche - LSCE", - "dimensions": "longitude latitude alevel time", - "out_name": "O17wv", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "O18p": { - "modeling_realm": "atmos", - "standard_name": "missing", - "units": "", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "18O in total precipitation", - "comment": "Roche - LSCE", - "dimensions": "longitude latitude time", - "out_name": "O18p", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "O18s": { - "modeling_realm": "atmos", - "standard_name": "missing", - "units": "", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "18O in solid precipitation", - "comment": "Roche - LSCE", - "dimensions": "longitude latitude time", - "out_name": "O18s", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "O18sw": { - "modeling_realm": "ocean", - "standard_name": "missing", - "units": "", - "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello volume: volcello", - "long_name": "O18 in sea water", - "comment": "Roche - LSCE", - "dimensions": "longitude latitude olevel time", - "out_name": "O18sw", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "O18wv": { - "modeling_realm": "atmos", - "standard_name": "missing", - "units": "", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "O18 in water vapor", - "comment": "Roche - LSCE", - "dimensions": "longitude latitude alevel time", - "out_name": "O18wv", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, "c13Land": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "total_land_c13", + "standard_name": "mass_content_of_13C_in_vegetation_and_litter_and_soil_and_forestry_and_agricultural_products", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Mass of 13C in all terrestrial carbon pools", - "comment": "", + "long_name": "Mass of 13C in All Terrestrial Carbon Pools", + "comment": "Carbon-13 mass content per unit area in vegetation (any living plants e.g. trees, shrubs, grass), litter (dead plant material in or above the soil), soil, and forestry and agricultural products (e.g. paper, cardboard, furniture, timber for construction, biofuels and food for both humans and livestock).", "dimensions": "longitude latitude time", "out_name": "c13Land", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -202,16 +33,17 @@ "ok_max_mean_abs": "" }, "c13Litter": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "litter_c13_content", + "standard_name": "litter_mass_content_of_13C", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", "long_name": "Mass of 13C in Litter Pool", - "comment": "", + "comment": "Carbon-13 mass content per unit area litter (dead plant material in or above the soil).", "dimensions": "longitude latitude time", "out_name": "c13Litter", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -219,16 +51,17 @@ "ok_max_mean_abs": "" }, "c13Soil": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "soil_c13_content", + "standard_name": "soil_mass_content_of_13C", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", "long_name": "Mass of 13C in Soil Pool", - "comment": "", + "comment": "Carbon-13 mass content per unit area in soil.", "dimensions": "longitude latitude time", "out_name": "c13Soil", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -236,16 +69,17 @@ "ok_max_mean_abs": "" }, "c13Veg": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "vegetation_c13_content", + "standard_name": "vegetation_mass_content_of_13C", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", "long_name": "Mass of 13C in Vegetation", - "comment": "", + "comment": "Carbon-13 mass content per unit area in vegetation (any living plants e.g. trees, shrubs, grass).", "dimensions": "longitude latitude time", "out_name": "c13Veg", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -253,16 +87,17 @@ "ok_max_mean_abs": "" }, "c14Land": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "total_land_c14", + "standard_name": "mass_content_of_14C_in_vegetation_and_litter_and_soil_and_forestry_and_agricultural_products", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Mass of 14C in all terrestrial carbon pools", - "comment": "", + "long_name": "Mass of 14C in All Terrestrial Carbon Pools", + "comment": "Carbon-14 mass content per unit area in vegetation (any living plants e.g. trees, shrubs, grass), litter (dead plant material in or above the soil), soil, and forestry and agricultural products (e.g. paper, cardboard, furniture, timber for construction, biofuels and food for both humans and livestock).", "dimensions": "longitude latitude time", "out_name": "c14Land", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -270,16 +105,17 @@ "ok_max_mean_abs": "" }, "c14Litter": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "litter_c14_content", + "standard_name": "litter_mass_content_of_14C", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", "long_name": "Mass of 14C in Litter Pool", - "comment": "", + "comment": "Carbon-14 mass content per unit area litter (dead plant material in or above the soil).", "dimensions": "longitude latitude time", "out_name": "c14Litter", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -287,16 +123,17 @@ "ok_max_mean_abs": "" }, "c14Soil": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "soil_c14_content", + "standard_name": "soil_mass_content_of_14C", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", "long_name": "Mass of 14C in Soil Pool", - "comment": "", + "comment": "Carbon-14 mass content per unit area in soil.", "dimensions": "longitude latitude time", "out_name": "c14Soil", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -304,16 +141,17 @@ "ok_max_mean_abs": "" }, "c14Veg": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "vegetation_c14_content", + "standard_name": "vegetation_mass_content_of_14C", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", "long_name": "Mass of 14C in Vegetation", - "comment": "", + "comment": "Carbon-14 mass content per unit area in vegetation (any living plants e.g. trees, shrubs, grass).", "dimensions": "longitude latitude time", "out_name": "c14Veg", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -321,8 +159,9 @@ "ok_max_mean_abs": "" }, "cLand": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "total_land_carbon", + "standard_name": "mass_content_of_carbon_in_vegetation_and_litter_and_soil_and_forestry_and_agricultural_products", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", @@ -330,7 +169,7 @@ "comment": "Report missing data over ocean grid cells. For fractional land report value averaged over the land fraction.", "dimensions": "longitude latitude time", "out_name": "cLand", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -338,16 +177,17 @@ "ok_max_mean_abs": "" }, "cLitterCwd": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "litter_wood_debris_carbon_content", + "standard_name": "wood_debris_mass_content_of_carbon", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", "long_name": "Carbon Mass in Coarse Woody Debris", - "comment": "", + "comment": "'Content' indicates a quantity per unit area. 'Wood debris' means dead organic matter composed of coarse wood. It is distinct from fine litter. The precise distinction between 'fine' and 'coarse' is model dependent.", "dimensions": "longitude latitude time", "out_name": "cLitterCwd", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -355,16 +195,17 @@ "ok_max_mean_abs": "" }, "cLitterGrass": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "litter_carbon_content", + "standard_name": "litter_mass_content_of_carbon", "units": "kg m-2", "cell_methods": "area: time: mean where natural_grasses (comment: mask=grassFrac)", "cell_measures": "area: areacella", - "long_name": "Carbon mass in litter on grass tiles", - "comment": "", + "long_name": "Carbon Mass in Litter on Grass Tiles", + "comment": "'Litter' is dead plant material in or above the soil. It is distinct from coarse wood debris. The precise distinction between 'fine' and 'coarse' is model dependent. 'Content' indicates a quantity per unit area. The sum of the quantities with standard names surface_litter_mass_content_of_carbon and subsurface_litter_mass_content_of_carbon has the standard name litter_mass_content_of_carbon.", "dimensions": "longitude latitude time", "out_name": "cLitterGrass", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -372,16 +213,17 @@ "ok_max_mean_abs": "" }, "cLitterShrub": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "litter_carbon_content", + "standard_name": "litter_mass_content_of_carbon", "units": "kg m-2", "cell_methods": "area: time: mean where shrubs (comment: mask=shrubFrac)", "cell_measures": "area: areacella", - "long_name": "Carbon mass in litter on shrub tiles", - "comment": "", + "long_name": "Carbon Mass in Litter on Shrub Tiles", + "comment": "'Litter' is dead plant material in or above the soil. It is distinct from coarse wood debris. The precise distinction between 'fine' and 'coarse' is model dependent. 'Content' indicates a quantity per unit area. The sum of the quantities with standard names surface_litter_mass_content_of_carbon and subsurface_litter_mass_content_of_carbon has the standard name litter_mass_content_of_carbon.", "dimensions": "longitude latitude time", "out_name": "cLitterShrub", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -389,16 +231,17 @@ "ok_max_mean_abs": "" }, "cLitterSubSurf": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "subsurface_litter_carbon_content", + "standard_name": "subsurface_litter_mass_content_of_carbon", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", "long_name": "Carbon Mass in Below-Ground Litter", - "comment": "sub-surface litter pool fed by root inputs.", + "comment": "subsurface litter pool fed by root inputs.", "dimensions": "longitude latitude time", "out_name": "cLitterSubSurf", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -406,8 +249,9 @@ "ok_max_mean_abs": "" }, "cLitterSurf": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "surface_litter_carbon_content", + "standard_name": "surface_litter_mass_content_of_carbon", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", @@ -415,7 +259,7 @@ "comment": "Surface or near-surface litter pool fed by leaf and above-ground litterfall", "dimensions": "longitude latitude time", "out_name": "cLitterSurf", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -423,16 +267,17 @@ "ok_max_mean_abs": "" }, "cLitterTree": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "litter_carbon_content", + "standard_name": "litter_mass_content_of_carbon", "units": "kg m-2", "cell_methods": "area: time: mean where trees (comment: mask=treeFrac)", "cell_measures": "area: areacella", - "long_name": "Carbon mass in litter on tree tiles", - "comment": "", + "long_name": "Carbon Mass in Litter on Tree Tiles", + "comment": "'Litter' is dead plant material in or above the soil. It is distinct from coarse wood debris. The precise distinction between 'fine' and 'coarse' is model dependent. 'Content' indicates a quantity per unit area. The sum of the quantities with standard names surface_litter_mass_content_of_carbon and subsurface_litter_mass_content_of_carbon has the standard name litter_mass_content_of_carbon.", "dimensions": "longitude latitude time", "out_name": "cLitterTree", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -440,8 +285,9 @@ "ok_max_mean_abs": "" }, "cMisc": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "miscellaneous_living_matter_carbon_content", + "standard_name": "miscellaneous_living_matter_mass_content_of_carbon", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", @@ -457,16 +303,17 @@ "ok_max_mean_abs": "" }, "cOther": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "other_vegegtation_components_carbon_content", + "standard_name": "miscellaneous_living_matter_mass_content_of_carbon", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Carbon Mass in Vegetation Components other than Leaves, Stems and Roots", + "long_name": "Carbon Mass in Vegetation Components Other than Leaves, Stems and Roots", "comment": "E.g. fruits, seeds, etc.", "dimensions": "longitude latitude time", "out_name": "cOther", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -474,12 +321,13 @@ "ok_max_mean_abs": "" }, "cSoil": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "soil_carbon_content", + "standard_name": "soil_mass_content_of_carbon", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Carbon Mass in Soil Pool", + "long_name": "Carbon Mass in Model Soil Pool", "comment": "Carbon mass in the full depth of the soil model.", "dimensions": "longitude latitude time", "out_name": "cSoil", @@ -491,33 +339,17 @@ "ok_max_mean_abs": "" }, "cSoilAbove1m": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "soil_carbon_content_above_1m_depth", + "standard_name": "soil_mass_content_of_carbon", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Carbon mass in soil pool above 1m depth", + "long_name": "Carbon Mass in Soil Pool Above 1m Depth", "comment": "Report missing data over ocean grid cells. For fractional land report value averaged over the land fraction.", - "dimensions": "longitude latitude time", + "dimensions": "longitude latitude time sdepth10", "out_name": "cSoilAbove1m", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "cSoilBelow1m": { - "modeling_realm": "land", - "standard_name": "soil_carbon_content_below_1m_depth", - "units": "kg m-2", - "cell_methods": "area: mean where land time: mean", - "cell_measures": "area: areacella", - "long_name": "Carbon Mass in Soil Pool below 1m Depth", - "comment": "", - "dimensions": "longitude latitude time", - "out_name": "cSoilBelow1m", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -525,16 +357,17 @@ "ok_max_mean_abs": "" }, "cSoilGrass": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "soil_carbon_content", + "standard_name": "soil_mass_content_of_carbon", "units": "kg m-2", "cell_methods": "area: time: mean where natural_grasses (comment: mask=grassFrac)", "cell_measures": "area: areacella", - "long_name": "Carbon mass in soil on grass tiles", - "comment": "", + "long_name": "Carbon Mass in Soil on Grass Tiles", + "comment": "'Content' indicates a quantity per unit area. The 'soil content' of a quantity refers to the vertical integral from the surface down to the bottom of the soil model. For the content between specified levels in the soil, standard names including content_of_soil_layer are used.", "dimensions": "longitude latitude time", "out_name": "cSoilGrass", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -542,16 +375,17 @@ "ok_max_mean_abs": "" }, "cSoilLevels": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "soil_carbon_content_on_model_levels", + "standard_name": "soil_mass_content_of_carbon", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Carbon mass in each model soil level (summed over all soil carbon pools in that level)", + "long_name": "Carbon Mass in Each Model Soil Level (Summed over All Soil Carbon Pools in That Level)", "comment": "for models with vertically discretised soil carbon, report total soil carbon for each level", - "dimensions": "longitude latitude time", + "dimensions": "longitude latitude sdepth time", "out_name": "cSoilLevels", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -559,16 +393,17 @@ "ok_max_mean_abs": "" }, "cSoilPools": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "soil_carbon_content_by_pool", + "standard_name": "soil_mass_content_of_carbon", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Carbon mass in each model soil pool (summed over vertical levels)", - "comment": "for models with multiple soil carbon pools, report each pool here. If models also have vertical discretaisation these should be aggregated", - "dimensions": "longitude latitude time", + "long_name": "Carbon Mass in Each Model Soil Pool (Summed over Vertical Levels)", + "comment": "For models with multiple soil carbon pools, report each pool here. If models also have vertical discretisation these should be aggregated", + "dimensions": "longitude latitude soilpools time", "out_name": "cSoilPools", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -576,16 +411,17 @@ "ok_max_mean_abs": "" }, "cSoilShrub": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "soil_carbon_content", + "standard_name": "soil_mass_content_of_carbon", "units": "kg m-2", "cell_methods": "area: time: mean where shrubs (comment: mask=shrubFrac)", "cell_measures": "area: areacella", - "long_name": "Carbon mass in soil on shrub tiles", - "comment": "", + "long_name": "Carbon Mass in Soil on Shrub Tiles", + "comment": "'Content' indicates a quantity per unit area. The 'soil content' of a quantity refers to the vertical integral from the surface down to the bottom of the soil model. For the content between specified levels in the soil, standard names including content_of_soil_layer are used.", "dimensions": "longitude latitude time", "out_name": "cSoilShrub", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -593,16 +429,17 @@ "ok_max_mean_abs": "" }, "cSoilTree": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "soil_carbon_content", + "standard_name": "soil_mass_content_of_carbon", "units": "kg m-2", "cell_methods": "area: time: mean where trees (comment: mask=treeFrac)", "cell_measures": "area: areacella", - "long_name": "Carbon mass in soil on tree tiles", - "comment": "", + "long_name": "Carbon Mass in Soil on Tree Tiles", + "comment": "'Content' indicates a quantity per unit area. The 'soil content' of a quantity refers to the vertical integral from the surface down to the bottom of the soil model. For the content between specified levels in the soil, standard names including content_of_soil_layer are used.", "dimensions": "longitude latitude time", "out_name": "cSoilTree", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -610,8 +447,9 @@ "ok_max_mean_abs": "" }, "cStem": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "stem_carbon_content", + "standard_name": "stem_mass_content_of_carbon", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", @@ -619,7 +457,7 @@ "comment": "including sapwood and hardwood.", "dimensions": "longitude latitude time", "out_name": "cStem", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -627,16 +465,17 @@ "ok_max_mean_abs": "" }, "cTotFireLut": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "missing", + "standard_name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_fires", "units": "kg m-2 s-1", - "cell_methods": "area: time: mean where landuse", + "cell_methods": "area: time: mean where sector", "cell_measures": "area: areacella", - "long_name": "Total carbon loss from natural and managed fire on land use tile, including deforestation fires", + "long_name": "Total Carbon Loss from Natural and Managed Fire on Land-Use Tile, Including Deforestation Fires", "comment": "Different from LMON this flux should include all fires occurring on the land use tile, including natural, man-made and deforestation fires", "dimensions": "longitude latitude landUse time", "out_name": "cTotFireLut", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -644,16 +483,17 @@ "ok_max_mean_abs": "" }, "cVegGrass": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "vegetation_carbon_content", "units": "kg m-2", "cell_methods": "area: time: mean where natural_grasses (comment: mask=grassFrac)", "cell_measures": "area: areacella", - "long_name": "Carbon mass in vegetation on grass tiles", - "comment": "", + "long_name": "Carbon Mass in Vegetation on Grass Tiles", + "comment": "'Content' indicates a quantity per unit area. 'Vegetation' means any plants e.g. trees, shrubs, grass. Plants are autotrophs i.e. 'producers' of biomass using carbon obtained from carbon dioxide.", "dimensions": "longitude latitude time", "out_name": "cVegGrass", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -661,16 +501,17 @@ "ok_max_mean_abs": "" }, "cVegShrub": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "vegetation_carbon_content", "units": "kg m-2", "cell_methods": "area: time: mean where shrubs (comment: mask=shrubFrac)", "cell_measures": "area: areacella", - "long_name": "Carbon mass in vegetation on shrub tiles", - "comment": "", + "long_name": "Carbon Mass in Vegetation on Shrub Tiles", + "comment": "'Content' indicates a quantity per unit area. 'Vegetation' means any plants e.g. trees, shrubs, grass. Plants are autotrophs i.e. 'producers' of biomass using carbon obtained from carbon dioxide.", "dimensions": "longitude latitude time", "out_name": "cVegShrub", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -678,16 +519,17 @@ "ok_max_mean_abs": "" }, "cVegTree": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "vegetation_carbon_content", "units": "kg m-2", "cell_methods": "area: time: mean where trees (comment: mask=treeFrac)", "cell_measures": "area: areacella", - "long_name": "Carbon mass in vegetation on tree tiles", - "comment": "", + "long_name": "Carbon Mass in Vegetation on Tree Tiles", + "comment": "'Content' indicates a quantity per unit area. 'Vegetation' means any plants e.g. trees, shrubs, grass. Plants are autotrophs i.e. 'producers' of biomass using carbon obtained from carbon dioxide.", "dimensions": "longitude latitude time", "out_name": "cVegTree", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -695,8 +537,9 @@ "ok_max_mean_abs": "" }, "cWood": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "wood_carbon_content", + "standard_name": "stem_mass_content_of_carbon", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", @@ -712,12 +555,13 @@ "ok_max_mean_abs": "" }, "cfadDbze94": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "histogram_of_equivalent_reflectivity_factor_over_height_above_reference_ellipsoid", - "units": "1.0", + "units": "1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "CloudSat Radar Reflectivity", + "long_name": "CloudSat Radar Reflectivity CFAD", "comment": "CFAD (Cloud Frequency Altitude Diagrams) are frequency distributions of radar reflectivity (or lidar scattering ratio) as a function of altitude. The variable cfadDbze94 is defined as the simulated relative frequency of occurrence of radar reflectivity in sampling volumes defined by altitude bins. The radar is observing at a frequency of 94GHz.", "dimensions": "longitude latitude alt40 dbze time", "out_name": "cfadDbze94", @@ -729,12 +573,13 @@ "ok_max_mean_abs": "" }, "cfadLidarsr532": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "histogram_of_backscattering_ratio_over_height_above_reference_ellipsoid", - "units": "1.0", + "units": "1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "CALIPSO Scattering Ratio", + "long_name": "CALIPSO Scattering Ratio CFAD", "comment": "CFAD (Cloud Frequency Altitude Diagrams) are frequency distributions of radar reflectivity (or lidar scattering ratio) as a function of altitude. The variable cfadLidarsr532 is defined as the simulated relative frequency of lidar scattering ratio in sampling volumes defined by altitude bins. The lidar is observing at a wavelength of 532nm.", "dimensions": "longitude latitude alt40 scatratio time", "out_name": "cfadLidarsr532", @@ -746,16 +591,17 @@ "ok_max_mean_abs": "" }, "clcalipsoice": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "ice_cloud_area_fraction_in_atmosphere_layer", "units": "%", "cell_methods": "time: mean", "cell_measures": "area: areacella", - "long_name": "CALIPSO ice cloud Fraction", - "comment": "", + "long_name": "CALIPSO Ice Cloud Percentage", + "comment": "Percentage cloud cover in CALIPSO standard atmospheric layers.", "dimensions": "longitude latitude alt40 time", "out_name": "clcalipsoice", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -763,16 +609,17 @@ "ok_max_mean_abs": "" }, "clcalipsoliq": { + "frequency": "mon", "modeling_realm": "atmos", - "standard_name": "liquid_cloud_area_fraction_in_atmosphere_layer", + "standard_name": "liquid_water_cloud_area_fraction_in_atmosphere_layer", "units": "%", "cell_methods": "time: mean", "cell_measures": "area: areacella", - "long_name": "CALIPSO liquid cloud Fraction", - "comment": "", + "long_name": "CALIPSO Liquid Cloud Percentage", + "comment": "Percentage liquid water ice cloud cover in CALIPSO standard atmospheric layers.", "dimensions": "longitude latitude alt40 time", "out_name": "clcalipsoliq", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -780,16 +627,17 @@ "ok_max_mean_abs": "" }, "cldicemxrat27": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "cloud_ice_mixing_ratio", - "units": "1.0", + "units": "1", "cell_methods": "time: mean", "cell_measures": "area: areacella", "long_name": "Cloud Ice Mixing Ratio", "comment": "Cloud ice mixing ratio", "dimensions": "longitude latitude plev27 time", "out_name": "cldicemxrat", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -797,6 +645,7 @@ "ok_max_mean_abs": "" }, "cldnci": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "number_concentration_of_ice_crystals_in_air_at_ice_cloud_top", "units": "m-3", @@ -806,7 +655,7 @@ "comment": "Concentration 'as seen from space' over ice-cloud portion of grid cell. This is the value from uppermost model layer with ice cloud or, if available, it is the sum over all ice cloud tops, no matter where they occur, as long as they are seen from the top of the atmosphere. Weight by total ice cloud top fraction (as seen from TOA) of each time sample when computing monthly mean.", "dimensions": "longitude latitude time", "out_name": "cldnci", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -814,6 +663,7 @@ "ok_max_mean_abs": "" }, "cldncl": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "number_concentration_of_cloud_liquid_water_particles_in_air_at_liquid_water_cloud_top", "units": "m-3", @@ -823,7 +673,7 @@ "comment": "Droplets are liquid only. Report concentration 'as seen from space' over liquid cloudy portion of grid cell. This is the value from uppermost model layer with liquid cloud or, if available, it is better to sum over all liquid cloud tops, no matter where they occur, as long as they are seen from the top of the atmosphere. Weight by total liquid cloud top fraction of (as seen from TOA) each time sample when computing monthly mean.", "dimensions": "longitude latitude time", "out_name": "cldncl", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -831,6 +681,7 @@ "ok_max_mean_abs": "" }, "cldnvi": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "atmosphere_number_content_of_cloud_droplets", "units": "m-2", @@ -840,7 +691,7 @@ "comment": "Droplets are liquid only. Values are weighted by liquid cloud fraction in each layer when vertically integrating, and for monthly means the samples are weighted by total liquid cloud fraction (as seen from TOA).", "dimensions": "longitude latitude time", "out_name": "cldnvi", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -848,16 +699,17 @@ "ok_max_mean_abs": "" }, "cldwatmxrat27": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "cloud_liquid_water_mixing_ratio", - "units": "1.0", + "units": "1", "cell_methods": "time: mean", "cell_measures": "area: areacella", "long_name": "Cloud Water Mixing Ratio", "comment": "Cloud water mixing ratio", "dimensions": "longitude latitude plev27 time", "out_name": "cldwatmxrat", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -865,16 +717,17 @@ "ok_max_mean_abs": "" }, "climodis": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "ice_cloud_area_fraction", "units": "%", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "MODIS Ice Cloud Area Percentage", - "comment": "", + "comment": "Total ice cloud area fraction (reported as a percentage) for the whole atmospheric column, as seen by the Moderate Resolution Imaging Spectroradiometer (MODIS). ", "dimensions": "longitude latitude time", "out_name": "climodis", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -882,16 +735,17 @@ "ok_max_mean_abs": "" }, "clmisr": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "cloud_area_fraction_in_atmosphere_layer", "units": "%", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Percentage Cloud Cover as Calculated by the MISR Simulator", - "comment": "Cloud percentage in spectral bands and layers as observed by the Multi-angle Imaging SpectroRadiometer (MISR) instrument.", + "long_name": "Percentage Cloud Cover as Calculated by the MISR Simulator (Including Error Flag)", + "comment": "Cloud percentage in spectral bands and layers as observed by the Multi-angle Imaging SpectroRadiometer (MISR) instrument. The first layer in each profile is reserved for a retrieval error flag.", "dimensions": "longitude latitude alt16 tau time", "out_name": "clmisr", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -899,16 +753,17 @@ "ok_max_mean_abs": "" }, "cltmodis": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "cloud_area_fraction", "units": "%", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "MODIS Total Cloud Cover Percentage", - "comment": "", + "comment": "Total cloud area fraction (reported as a percentage) for the whole atmospheric column, as seen by the Moderate Resolution Imaging Spectroradiometer (MODIS). Includes both large-scale and convective cloud.", "dimensions": "longitude latitude time", "out_name": "cltmodis", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -916,16 +771,17 @@ "ok_max_mean_abs": "" }, "clwmodis": { + "frequency": "mon", "modeling_realm": "atmos", - "standard_name": "liquid_cloud_area_fraction", + "standard_name": "liquid_water_cloud_area_fraction", "units": "%", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "MODIS Liquid Cloud Fraction", - "comment": "", + "long_name": "MODIS Liquid Cloud Percentage", + "comment": "Mass of cloud liquid water, as seen by the Moderate Resolution Imaging Spectroradiometer (MODIS). Includes both large-scale and convective cloud.", "dimensions": "longitude latitude time", "out_name": "clwmodis", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -933,8 +789,9 @@ "ok_max_mean_abs": "" }, "clwvic": { + "frequency": "mon", "modeling_realm": "atmos", - "standard_name": "atmosphere_convective_cloud_condensed_water_content", + "standard_name": "atmosphere_mass_content_of_convective_cloud_condensed_water", "units": "kg m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", @@ -942,7 +799,7 @@ "comment": "calculate mass of convective condensed (liquid + ice) water in the column divided by the area of the column (not just the area of the cloudy portion of the column). This includes precipitating hydrometeors ONLY if the precipitating hydrometeors affect the calculation of radiative transfer in model.", "dimensions": "longitude latitude time", "out_name": "clwvic", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -950,16 +807,17 @@ "ok_max_mean_abs": "" }, "co23D": { + "frequency": "mon", "modeling_realm": "atmos", - "standard_name": "CO2_3D_tracer", + "standard_name": "mass_fraction_of_carbon_dioxide_tracer_in_air", "units": "kg kg-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "3D field of transported CO2", + "long_name": "3D-Field of Transported CO2", "comment": "report 3D field of model simulated atmospheric CO2 mass mixing ration on model levels", "dimensions": "longitude latitude alevel time", "out_name": "co23D", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -967,6 +825,7 @@ "ok_max_mean_abs": "" }, "co2s": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "mole_fraction_of_carbon_dioxide_in_air", "units": "1e-06", @@ -976,7 +835,7 @@ "comment": "As co2, but only at the surface", "dimensions": "longitude latitude time", "out_name": "co2s", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -984,6 +843,7 @@ "ok_max_mean_abs": "" }, "columnmassflux": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "atmosphere_net_upward_convective_mass_flux", "units": "kg m-2 s-1", @@ -993,16 +853,17 @@ "comment": "Column integral of (mcu-mcd)", "dimensions": "longitude latitude time", "out_name": "columnmassflux", - "type": "", - "positive": "", + "type": "real", + "positive": "up", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "conccmcn": { + "frequency": "mon", "modeling_realm": "atmos", - "standard_name": "number_concentration_of_coarse_mode_ambient_aerosol_in_air", + "standard_name": "number_concentration_of_coarse_mode_ambient_aerosol_particles_in_air", "units": "m-3", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", @@ -1010,7 +871,7 @@ "comment": "includes all particles with diameter larger than 1 micron", "dimensions": "longitude latitude alevel time", "out_name": "conccmcn", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1018,16 +879,17 @@ "ok_max_mean_abs": "" }, "conccn": { + "frequency": "mon", "modeling_realm": "atmos", - "standard_name": "number_concentration_of_ambient_aerosol_in_air", + "standard_name": "number_concentration_of_ambient_aerosol_particles_in_air", "units": "m-3", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Aerosol Number Concentration", - "comment": "", + "comment": "'Number concentration' means the number of particles or other specified objects per unit volume. 'Aerosol' means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. 'Ambient_aerosol' means that the aerosol is measured or modelled at the ambient state of pressure, temperature and relative humidity that exists in its immediate environment. 'Ambient aerosol particles' are aerosol particles that have taken up ambient water through hygroscopic growth. The extent of hygroscopic growth depends on the relative humidity and the composition of the particles.", "dimensions": "longitude latitude alevel time", "out_name": "conccn", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1035,16 +897,17 @@ "ok_max_mean_abs": "" }, "concdust": { + "frequency": "mon", "modeling_realm": "atmos", - "standard_name": "mass_concentration_of_dust_dry_aerosol_in_air", + "standard_name": "mass_concentration_of_dust_dry_aerosol_particles_in_air", "units": "kg m-3", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Concentration of Dust", - "comment": "", + "comment": "Mass concentration means mass per unit volume and is used in the construction mass_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. 'Aerosol' means the system of suspended liquid or solid particles in air (except cloud droplets) and their carrier gas, the air itself. Aerosol particles take up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the particles. 'Dry aerosol particles' means aerosol particles without any water uptake.", "dimensions": "longitude latitude alevel time", "out_name": "concdust", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1052,8 +915,9 @@ "ok_max_mean_abs": "" }, "concnmcn": { + "frequency": "mon", "modeling_realm": "atmos", - "standard_name": "number_concentration_of_nucleation_mode_ambient_aerosol_in_air", + "standard_name": "number_concentration_of_nucleation_mode_ambient_aerosol_particles_in_air", "units": "m-3", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", @@ -1061,7 +925,7 @@ "comment": "includes all particles with diameter smaller than 3 nm", "dimensions": "longitude latitude alevel time", "out_name": "concnmcn", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1069,6 +933,7 @@ "ok_max_mean_abs": "" }, "cropFracC3": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "area_fraction", "units": "%", @@ -1076,9 +941,9 @@ "cell_measures": "area: areacella", "long_name": "Percentage Cover by C3 Crops", "comment": "Percentage of entire grid cell covered by C3 crops", - "dimensions": "longitude latitude time typec3pft typecrop", + "dimensions": "longitude latitude time typec3crop", "out_name": "cropFracC3", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1086,6 +951,7 @@ "ok_max_mean_abs": "" }, "cropFracC4": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "area_fraction", "units": "%", @@ -1093,9 +959,9 @@ "cell_measures": "area: areacella", "long_name": "Percentage Cover by C4 Crops", "comment": "Percentage of entire grid cell covered by C4 crops", - "dimensions": "longitude latitude time typec4pft typecrop", + "dimensions": "longitude latitude time typec4crop", "out_name": "cropFracC4", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1103,16 +969,17 @@ "ok_max_mean_abs": "" }, "depdust": { - "modeling_realm": "atmos", - "standard_name": "tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_total_deposition", + "frequency": "mon", + "modeling_realm": "aerosol", + "standard_name": "minus_tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_deposition", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Total Deposition Rate of Dust", - "comment": "Balkanski - LSCE", + "comment": "Fdry mass deposition rate of dust", "dimensions": "longitude latitude time", "out_name": "depdust", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1120,32 +987,16 @@ "ok_max_mean_abs": "" }, "diabdrag": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "tendency_of_eastward_wind_due_to_numerical_artefacts", "units": "m s-2", "cell_methods": "time: mean", "cell_measures": "area: areacella", "long_name": "Tendency of Eastward Wind from Numerical Artefacts", - "comment": "Other sub-grid scale/numerical zonal drag excluding that already provided for the parameterized orographic and non-ororgraphic gravity waves. This would be used to calculate the total 'diabatic drag'. Contributions to this additional drag such Rayleigh friction and diffusion that can be calculated from the monthly mean wind fields should not be included, but details (e.g. coefficients) of the friction and/or diffusion used in the model should be provided separately.", + "comment": "Other sub-grid scale/numerical zonal drag excluding that already provided for the parameterized orographic and non-orographic gravity waves. This would be used to calculate the total 'diabatic drag'. Contributions to this additional drag such Rayleigh friction and diffusion that can be calculated from the monthly mean wind fields should not be included, but details (e.g. coefficients) of the friction and/or diffusion used in the model should be provided separately.", "dimensions": "longitude latitude plev19 time", "out_name": "diabdrag", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "dissi13c": { - "modeling_realm": "ocnBgChem", - "standard_name": "mole_concentration_of_dissolved_inorganic_carbon13_in_sea_water", - "units": "mol m-3", - "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello volume: volcello", - "long_name": "Dissolved Inorganic 13Carbon Concentration", - "comment": "Dissolved inorganic 14carbon (CO3+HCO3+H2CO3) concentration", - "dimensions": "longitude latitude olevel time", - "out_name": "dissi13c", "type": "real", "positive": "", "valid_min": "", @@ -1154,32 +1005,16 @@ "ok_max_mean_abs": "" }, "dissi14c": { - "modeling_realm": "land", - "standard_name": "mole_concentration_of_dissolved_inorganic_c14_in_sea_water", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_dissolved_inorganic_14C_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Concentration of DI14C", - "comment": "", + "long_name": "Dissolved Inorganic Carbon-14 Concentration", + "comment": "Dissolved inorganic carbon-14 (CO3+HCO3+H2CO3) concentration", "dimensions": "longitude latitude olevel time", "out_name": "dissi14c", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "dissicnat": { - "modeling_realm": "ocnBgChem", - "standard_name": "mole_concentration_of_dissolved_inorganic_carbon_in_sea_water_natural_component", - "units": "mol m-3", - "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello volume: volcello", - "long_name": "Natural Dissolved Inorganic Carbon Concentration", - "comment": "Dissolved inorganic carbon (CO3+HCO3+H2CO3) concentration at preindustrial atmospheric xCO2", - "dimensions": "longitude latitude olevel time", - "out_name": "dissicnat", "type": "real", "positive": "", "valid_min": "", @@ -1188,16 +1023,17 @@ "ok_max_mean_abs": "" }, "ec550aer": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "volume_extinction_coefficient_in_air_due_to_ambient_aerosol_particles", "units": "m-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Aerosol extinction coefficient", - "comment": "Aerosol Extinction @550nm", - "dimensions": "longitude latitude alevel time", + "long_name": "Aerosol Extinction Coefficient", + "comment": "Aerosol Extinction at 550nm", + "dimensions": "longitude latitude alevel time lambda550nm", "out_name": "ec550aer", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1205,16 +1041,17 @@ "ok_max_mean_abs": "" }, "evspsblpot": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "water_potential_evaporation_flux", "units": "kg m-2 s-1", - "cell_methods": "area: time: mean", + "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", "long_name": "Potential Evapotranspiration", "comment": "at surface; potential flux of water into the atmosphere due to conversion of both liquid and solid phases to vapor (from underlying surface and vegetation)", "dimensions": "longitude latitude time", "out_name": "evspsblpot", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1222,12 +1059,13 @@ "ok_max_mean_abs": "" }, "exparag": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "sinking_mole_flux_of_aragonite_expressed_as_carbon_in_sea_water", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Sinking Aragonite Flux", + "long_name": "Downward Flux of Aragonite", "comment": "Downward flux of Aragonite", "dimensions": "longitude latitude olevel time", "out_name": "exparag", @@ -1239,12 +1077,13 @@ "ok_max_mean_abs": "" }, "expcalc": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "sinking_mole_flux_of_calcite_expressed_as_carbon_in_sea_water", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Sinking Calcite Flux", + "long_name": "Downward Flux of Calcite", "comment": "Downward flux of Calcite", "dimensions": "longitude latitude olevel time", "out_name": "expcalc", @@ -1255,31 +1094,33 @@ "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, - "expcfe": { - "modeling_realm": "ocean", + "expfe": { + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "sinking_mole_flux_of_particulate_iron_in_sea_water", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", "long_name": "Sinking Particulate Iron Flux", - "comment": "", + "comment": "In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. 'Sinking' is the gravitational settling of particulate matter suspended in a liquid. A sinking flux is positive downwards and is calculated relative to the movement of the surrounding fluid.", "dimensions": "longitude latitude olevel time", - "out_name": "expcfe", - "type": "", - "positive": "", + "out_name": "expfe", + "type": "real", + "positive": "down", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "expn": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "sinking_mole_flux_of_particulate_organic_nitrogen_in_sea_water", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", "long_name": "Sinking Particulate Organic Nitrogen Flux", - "comment": "", + "comment": "In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. 'Sinking' is the gravitational settling of particulate matter suspended in a liquid. A sinking flux is positive downwards and is calculated relative to the movement of the surrounding fluid.", "dimensions": "longitude latitude olevel time", "out_name": "expn", "type": "real", @@ -1290,13 +1131,14 @@ "ok_max_mean_abs": "" }, "expp": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "sinking_mole_flux_of_particulate_organic_phosphorus_in_sea_water", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", "long_name": "Sinking Particulate Organic Phosphorus Flux", - "comment": "", + "comment": "In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. 'Sinking' is the gravitational settling of particulate matter suspended in a liquid. A sinking flux is positive downwards and is calculated relative to the movement of the surrounding fluid.", "dimensions": "longitude latitude olevel time", "out_name": "expp", "type": "real", @@ -1307,13 +1149,14 @@ "ok_max_mean_abs": "" }, "expsi": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "sinking_mole_flux_of_particulate_silicon_in_sea_water", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Sinking Particulate Silica Flux", - "comment": "", + "long_name": "Sinking Particulate Silicon Flux", + "comment": "In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. 'Sinking' is the gravitational settling of particulate matter suspended in a liquid. A sinking flux is positive downwards and is calculated relative to the movement of the surrounding fluid.", "dimensions": "longitude latitude olevel time", "out_name": "expsi", "type": "real", @@ -1324,16 +1167,17 @@ "ok_max_mean_abs": "" }, "fAnthDisturb": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_anthrogpogenic_emission", + "standard_name": "tendency_of_atmosphere_mass_content_of_carbon_dioxide_expressed_as_carbon_due_to_anthropogenic_emission", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "carbon mass flux into atmosphere due to any human activity", - "comment": "will require some careful definition to make sure we capture everything - any human activity that releases carbon to the atmosphere instead of into product pool goes here. E.g. Deforestation fire, harvest assumed to decompose straight away, grazing...", + "long_name": "Carbon Mass Flux from Vegetation, Litter or Soil Pools into the Atmosphere Due to any Human Activity", + "comment": "Anthropogenic flux of carbon as carbon dioxide into the atmosphere. That is, emissions influenced, caused, or created by human activity. Anthropogenic emission of carbon dioxide includes fossil fuel use, cement production, agricultural burning and sources associated with anthropogenic land use change, except forest regrowth.", "dimensions": "longitude latitude time", "out_name": "fAnthDisturb", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1341,16 +1185,17 @@ "ok_max_mean_abs": "" }, "fBNF": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "biological_nitrogen_fixation", + "standard_name": "tendency_of_soil_and_vegetation_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_fixation", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "biological nitrogen fixation", - "comment": "", + "long_name": "Biological Nitrogen Fixation", + "comment": "The fixation (uptake of nitrogen gas directly from the atmosphere) of nitrogen due to biological processes.", "dimensions": "longitude latitude time", "out_name": "fBNF", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1358,16 +1203,17 @@ "ok_max_mean_abs": "" }, "fCLandToOcean": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "carbon_mass_flux_into_ocean_from_rivers", + "standard_name": "mass_flux_of_carbon_into_sea_water_from_rivers", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", - "cell_measures": "area: areacella", - "long_name": "Lateral transfer of carbon out of gridcell that eventually goes into ocean", + "cell_measures": "area: areacellr", + "long_name": "Lateral Transfer of Carbon out of Grid Cell That Eventually Goes into Ocean", "comment": "leached carbon etc that goes into run off or river routing and finds its way into ocean should be reported here.", "dimensions": "longitude latitude time", "out_name": "fCLandToOcean", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1375,16 +1221,17 @@ "ok_max_mean_abs": "" }, "fDeforestToAtmos": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "surface_net_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_anthropogenic_land_use_change", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Deforested biomass that goes into atmosphere as a result of anthropogenic land use change", + "long_name": "Deforested Biomass That Goes into Atmosphere as a Result of Anthropogenic Land-Use Change", "comment": "When land use change results in deforestation of natural vegetation (trees or grasslands) then natural biomass is removed. The treatment of deforested biomass differs significantly across models, but it should be straight-forward to compare deforested biomass across models.", "dimensions": "longitude latitude time", "out_name": "fDeforestToAtmos", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1392,16 +1239,17 @@ "ok_max_mean_abs": "" }, "fDeforestToProduct": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "deforested_biomass_into_product_pool_due_to_anthorpogenic_land_use_change", + "standard_name": "carbon_mass_flux_into_forestry_and_agricultural_products_due_to_anthropogenic_land_use_or_land_cover_change", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Deforested biomass that goes into product pool as a result of anthropogenic land use change", + "long_name": "Deforested Biomass That Goes into Product Pool as a Result of Anthropogenic Land-Use Change", "comment": "When land use change results in deforestation of natural vegetation (trees or grasslands) then natural biomass is removed. The treatment of deforested biomass differs significantly across models, but it should be straight-forward to compare deforested biomass across models.", "dimensions": "longitude latitude time", "out_name": "fDeforestToProduct", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1409,16 +1257,17 @@ "ok_max_mean_abs": "" }, "fFireAll": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "fire_CO2_emissions_from_all_sources", + "standard_name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_fires", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Carbon Mass Flux into Atmosphere due to CO2 emissions from Fire resulting from all sources including natural, anthropogenic and land use change.", - "comment": "Only total fire emissions can be compared to observations.", + "long_name": "Carbon Mass Flux into Atmosphere Due to CO2 Emission from Fire Including All Sources", + "comment": "From all sources, Including natural, anthropogenic and Land-use change. Only total fire emissions can be compared to observations.", "dimensions": "longitude latitude time", "out_name": "fFireAll", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1426,16 +1275,17 @@ "ok_max_mean_abs": "" }, "fFireNat": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "fire_CO2_emissions_from_wildfire", + "standard_name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_natural_fires", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Carbon Mass Flux into Atmosphere due to CO2 Emission from natural Fire", + "long_name": "Carbon Mass Flux into Atmosphere Due to CO2 Emission from Natural Fire", "comment": "CO2 emissions from natural fires", "dimensions": "longitude latitude time", "out_name": "fFireNat", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1443,33 +1293,35 @@ "ok_max_mean_abs": "" }, "fHarvestToAtmos": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_crop_harvesting", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Harvested biomass that goes straight into atmosphere", + "long_name": "Harvested Biomass That Goes Straight into Atmosphere", "comment": "any harvested carbon that is assumed to decompose immediately into the atmosphere is reported here", "dimensions": "longitude latitude time", "out_name": "fHarvestToAtmos", - "type": "", - "positive": "", + "type": "real", + "positive": "up", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "fHarvestToProduct": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "harvested_biomass_into_product_pool", + "standard_name": "mass_flux_of_carbon_into_forestry_and_agricultural_products_due_to_crop_harvesting", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Harvested biomass that goes into product pool", + "long_name": "Harvested Biomass That Goes into Product Pool", "comment": "be it food or wood harvest, any carbon that is subsequently stored is reported here", "dimensions": "longitude latitude time", "out_name": "fHarvestToProduct", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1477,16 +1329,17 @@ "ok_max_mean_abs": "" }, "fLitterFire": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "fire_CO2_emissions_from_litter_carbon", + "standard_name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_litter_in_fires", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Carbon Mass Flux from Litter, CWD or any non-living pool into Atmosphere due to CO2 Emission from all Fire", + "long_name": "Carbon Mass Flux from Litter, CWD or any non-Living Pool into Atmosphere Due to CO2 Emission from All Fire", "comment": "Required for unambiguous separation of vegetation and soil + litter turnover times, since total fire flux draws from both sources", "dimensions": "longitude latitude time", "out_name": "fLitterFire", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1494,12 +1347,13 @@ "ok_max_mean_abs": "" }, "fLuc": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "surface_net_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_anthropogenic_land_use_change", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Net Carbon Mass Flux into Atmosphere due to Land Use Change", + "long_name": "Net Carbon Mass Flux into Atmosphere Due to Land-Use Change", "comment": "Carbon mass flux per unit area into atmosphere due to human changes to land (excluding forest regrowth) accounting possibly for different time-scales related to fate of the wood, for example.", "dimensions": "longitude latitude time", "out_name": "fLuc", @@ -1511,33 +1365,35 @@ "ok_max_mean_abs": "" }, "fLulccAtmLut": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_direct_to_atmosphere_due_to_anthropogenic_land_use_land_cover_change", - "units": "kg s-1", - "cell_methods": "area: time: mean where landuse", + "standard_name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_anthropogenic_land_use_or_land_cover_change_excluding_forestry_and_agricultural_products", + "units": "kg m-2 s-1", + "cell_methods": "area: time: mean where sector", "cell_measures": "area: areacella", - "long_name": "carbon transferred directly to atmosphere due to any land-use or land-cover change activities including deforestation or agricultural fire", - "comment": "This annual mean flux refers to the transfer of carbon directly to the atmosphere due to any land-use or land-cover change activities. Include carbon transferred due to deforestation or agricultural directly into atsmophere, and emissions form anthropogenic pools into atmosphere", + "long_name": "Carbon Transferred Directly to Atmosphere Due to any Land-Use or Land-Cover Change Activities", + "comment": "This annual mean flux refers to the transfer of carbon directly to the atmosphere due to any land-use or land-cover change activities. Include carbon transferred due to deforestation or agricultural directly into atmosphere, and emissions form anthropogenic pools into atmosphere", "dimensions": "longitude latitude landUse time", "out_name": "fLulccAtmLut", - "type": "", - "positive": "", + "type": "real", + "positive": "up", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "fLulccProductLut": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "carbon_mass_flux_into_wood_and_agricultural_product_pools_due_to_anthropogenic_land_use_or_land_cover_change", + "standard_name": "carbon_mass_flux_into_forestry_and_agricultural_products_due_to_anthropogenic_land_use_or_land_cover_change", "units": "kg m-2 s-1", - "cell_methods": "area: time: mean where landuse", + "cell_methods": "area: time: mean where sector", "cell_measures": "area: areacella", - "long_name": "carbon harvested due to land-use or land-cover change process that enters anthropogenic product pools on tile", - "comment": "This annual mean flux refers to the transfer of carbon primarily through harvesting land use into anthropogenic product pools, e.g.,deforestation or wood harvestingfrom primary or secondary lands, food harvesting on croplands, harvesting (grazing) by animals on pastures.", + "long_name": "Carbon Harvested Due to Land-Use or Land-Cover Change Process That Enters Anthropogenic Product Pools on Tile", + "comment": "This annual mean flux refers to the transfer of carbon primarily through harvesting land use into anthropogenic product pools, e.g.,deforestation or wood harvesting from primary or secondary lands, food harvesting on croplands, harvesting (grazing) by animals on pastures.", "dimensions": "longitude latitude landUse time", "out_name": "fLulccProductLut", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1545,16 +1401,17 @@ "ok_max_mean_abs": "" }, "fLulccResidueLut": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "carbon_mass_flux_into_soil_and_litter_due_to_anthropogenic_land_use_or_land_cover_change", "units": "kg m-2 s-1", - "cell_methods": "area: time: mean where landuse", + "cell_methods": "area: time: mean where sector", "cell_measures": "area: areacella", - "long_name": "carbon transferred to soil or litter pools due to land-use or land-cover change processes on tile", + "long_name": "Carbon Transferred to Soil or Litter Pools Due to Land-Use or Land-Cover Change Processes on Tile", "comment": "This annual mean flux refers to the transfer of carbon into soil or litter pools due to any land use or land-cover change activities", "dimensions": "longitude latitude landUse time", "out_name": "fLulccResidueLut", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1562,33 +1419,35 @@ "ok_max_mean_abs": "" }, "fN2O": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "land_net_n2o_flux", + "standard_name": "surface_upward_mass_flux_of_nitrous_oxide_expressed_as_nitrogen_out_of_vegetation_and_litter_and_soil", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Total land N2O flux", - "comment": "", + "long_name": "Total Land N2O Flux", + "comment": "Surface upward flux of nitrous oxide (N2O) from vegetation (any living plants e.g. trees, shrubs, grass), litter (dead plant material in or above the soil), soil.", "dimensions": "longitude latitude time", "out_name": "fN2O", - "type": "", - "positive": "", + "type": "real", + "positive": "up", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "fNAnthDisturb": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "nitrogen_flux_into_atmos_due_to_direct_human_disturbance", + "standard_name": "tendency_of_atmosphere_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_anthropogenic_emission", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "nitrogen mass flux out of land due to any human activity", + "long_name": "Nitrogen Mass Flux out of Land Due to any Human Activity", "comment": "will require some careful definition to make sure we capture everything - any human activity that releases nitrogen from land instead of into product pool goes here. E.g. Deforestation fire, harvest assumed to decompose straight away, grazing...", "dimensions": "longitude latitude time", "out_name": "fNAnthDisturb", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1596,16 +1455,17 @@ "ok_max_mean_abs": "" }, "fNLandToOcean": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "nitrogen_mass_flux_into_ocean_from_rivers", + "standard_name": "mass_flux_of_nitrogen_compounds_expressed_as_nitrogen_into_sea_from_rivers", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Lateral transfer of nitrogen out of gridcell that eventually goes into ocean", + "long_name": "Lateral Transfer of Nitrogen out of Grid Cell That Eventually Goes into Ocean", "comment": "leached nitrogen etc that goes into run off or river routing and finds its way into ocean should be reported here.", "dimensions": "longitude latitude time", "out_name": "fNLandToOcean", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1613,16 +1473,17 @@ "ok_max_mean_abs": "" }, "fNLitterSoil": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "nitrogen_mass_flux_into_soil_from_litter", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", "long_name": "Total Nitrogen Mass Flux from Litter to Soil", - "comment": "", + "comment": "In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. 'Litter' is dead plant material in or above the soil.", "dimensions": "longitude latitude time", "out_name": "fNLitterSoil", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1630,33 +1491,35 @@ "ok_max_mean_abs": "" }, "fNOx": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "land_net_nox_flux", + "standard_name": "surface_upward_mass_flux_of_nox_expressed_as_nitrogen_out_of_vegetation_and_litter_and_soil", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Total land NOx flux", - "comment": "", + "long_name": "Total Land NOx Flux", + "comment": "The surface called 'surface' means the lower boundary of the atmosphere. 'Upward' indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. 'Nox' means a combination of two radical species containing nitrogen and oxygen NO+NO2. 'Vegetation' means any living plants e.g. trees, shrubs, grass. 'Litter' is dead plant material in or above the soil.", "dimensions": "longitude latitude time", "out_name": "fNOx", - "type": "", - "positive": "", + "type": "real", + "positive": "up", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "fNProduct": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "nitrogen_mass_flux_to_product_pool_due_to_anthorpogenic_activity", + "standard_name": "nitrogen_mass_flux_into_forestry_and_agricultural_products_due_to_anthropogenic_land_use_or_land_cover_change", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Deforested or harvested biomass as a result of anthropogenic land use or change", - "comment": "When land use change results in deforestation of natural vegetation (trees or grasslands) then natural biomass is removed. The treatment of deforested biomass differs significantly across models, but it shoule be straight-forward to compare deforested biomass across models.", + "long_name": "Deforested or Harvested Biomass as a Result of Anthropogenic Land-Use or Change", + "comment": "When land use change results in deforestation of natural vegetation (trees or grasslands) then natural biomass is removed. The treatment of deforested biomass differs significantly across models, but it should be straight-forward to compare deforested biomass across models.", "dimensions": "longitude latitude time", "out_name": "fNProduct", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1664,16 +1527,17 @@ "ok_max_mean_abs": "" }, "fNVegLitter": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "litter_nitrogen_flux", + "standard_name": "nitrogen_mass_flux_into_litter_from_vegetation", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", "long_name": "Total Nitrogen Mass Flux from Vegetation to Litter", - "comment": "", + "comment": "In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. 'Litter' is dead plant material in or above the soil. 'Vegetation' means any living plants e.g. trees, shrubs, grass.", "dimensions": "longitude latitude time", "out_name": "fNVegLitter", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1681,6 +1545,7 @@ "ok_max_mean_abs": "" }, "fNVegSoil": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "nitrogen_mass_flux_into_soil_from_vegetation_excluding_litter", "units": "kg m-2 s-1", @@ -1690,7 +1555,7 @@ "comment": "In some models part of nitrogen (e.g., root exudate) can go directly into the soil pool without entering litter.", "dimensions": "longitude latitude time", "out_name": "fNVegSoil", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1698,16 +1563,17 @@ "ok_max_mean_abs": "" }, "fNdep": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "deposition_of_nitrogen_onto_land", + "standard_name": "minus_tendency_of_atmosphere_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_deposition", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", "long_name": "Dry and Wet Deposition of Reactive Nitrogen onto Land", - "comment": "", + "comment": "Surface deposition rate of nitrogen.", "dimensions": "longitude latitude time", "out_name": "fNdep", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1715,16 +1581,17 @@ "ok_max_mean_abs": "" }, "fNfert": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "fertiliser_of_nitrogen_onto_land", + "standard_name": "tendency_of_soil_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_fertilization", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "total N added for cropland fertilisation (artificial and manure)", - "comment": "relative to total land area of a grid cell, not relative to agricultural area", + "long_name": "Total Nitrogen Added for Cropland Fertilisation (Artificial and Manure)", + "comment": "Total Nitrogen added for cropland fertilisation (artificial and manure). Relative to total land area of a grid cell, not relative to agricultural area", "dimensions": "longitude latitude time", "out_name": "fNfert", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1732,16 +1599,17 @@ "ok_max_mean_abs": "" }, "fNgas": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "land_nitrogen_lost_to_atmosphere", + "standard_name": "surface_upward_mass_flux_of_nitrogen_compounds_expressed_as_nitrogen", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Total Nitrogen lost to the atmosphere (sum of NHx, NOx, N2O, N2)", - "comment": "", + "long_name": "Total Nitrogen Lost to the Atmosphere (Sum of NHx, NOx, N2O, N2)", + "comment": "Total flux of Nitrogen from the land into the atmosphere.", "dimensions": "longitude latitude time", "out_name": "fNgas", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1749,16 +1617,17 @@ "ok_max_mean_abs": "" }, "fNgasFire": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "land_nitrogen_lost_to_atmosphere_due_to_fire", + "standard_name": "surface_upward_mass_flux_of_nitrogen_compounds_expressed_as_nitrogen_due_to_emission_from_fires", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Total N lost to the atmosphere (including NHx, NOx, N2O, N2) from fire.", - "comment": "", + "long_name": "Total Nitrogen Lost to the Atmosphere (Including NHx, NOx, N2O, N2) from Fire", + "comment": "Flux of Nitrogen from the land into the atmosphere due to fire", "dimensions": "longitude latitude time", "out_name": "fNgasFire", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1766,16 +1635,17 @@ "ok_max_mean_abs": "" }, "fNgasNonFire": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "land_nitrogen_lost_to_atmosphere_not_due_to_fire", + "standard_name": "surface_upward_mass_flux_of_nitrogen_compounds_expressed_as_nitrogen_due_to_all_land_processes_excluding_fires", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Total N lost to the atmosphere (including NHx, NOx, N2O, N2) from all processes except fire.", - "comment": "", + "long_name": "Total Nitrogen Lost to the Atmosphere (Including NHx, NOx, N2O, N2) from All Processes Except Fire", + "comment": "Flux of Nitrogen from the land into the atmosphere due to all processes other than fire", "dimensions": "longitude latitude time", "out_name": "fNgasNonFire", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1783,16 +1653,17 @@ "ok_max_mean_abs": "" }, "fNleach": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "land_nitrogen_lost_to_leaching", + "standard_name": "mass_flux_of_carbon_out_of_soil_due_to_leaching_and_runoff", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Total N loss to leaching or runoff (sum of ammonium, nitrite and nitrate)", - "comment": "", + "long_name": "Total Nitrogen Loss to Leaching or Runoff (Sum of Ammonium, Nitrite and Nitrate)", + "comment": "In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. The specification of a physical process by the phrase 'due_to_' process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. 'Leaching' means the loss of water soluble chemical species from soil. Runoff is the liquid water which drains from land. If not specified, 'runoff' refers to the sum of surface runoff and subsurface drainage.", "dimensions": "longitude latitude time", "out_name": "fNleach", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1800,16 +1671,17 @@ "ok_max_mean_abs": "" }, "fNloss": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "land_nitrogen_lost", + "standard_name": "surface_upward_mass_flux_of_nitrogen_compounds_expressed_as_nitrogen_out_of_vegetation_and_litter_and_soil", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Total N lost (including NHx, NOx, N2O, N2 and leaching)", - "comment": "Not all models split losses into gasesous and leaching", + "long_name": "Total Nitrogen Lost (Including NHx, NOx, N2O, N2 and Leaching)", + "comment": "Not all models split losses into gaseous and leaching", "dimensions": "longitude latitude time", "out_name": "fNloss", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1817,16 +1689,17 @@ "ok_max_mean_abs": "" }, "fNnetmin": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "net_nitrogen_mineralisation", + "standard_name": "mass_flux_of_nitrogen_compounds_expressed_as_nitrogen_out_of_litter_and_soil_due_to_immobilisation_and_remineralization", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Net nitrogen release from soil and litter as the outcome of nitrogen immobilisation and gross mineralisation", - "comment": "", + "long_name": "Net Nitrogen Release from Soil and Litter as the Outcome of Nitrogen Immobilisation and Gross Mineralisation", + "comment": "Loss of soil nitrogen through remineralization and immobilisation. Remineralization is the degradation of organic matter into inorganic forms of carbon, nitrogen, phosphorus and other micronutrients, which consumes oxygen and releases energy. Immobilisation of nitrogen refers to retention of nitrogen by micro-organisms under certain conditions, making it unavailable for plants.", "dimensions": "longitude latitude time", "out_name": "fNnetmin", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1834,16 +1707,17 @@ "ok_max_mean_abs": "" }, "fNup": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "plant_nitrogen_uptake", + "standard_name": "tendency_of_vegetation_mass_content_of_nitrogen_compounds_expressed_as_nitrogen_due_to_fixation", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "total plant nitrogen uptake (sum of ammonium and nitrate), irrespective of the source of nitrogen", - "comment": "", + "long_name": "Total Plant Nitrogen Uptake (Sum of Ammonium and Nitrate) Irrespective of the Source of Nitrogen", + "comment": "The uptake of nitrogen by fixation: nitrogen fixation means the uptake of nitrogen gas directly from the atmosphere. ", "dimensions": "longitude latitude time", "out_name": "fNup", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1851,16 +1725,17 @@ "ok_max_mean_abs": "" }, "fProductDecomp": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "Carbon_flux_out_of_storage_product_pools_into_atmos", + "standard_name": "tendency_of_atmosphere_mass_content_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_forestry_and_agricultural_products", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "decomposition out of product pools to CO2 in atmos", - "comment": "", + "long_name": "Decomposition out of Product Pools to CO2 in Atmosphere", + "comment": "Flux of CO2 from product pools into the atmosphere. Examples of 'forestry and agricultural products' are paper, cardboard, furniture, timber for construction, biofuels and food for both humans and livestock. Models that simulate land use changes have one or more pools of carbon that represent these products in order to conserve carbon and allow its eventual release into the atmosphere, for example, when the products decompose in landfill sites.", "dimensions": "longitude latitude time", "out_name": "fProductDecomp", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1868,16 +1743,17 @@ "ok_max_mean_abs": "" }, "fProductDecompLut": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "tendency_of_atmospheric_mass_content_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_wood_and_agricultural_product_pool", - "units": "kg s-1", - "cell_methods": "area: time: mean where landuse", + "standard_name": "tendency_of_atmosphere_mass_content_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_forestry_and_agricultural_products", + "units": "kg m-2 s-1", + "cell_methods": "area: time: mean where sector", "cell_measures": "area: areacella", - "long_name": "flux from wood and agricultural product pools on land use tile into atmosphere", - "comment": "If a model has explicit anthropogenic product pools by land use tile", + "long_name": "Flux from Wood and Agricultural Product Pools on Land Use Tile into Atmosphere", + "comment": "Flux of CO2 from product pools into the atmosphere. Examples of 'forestry and agricultural products' are paper, cardboard, furniture, timber for construction, biofuels and food for both humans and livestock. Models that simulate land use changes have one or more pools of carbon that represent these products in order to conserve carbon and allow its eventual release into the atmosphere, for example, when the products decompose in landfill sites. Produce this variable i a model has explicit anthropogenic product pools by land use tile", "dimensions": "longitude latitude landUse time", "out_name": "fProductDecompLut", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1885,16 +1761,17 @@ "ok_max_mean_abs": "" }, "fVegFire": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "fire_CO2_emissions_from_vegetation_carbon", + "standard_name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_vegetation_in_fires", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Carbon Mass Flux from Vegetation into Atmosphere due to CO2 Emission from all Fire", + "long_name": "Carbon Mass Flux from Vegetation into Atmosphere Due to CO2 Emission from All Fire", "comment": "Required for unambiguous separation of vegetation and soil + litter turnover times, since total fire flux draws from both sources", "dimensions": "longitude latitude time", "out_name": "fVegFire", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1902,8 +1779,9 @@ "ok_max_mean_abs": "" }, "fVegLitterMortality": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "mortality_litter_carbon_flux", + "standard_name": "mass_flux_of_carbon_into_litter_from_vegetation_due_to_mortality", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", @@ -1911,7 +1789,7 @@ "comment": "needed to separate changing vegetation C turnover times resulting from changing allocation versus changing mortality", "dimensions": "longitude latitude time", "out_name": "fVegLitterMortality", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1919,8 +1797,9 @@ "ok_max_mean_abs": "" }, "fVegLitterSenescence": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "senescence_litter_carbon_flux", + "standard_name": "mass_flux_of_carbon_into_litter_from_vegetation_due_to_senescence", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", @@ -1928,7 +1807,7 @@ "comment": "needed to separate changing vegetation C turnover times resulting from changing allocation versus changing mortality", "dimensions": "longitude latitude time", "out_name": "fVegLitterSenescence", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1936,16 +1815,17 @@ "ok_max_mean_abs": "" }, "fVegSoilMortality": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "mortality_vegtosoil_carbon_flux", + "standard_name": "mass_flux_of_carbon_into_soil_from_vegetation_due_to_mortality", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Total Carbon Mass Flux from Vegetation to Soil as a result of mortality", + "long_name": "Total Carbon Mass Flux from Vegetation to Soil as a Result of Mortality", "comment": "needed to separate changing vegetation C turnover times resulting from changing allocation versus changing mortality", "dimensions": "longitude latitude time", "out_name": "fVegSoilMortality", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1953,16 +1833,17 @@ "ok_max_mean_abs": "" }, "fVegSoilSenescence": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "senescence_vegtosoil_carbon_flux", + "standard_name": "mass_flux_of_carbon_into_soil_from_vegetation_due_to_senescence", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Total Carbon Mass Flux from Vegetation to Soil as a result of leaf, branch, and root senescence", + "long_name": "Total Carbon Mass Flux from Vegetation to Soil as a Result of Leaf, Branch, and Root Senescence", "comment": "needed to separate changing vegetation C turnover times resulting from changing allocation versus changing mortality", "dimensions": "longitude latitude time", "out_name": "fVegSoilSenescence", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1970,304 +1851,34 @@ "ok_max_mean_abs": "" }, "fahLut": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "surface_upward_heat_flux_due_to_anthropogenic_energy_consumption", "units": "W m-2", - "cell_methods": "area: time: mean where landuse", + "cell_methods": "area: time: mean where sector", "cell_measures": "area: areacella", - "long_name": "Anthropogenic heat flux generated from non-renewable human primary energy consumption, including energy use by vehicles, commercial and residential buildings, industry, and power plants. Primary energy refers to energy in natural resources, fossil and nonfossil, before conversion into other forms, such as electricity.", - "comment": "", + "long_name": "Anthropogenic Heat Flux Generated from non-Renewable Human Primary Energy Consumption", + "comment": "Anthropogenic heat flux generated from non-renewable human primary energy consumption, including energy use by vehicles, commercial and residential buildings, industry, and power plants. Primary energy refers to energy in natural resources, fossil and nonfossil, before conversion into other forms, such as electricity.", "dimensions": "longitude latitude landUse time", "out_name": "fahLut", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "fbddtalk": { - "modeling_realm": "ocnBgChem", - "standard_name": "integral_wrt_depth_of_tendency_of_sea_water_alkalinity_expressed_as_mole_equivalent_due_to_biological_processes", - "units": "mol m-2 s-1", - "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello volume: volcello", - "long_name": "Rate of Change of Biological Alkalinity due to Biological Activity", - "comment": "vertical integral of net biological terms in time rate of change of alkalinity", - "dimensions": "longitude latitude olevel time", - "out_name": "fbddtalk", - "type": "real", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "fbddtdic": { - "modeling_realm": "ocnBgChem", - "standard_name": "tendency_of_ocean_mole_content_of_dissolved_inorganic_carbon_due_to_biological_processes", - "units": "mol m-2 s-1", - "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello volume: volcello", - "long_name": "Rate of Change of Dissolved Inorganic Carbon due to Biological Activity", - "comment": "vertical integral of net biological terms in time rate of change of dissolved inorganic carbon", - "dimensions": "longitude latitude olevel time", - "out_name": "fbddtdic", - "type": "real", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "fbddtdife": { - "modeling_realm": "ocnBgChem", - "standard_name": "tendency_of_ocean_mole_content_of_dissolved_inorganic_iron_due_to_biological_processes", - "units": "mol m-2 s-1", - "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello volume: volcello", - "long_name": "Rate of Change of Dissolved Inorganic Iron due to Biological Activity", - "comment": "vertical integral of net biological terms in time rate of change of dissolved inorganic iron", - "dimensions": "longitude latitude olevel time", - "out_name": "fbddtdife", - "type": "real", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "fbddtdin": { - "modeling_realm": "ocnBgChem", - "standard_name": "tendency_of_ocean_mole_content_of_dissolved_inorganic_nitrogen_due_to_biological_processes", - "units": "mol m-2 s-1", - "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello volume: volcello", - "long_name": "Rate of Change of Dissolved Inorganic Nitrogen due to Biological Activity", - "comment": "vertical integral of net biological terms in time rate of change of nitrogen nutrients (e.g. NO3+NH4)", - "dimensions": "longitude latitude olevel time", - "out_name": "fbddtdin", - "type": "real", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "fbddtdip": { - "modeling_realm": "ocnBgChem", - "standard_name": "tendency_of_ocean_mole_content_of_dissolved_inorganic_phosphorus_due_to_biological_processes", - "units": "mol m-2 s-1", - "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello volume: volcello", - "long_name": "Rate of Change of Dissolved Inorganic Phosphorus due to Biological Activity", - "comment": "vertical integral of net biological terms in time rate of change of phosphate", - "dimensions": "longitude latitude olevel time", - "out_name": "fbddtdip", - "type": "real", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "fbddtdisi": { - "modeling_realm": "ocnBgChem", - "standard_name": "tendency_of_ocean_mole_content_of_dissolved_inorganic_silicon_due_to_biological_processes", - "units": "mol m-2 s-1", - "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello volume: volcello", - "long_name": "Rate of Change of Dissolved Inorganic Silicon due to Biological Activity", - "comment": "vertical integral of net biological terms in time rate of change of dissolved inorganic silicate", - "dimensions": "longitude latitude olevel time", - "out_name": "fbddtdisi", - "type": "real", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "fddtalk": { - "modeling_realm": "ocnBgChem", - "standard_name": "integral_wrt_depth_of_tendency_of_sea_water_alkalinity_expressed_as_mole_equivalent", - "units": "mol m-2 s-1", - "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello volume: volcello", - "long_name": "Rate of Change of Total Alkalinity", - "comment": "vertical integral of net time rate of change of alkalinity", - "dimensions": "longitude latitude olevel time", - "out_name": "fddtalk", - "type": "real", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "fddtdic": { - "modeling_realm": "ocnBgChem", - "standard_name": "tendency_of_ocean_mole_content_of_dissolved_inorganic_carbon", - "units": "mol m-2 s-1", - "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello volume: volcello", - "long_name": "Rate of Change of Net Dissolved Inorganic Carbon", - "comment": "", - "dimensions": "longitude latitude olevel time", - "out_name": "fddtdic", - "type": "real", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "fddtdife": { - "modeling_realm": "ocnBgChem", - "standard_name": "tendency_of_ocean_mole_content_of_dissolved_inorganic_iron", - "units": "mol m-2 s-1", - "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello volume: volcello", - "long_name": "Rate of Change of Net Dissolved Inorganic Iron", - "comment": "vertical integral of net time rate of change of dissolved inorganic iron", - "dimensions": "longitude latitude olevel time", - "out_name": "fddtdife", - "type": "real", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "fddtdin": { - "modeling_realm": "ocnBgChem", - "standard_name": "tendency_of_ocean_mole_content_of_dissolved_inorganic_nitrogen", - "units": "mol m-2 s-1", - "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello volume: volcello", - "long_name": "Rate of Change of Net Dissolved Inorganic Nitrogen", - "comment": "Net time rate of change of nitrogen nutrients (e.g. NO3+NH4)", - "dimensions": "longitude latitude olevel time", - "out_name": "fddtdin", - "type": "real", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "fddtdip": { - "modeling_realm": "ocnBgChem", - "standard_name": "tendency_of_ocean_mole_content_of_dissolved_inorganic_phosphorus", - "units": "mol m-2 s-1", - "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello volume: volcello", - "long_name": "Rate of Change of Net Dissolved Inorganic Phosphate", - "comment": "vertical integral of net time rate of change of phosphate", - "dimensions": "longitude latitude olevel time", - "out_name": "fddtdip", - "type": "real", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "fddtdisi": { - "modeling_realm": "ocnBgChem", - "standard_name": "tendency_of_ocean_mole_content_of_dissolved_inorganic_silicon", - "units": "mol m-2 s-1", - "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello volume: volcello", - "long_name": "Rate of Change of Net Dissolved Inorganic Silicon", - "comment": "vertical integral of net time rate of change of dissolved inorganic silicate", - "dimensions": "longitude latitude olevel time", - "out_name": "fddtdisi", - "type": "real", - "positive": "", + "type": "real", + "positive": "up", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "fg14co2": { - "modeling_realm": "ocnBgChem", - "standard_name": "air_sea_flux_of_14CO2", - "units": "mol m-2 s-1", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "surface_downward_mass_flux_of_14C_dioxide_abiotic_analogue_expressed_as_carbon", + "units": "kg m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Total air-sea flux of 14CO2", - "comment": "", + "long_name": "Total Surface Downward Flux of 14CO2 into Ocean", + "comment": "Gas exchange flux of carbon-14 as CO2 (positive into ocean)", "dimensions": "longitude latitude time", "out_name": "fg14co2", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "fg14co2abio": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_downward_mass_flux_of_abiotic_14_carbon_dioxide_expressed_as_carbon", - "units": "kg m-2 s-1", - "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello volume: volcello", - "long_name": "Surface Downward Flux of Abiotic 14CO2", - "comment": "Gas exchange flux of abiotic 14CO2 (positive into ocean)", - "dimensions": "longitude latitude olevel time", - "out_name": "fg14co2abio", - "type": "real", - "positive": "down", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "fgco2abio": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_downward_mass_flux_of_abiotic_carbon_dioxide_expressed_as_carbon", - "units": "kg m-2 s-1", - "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello volume: volcello", - "long_name": "Surface Downward Flux of Abiotic CO2", - "comment": "Gas exchange flux of abiotic CO2 (positive into ocean)", - "dimensions": "longitude latitude olevel time", - "out_name": "fgco2abio", - "type": "real", - "positive": "down", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "fgco2nat": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_downward_mass_flux_of_natural_carbon_dioxide_expressed_as_carbon", - "units": "kg m-2 s-1", - "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello volume: volcello", - "long_name": "Surface Downward Flux of Natural CO2", - "comment": "Gas exchange flux of natural CO2 (positive into ocean)", - "dimensions": "longitude latitude olevel time", - "out_name": "fgco2nat", - "type": "real", - "positive": "down", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "fgdms": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_upward_mole_flux_of_dimethyl_sulfide", - "units": "mol m-2 s-1", - "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello volume: volcello", - "long_name": "Surface Upward Flux of DMS", - "comment": "Gas exchange flux of DMS (positive into atmosphere)", - "dimensions": "longitude latitude olevel time", - "out_name": "fgdms", "type": "real", "positive": "", "valid_min": "", @@ -2276,16 +1887,17 @@ "ok_max_mean_abs": "" }, "flandice": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "water_flux_into_sea_water_from_land_ice", "units": "kg m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Water flux into Sea Water from Land Ice", + "long_name": "Water Flux into Sea Water from Land Ice", "comment": "Computed as the water flux into the ocean due to land ice (runoff water from surface and base of land ice or melt from base of ice shelf or vertical ice front) into the ocean divided by the area ocean portion of the grid cell", "dimensions": "longitude latitude time", "out_name": "flandice", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2293,8 +1905,9 @@ "ok_max_mean_abs": "" }, "flashrate": { + "frequency": "mon", "modeling_realm": "atmosChem", - "standard_name": "lightning_flash_rate", + "standard_name": "frequency_of_lightning_flashes_per_unit_area", "units": "km-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", @@ -2302,7 +1915,7 @@ "comment": "proposed name: lightning_flash_rate (units to be interpreted as 'counts km-2 s-1)", "dimensions": "longitude latitude time", "out_name": "flashrate", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2310,16 +1923,17 @@ "ok_max_mean_abs": "" }, "fracLut": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "area_fraction", "units": "%", "cell_methods": "area: mean where land over all_area_types time: mean", "cell_measures": "area: areacella", - "long_name": "fraction of grid cell for each land use tile", - "comment": "end of year values (not annual mean); note that fraction should be reported as fraction of land grid cell (example: frac_lnd = 0.5, frac_ocn = 0.5, frac_crop_lnd = 0.2 (of land portion of grid cell), then frac_lut(crp) = 0.5*0.2 = 0.1)", + "long_name": "Percentage of Grid Cell for Each Land-Use Tile", + "comment": "End of year values (not annual mean); note that percentage should be reported as percentage of land grid cell (example: frac_lnd = 0.5, frac_ocn = 0.5, frac_crop_lnd = 0.2 (of land portion of grid cell), then frac_lut(crop) = 0.5*0.2 = 0.1)", "dimensions": "longitude latitude landUse time", "out_name": "fracLut", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2327,16 +1941,17 @@ "ok_max_mean_abs": "" }, "gppGrass": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "gross_primary_productivity_of_biomass_expressed_as_carbon", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where natural_grasses (comment: mask=grassFrac)", "cell_measures": "area: areacella", - "long_name": "gross primary production on grass tiles", - "comment": "Total GPP of grass in the gridcell", + "long_name": "Gross Primary Production on Grass Tiles", + "comment": "Total GPP of grass in the grid cell", "dimensions": "longitude latitude time", "out_name": "gppGrass", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2344,16 +1959,17 @@ "ok_max_mean_abs": "" }, "gppLut": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "gross_primary_productivity_of_biomass_expressed_as_carbon", "units": "kg m-2 s-1", - "cell_methods": "area: time: mean where landuse", + "cell_methods": "area: time: mean where sector", "cell_measures": "area: areacella", - "long_name": "gross primary productivity on land use tile", - "comment": "", + "long_name": "Gross Primary Productivity on Land-Use Tile", + "comment": "The rate of synthesis of biomass from inorganic precursors by autotrophs ('producers') expressed as the mass of carbon which it contains. For example, photosynthesis in plants or phytoplankton. The producers also respire some of this biomass and the difference is referred to as the net primary production. Reported on land-use tiles.", "dimensions": "longitude latitude landUse time", "out_name": "gppLut", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2361,16 +1977,17 @@ "ok_max_mean_abs": "" }, "gppShrub": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "gross_primary_productivity_of_biomass_expressed_as_carbon", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where shrubs (comment: mask=shrubFrac)", "cell_measures": "area: areacella", - "long_name": "gross primary production on Shrub tiles", - "comment": "Total GPP of shrubs in the gridcell", + "long_name": "Gross Primary Production on Shrub Tiles", + "comment": "Total GPP of shrubs in the grid cell", "dimensions": "longitude latitude time", "out_name": "gppShrub", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2378,16 +1995,17 @@ "ok_max_mean_abs": "" }, "gppTree": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "gross_primary_productivity_of_biomass_expressed_as_carbon", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where trees (comment: mask=treeFrac)", "cell_measures": "area: areacella", - "long_name": "gross primary production on tree tiles", - "comment": "Total GPP of trees in the gridcell", + "long_name": "Gross Primary Production on Tree Tiles", + "comment": "Total GPP of trees in the grid cell", "dimensions": "longitude latitude time", "out_name": "gppTree", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2395,16 +2013,17 @@ "ok_max_mean_abs": "" }, "gppc13": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "gross_primary_productivity_of_c13", + "standard_name": "gross_primary_productivity_of_biomass_expressed_as_13C", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Mass Flux of 13C out of Atmosphere due to Gross Primary Production on Land", - "comment": "", + "long_name": "Mass Flux of 13C out of Atmosphere Due to Gross Primary Production on Land", + "comment": "The rate of synthesis of carbon-13 in biomass from inorganic precursors by autotrophs ('producers') expressed as the mass of carbon which it contains. For example, photosynthesis in plants or phytoplankton. The producers also respire some of this biomass and the difference is referred to as the net primary production. ", "dimensions": "longitude latitude time", "out_name": "gppc13", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2412,16 +2031,17 @@ "ok_max_mean_abs": "" }, "gppc14": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "gross_primary_productivity_of_c14", + "standard_name": "gross_primary_productivity_of_biomass_expressed_as_14C", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Mass Flux of 14C out of Atmosphere due to Gross Primary Production on Land", - "comment": "", + "long_name": "Mass Flux of 14C out of Atmosphere Due to Gross Primary Production on Land", + "comment": "The rate of synthesis of carbon-14 in biomass from inorganic precursors by autotrophs ('producers') expressed as the mass of carbon which it contains. For example, photosynthesis in plants or phytoplankton. The producers also respire some of this biomass and the difference is referred to as the net primary production. ", "dimensions": "longitude latitude time", "out_name": "gppc14", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2429,16 +2049,17 @@ "ok_max_mean_abs": "" }, "grassFracC3": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "area_fraction", "units": "%", "cell_methods": "area: mean where land over all_area_types time: mean", "cell_measures": "area: areacella", - "long_name": "C3 grass Area Percentage", - "comment": "Fraction of entire grid cell covered by C3 grass.", - "dimensions": "longitude latitude time typec3pft typenatgr", + "long_name": "C3 Grass Area Percentage", + "comment": "Percentage of entire grid cell covered by C3 grass.", + "dimensions": "longitude latitude time typec3natg", "out_name": "grassFracC3", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2446,16 +2067,17 @@ "ok_max_mean_abs": "" }, "grassFracC4": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "area_fraction", "units": "%", "cell_methods": "area: mean where land over all_area_types time: mean", "cell_measures": "area: areacella", - "long_name": "C4 grass Area Percentage", - "comment": "Fraction of entire grid cell covered by C4 grass.", - "dimensions": "longitude latitude time typec4pft typenatgr", + "long_name": "C4 Grass Area Percentage", + "comment": "Percentage of entire grid cell covered by C4 grass.", + "dimensions": "longitude latitude time typec4natg", "out_name": "grassFracC4", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2463,33 +2085,17 @@ "ok_max_mean_abs": "" }, "grplmxrat27": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "mass_fraction_of_graupel_in_air", - "units": "1.0", + "units": "1", "cell_methods": "time: mean", "cell_measures": "area: areacella", "long_name": "Graupel Mixing Ratio", "comment": "Graupel mixing ratio", "dimensions": "longitude latitude plev27 time", "out_name": "grplmxrat", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "hcont300": { - "modeling_realm": "ocean", - "standard_name": "heat_content_of_ocean_layer", - "units": "m K", - "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", - "long_name": "Heat content of upper 300 meters", - "comment": "Used in PMIP2", - "dimensions": "longitude latitude time depth300m", - "out_name": "hcont300", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2497,50 +2103,53 @@ "ok_max_mean_abs": "" }, "hflsLut": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "surface_upward_latent_heat_flux", "units": "W m-2", - "cell_methods": "area: time: mean where landuse", + "cell_methods": "area: time: mean where sector", "cell_measures": "area: areacella", - "long_name": "latent heat flux on land use tile", - "comment": "", + "long_name": "Latent Heat Flux on Land-Use Tile", + "comment": "The surface called 'surface' means the lower boundary of the atmosphere. 'Upward' indicates a vector component which is positive when directed upward (negative downward). The surface latent heat flux is the exchange of heat between the surface and the air on account of evaporation (including sublimation). In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions": "longitude latitude landUse time", "out_name": "hflsLut", - "type": "", - "positive": "", + "type": "real", + "positive": "up", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "hfssLut": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "surface_upward_sensible_heat_flux", "units": "W m-2", - "cell_methods": "area: time: mean where landuse", + "cell_methods": "area: time: mean where sector", "cell_measures": "area: areacella", - "long_name": "sensible heat flux on land use tile", - "comment": "", + "long_name": "Sensible Heat Flux on Land-Use Tile", + "comment": "Upward sensible heat flux on land use tiles. The surface sensible heat flux, also called turbulent heat flux, is the exchange of heat between the surface and the air by motion of air.", "dimensions": "longitude latitude landUse time", "out_name": "hfssLut", - "type": "", - "positive": "", + "type": "real", + "positive": "up", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "hursminCrop": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "relative_humidity", "units": "%", - "cell_methods": "area: mean time: minimum within days time: mean over days", + "cell_methods": "area: mean where crops time: minimum within days time: mean over days", "cell_measures": "area: areacella", "long_name": "Daily Minimum Near-Surface Relative Humidity over Crop Tile", - "comment": "minimum near-surface (usually, 2 meter) relative humidity (add cell_method attribute 'time: min')", + "comment": "The relative humidity with respect to liquid water for T> 0 C, and with respect to ice for T<0 C.", "dimensions": "longitude latitude time height2m", "out_name": "hursminCrop", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2548,16 +2157,17 @@ "ok_max_mean_abs": "" }, "hus": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "specific_humidity", - "units": "1.0", - "cell_methods": "time: mean", + "units": "1", + "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Specific Humidity", - "comment": "", - "dimensions": "longitude latitude plev7c time", + "comment": "Specific humidity is the mass fraction of water vapor in (moist) air.", + "dimensions": "longitude latitude plev7h time", "out_name": "hus", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2565,16 +2175,17 @@ "ok_max_mean_abs": "" }, "hus27": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "specific_humidity", - "units": "1.0", + "units": "1", "cell_methods": "time: mean", "cell_measures": "area: areacella", "long_name": "Specific Humidity", - "comment": "", + "comment": "Specific humidity is the mass fraction of water vapor in (moist) air.", "dimensions": "longitude latitude plev27 time", "out_name": "hus", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2582,16 +2193,17 @@ "ok_max_mean_abs": "" }, "hussLut": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "specific_humidity", - "units": "1.0", - "cell_methods": "area: time: mean where landuse", + "units": "1", + "cell_methods": "area: time: mean where sector", "cell_measures": "area: areacella", - "long_name": "near-surface specific humidity on land use tile", + "long_name": "Near-Surface Specific Humidity on Land-Use Tile", "comment": "Normally, the specific humidity should be reported at the 2 meter height", "dimensions": "longitude latitude landUse time height2m", "out_name": "hussLut", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2599,16 +2211,17 @@ "ok_max_mean_abs": "" }, "intuadse": { + "frequency": "mon", "modeling_realm": "atmos", - "standard_name": "vertical_integral_eastward_wind_by_dry_static_energy", - "units": "1.e6 J m-1 s-1", + "standard_name": "eastward_atmosphere_dry_static_energy_transport_across_unit_distance", + "units": "MJ m-1 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Vertically integrated Eastward dry transport (cp.T +zg).u (Mass_weighted_vertical integral of the product of northward wind by dry static_energy per mass unit)", - "comment": "Used in PMIP2", + "long_name": "Vertically Integrated Eastward Dry Statice Energy Transport", + "comment": "Vertically integrated eastward dry static energy transport (cp.T +zg).v (Mass_weighted_vertical integral of the product of eastward wind by dry static_energy per mass unit)", "dimensions": "longitude latitude time", "out_name": "intuadse", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2616,16 +2229,17 @@ "ok_max_mean_abs": "" }, "intuaw": { + "frequency": "mon", "modeling_realm": "atmos", - "standard_name": "vertical_integral_eastward_wind_by_total_water", + "standard_name": "eastward_atmosphere_water_transport_across_unit_distance", "units": "kg m-1 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Vertically integrated Eastward moisture transport (Mass_weighted_vertical integral of the product of eastward wind by total water mass per unit mass)", - "comment": "Used in PMIP2", + "long_name": "Vertically Integrated Eastward Moisture Transport", + "comment": "Vertically integrated Eastward moisture transport (Mass weighted vertical integral of the product of eastward wind by total water mass per unit mass)", "dimensions": "longitude latitude time", "out_name": "intuaw", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2633,16 +2247,17 @@ "ok_max_mean_abs": "" }, "intvadse": { + "frequency": "mon", "modeling_realm": "atmos", - "standard_name": "vertical_integral_northward_wind_by_dry_static_energy", - "units": "1.e6 J m-1 s-1", + "standard_name": "northward_atmosphere_dry_static_energy_transport_across_unit_distance", + "units": "MJ m-1 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Vertically integrated Northward dry transport (cp.T +zg).v (Mass_weighted_vertical integral of the product of northward wind by dry static_energy per mass unit)", - "comment": "Used in PMIP2", + "long_name": "Vertically Integrated Northward Dry Static Energy Transport", + "comment": "Vertically integrated northward dry static energy transport (cp.T +zg).v (Mass_weighted_vertical integral of the product of northward wind by dry static_energy per mass unit)", "dimensions": "longitude latitude time", "out_name": "intvadse", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2650,16 +2265,17 @@ "ok_max_mean_abs": "" }, "intvaw": { + "frequency": "mon", "modeling_realm": "atmos", - "standard_name": "vertical_integral_northward_wind_by_total_water", + "standard_name": "northward_atmosphere_water_transport_across_unit_distance", "units": "kg m-1 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Vertically integrated Northward moisture transport (Mass_weighted_vertical integral of the product of northward wind by total water mass per unit mass)", - "comment": "Used in PMIP2", + "long_name": "Vertically Integrated Northward Moisture Transport", + "comment": "Vertically integrated Northward moisture transport (Mass_weighted_vertical integral of the product of northward wind by total water mass per unit mass)", "dimensions": "longitude latitude time", "out_name": "intvaw", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2667,33 +2283,35 @@ "ok_max_mean_abs": "" }, "irrLut": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "surface_downward_water_flux_due_to_irrigation", - "units": "kg s-1", - "cell_methods": "area: time: mean where landuse", + "standard_name": "surface_downward_mass_flux_of_water_due_to_irrigation", + "units": "kg m-2 s-1", + "cell_methods": "area: time: mean where sector", "cell_measures": "area: areacella", - "long_name": "Irrigation flux including any irrigation for crops, trees, pasture, or urban lawns", - "comment": "", + "long_name": "Irrigation Flux Including any Irrigation for Crops, Trees, Pasture, or Urban Lawns", + "comment": "Mass flux of water due to irrigation.", "dimensions": "longitude latitude landUse time", "out_name": "irrLut", - "type": "", - "positive": "", + "type": "real", + "positive": "down", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "jpdftaureicemodis": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "cloud_area_fraction_in_atmosphere_layer", "units": "%", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "MODIS Optical Thickness-Particle Size joint distribution, ice", - "comment": "", - "dimensions": "longitude latitude plev7c effectRadIc tau time", + "long_name": "MODIS Joint Distribution of Optical Thickness and Particle Size, Ice", + "comment": "Joint probability distribution function, giving probability of cloud as a function of optical thickness and particle size, as measured by MODIS. For cloud ice particles.", + "dimensions": "longitude latitude effectRadIc tau time", "out_name": "jpdftaureicemodis", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2701,16 +2319,17 @@ "ok_max_mean_abs": "" }, "jpdftaureliqmodis": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "cloud_area_fraction_in_atmosphere_layer", "units": "%", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "MODIS Optical Thickness-Particle Size joint distribution, liquid", - "comment": "", - "dimensions": "longitude latitude plev7c effectRadLi tau time", + "long_name": "MODIS Optical Thickness-Particle Size Joint Distribution, Liquid", + "comment": "Joint probability distribution function, giving probability of cloud as a function of optical thickness and particle size, as measured by MODIS. For liquid cloud particles.", + "dimensions": "longitude latitude effectRadLi tau time", "out_name": "jpdftaureliqmodis", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2718,16 +2337,17 @@ "ok_max_mean_abs": "" }, "laiLut": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "missing", - "units": "1.0", - "cell_methods": "area: time: mean where landuse", + "standard_name": "leaf_area_index", + "units": "1", + "cell_methods": "area: time: mean where sector", "cell_measures": "area: areacella", - "long_name": "Leaf Area Index on Land Use Tile", - "comment": "Note that if tile does not model lai, for example, on the urban tile, then should be reported as missing value", + "long_name": "Leaf Area Index on Land-Use Tile", + "comment": "A ratio obtained by dividing the total upper leaf surface area of vegetation by the (horizontal) surface area of the land on which it grows.", "dimensions": "longitude latitude landUse time", "out_name": "laiLut", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2735,16 +2355,17 @@ "ok_max_mean_abs": "" }, "loaddust": { + "frequency": "mon", "modeling_realm": "atmos", - "standard_name": "atmosphere_mass_content_of_dust_dry_aerosol", + "standard_name": "atmosphere_mass_content_of_dust_dry_aerosol_particles", "units": "kg m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Load of Dust", - "comment": "", + "comment": "The total dry mass of dust aerosol particles per unit area.", "dimensions": "longitude latitude time", "out_name": "loaddust", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2752,16 +2373,17 @@ "ok_max_mean_abs": "" }, "loadso4": { + "frequency": "mon", "modeling_realm": "atmos", - "standard_name": "atmosphere_mass_content_of_sulfate_dry_aerosol", + "standard_name": "atmosphere_mass_content_of_sulfate_dry_aerosol_particles", "units": "kg m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Load of SO4", - "comment": "", + "comment": "The total dry mass of sulfate aerosol particles per unit area.", "dimensions": "longitude latitude time", "out_name": "loadso4", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2769,16 +2391,17 @@ "ok_max_mean_abs": "" }, "loadss": { + "frequency": "mon", "modeling_realm": "atmos", - "standard_name": "atmosphere_mass_content_of_seasalt_dry_aerosol", + "standard_name": "atmosphere_mass_content_of_sea_salt_dry_aerosol_particles", "units": "kg m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Load of Seasalt", - "comment": "", + "long_name": "Load of Sea-Salt Aerosol", + "comment": "The total dry mass of sea salt aerosol particles per unit area.", "dimensions": "longitude latitude time", "out_name": "loadss", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2786,16 +2409,17 @@ "ok_max_mean_abs": "" }, "lwsrfasdust": { + "frequency": "mon", "modeling_realm": "atmos", - "standard_name": "tendency_of_all_sky_surface_longwave_flux_to_dust_ambient_aerosol_particles", + "standard_name": "surface_net_downward_longwave_dust_ambient_aerosol_particles_direct_radiative_effect", "units": "W m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "All-sky Surface Longwave radiative flux due to Dust", - "comment": "Balkanski - LSCE", + "long_name": "All-Sky Surface Longwave Radiative Flux Due to Dust", + "comment": "The direct radiative effect refers to the instantaneous radiative impact on the Earth's energy balance, excluding secondary effects such as changes in cloud cover.", "dimensions": "longitude latitude time", "out_name": "lwsrfasdust", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2803,16 +2427,17 @@ "ok_max_mean_abs": "" }, "lwsrfcsdust": { + "frequency": "mon", "modeling_realm": "atmos", - "standard_name": "tendency_of_clear_sky_surface_longwave_flux_to_dust_ambient_aerosol_particles", + "standard_name": "surface_net_downward_longwave_dust_ambient_aerosol_particles_direct_radiative_effect_assuming_clear_sky", "units": "W m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Clear-sky Surface Longwave radiative flux due to Dust", - "comment": "Balkanski - LSCE", + "long_name": "Clear-Sky Surface Longwave Radiative Flux Due to Dust", + "comment": "The direct radiative effect refers to the instantaneous radiative impact on the Earth's energy balance, excluding secondary effects such as changes in cloud cover. Calculating in clear-sky conditions.", "dimensions": "longitude latitude time", "out_name": "lwsrfcsdust", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2820,50 +2445,53 @@ "ok_max_mean_abs": "" }, "lwtoaasdust": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "toa_instantaneous_longwave_forcing", "units": "W m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "all sky lw-rf dust at toa", - "comment": "proposed name: toa_instantaneous_longwave_forcing_due_to_dust_ambient_aerosol", + "long_name": "TOA All-Sky Longwave Radiative Forcing Due to Dust", + "comment": "Instantaneous forcing is the radiative flux change caused instantaneously by an imposed change in radiative forcing agent (greenhouse gases, aerosol, solar radiation, etc.).", "dimensions": "longitude latitude time", "out_name": "lwtoaasdust", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, - "lwtoacs": { + "lwtoacsaer": { + "frequency": "mon", "modeling_realm": "atmos", - "standard_name": "tendency_of_clear_sky_top_of_atmosphere_longwave_flux_to_dust_ambient_aerosol_particles___2D_field_radiative_properties", + "standard_name": "toa_instantaneous_longwave_forcing", "units": "W m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Clear-sky TOA Longwave radiative flux due to Dust", - "comment": "Balkanski - LSCE", + "long_name": "TOA Clear-Sky longwave Radiative Forcing due to Aerosols", + "comment": "Instantaneous forcing is the radiative flux change caused instantaneously by an imposed change in radiative forcing agent (greenhouse gases, aerosol, solar radiation, etc.).", "dimensions": "longitude latitude time", - "out_name": "lwtoacs", - "type": "", + "out_name": "lwtoacsaer", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, - "lwtoacsaer": { + "lwtoacsdust": { + "frequency": "mon", "modeling_realm": "atmos", - "standard_name": "toa_instantaneous_longwave_forcing", + "standard_name": "toa_longwave_dust_ambient_aerosol_particles_direct_radiative_effect_assuming_clear_sky", "units": "W m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "clear sky lw-rf aerosols at toa", - "comment": "proposed name: toa_instantaneous_longwave_forcing_due_to_ambient_aerosol_assuming_clear_sky", + "long_name": "TOA Clear-Sky Longwave Radiative Forcing Due to Dust", + "comment": "The direct radiative effect refers to the instantaneous radiative impact on the Earth's energy balance, excluding secondary effects such as changes in cloud cover.", "dimensions": "longitude latitude time", - "out_name": "lwtoacsaer", - "type": "", + "out_name": "lwtoacsdust", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2871,67 +2499,17 @@ "ok_max_mean_abs": "" }, "md": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_emission", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Wet diameter mode coarse insoluble", - "comment": "Balkanski - LSCE", + "long_name": "Wet Diameter Mode Coarse Insoluble", + "comment": "Emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. the surface of the earth). ", "dimensions": "longitude latitude alevel time", "out_name": "md", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "mmraerso4": { - "modeling_realm": "atmos", - "standard_name": "mass_fraction_of_sulfate_dry_aerosol_in_air", - "units": "kg kg-1", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "Aerosol Sulfate Mass Mixing Ratio", - "comment": "", - "dimensions": "longitude latitude time", - "out_name": "mmraerso4", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "mmrbc": { - "modeling_realm": "aerosol", - "standard_name": "mass_fraction_of_elemental_carbon_dry_aerosol_particles_in_air", - "units": "kg kg-1", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "Elemental carbon mass mixing ratio", - "comment": "", - "dimensions": "longitude latitude time", - "out_name": "mmrbc", - "type": "float", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "mmrdust": { - "modeling_realm": "aerosol", - "standard_name": "mass_fraction_of_dust_dry_aerosol_particles_in_air", - "units": "kg kg-1", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "Dust aerosol mass mixing ratio", - "comment": "", - "dimensions": "longitude latitude time", - "out_name": "mmrdust", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2939,33 +2517,17 @@ "ok_max_mean_abs": "" }, "mmrno3": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "mass_fraction_of_nitrate_dry_aerosol_particles_in_air", "units": "kg kg-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "NO3 aerosol mass mixing ratio", - "comment": "", + "long_name": "NO3 Aerosol Mass Mixing Ratio", + "comment": "Dry mass fraction of nitrate aerosol particles in air.", "dimensions": "longitude latitude time", "out_name": "mmrno3", - "type": "float", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "mmrss": { - "modeling_realm": "aerosol", - "standard_name": "mass_fraction_of_seasalt_dry_aerosol_particles_in_air", - "units": "kg kg-1", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "Sea Salt mass mixing ratio", - "comment": "", - "dimensions": "longitude latitude time", - "out_name": "mmrss", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2973,16 +2535,17 @@ "ok_max_mean_abs": "" }, "mrlso": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "soil_liquid_water_content", + "standard_name": "liquid_water_content_of_soil_layer", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", "long_name": "Soil Liquid Water Content", - "comment": "the mass (summed over all all layers) of liquid water.", + "comment": "The mass (summed over all all layers) of liquid water.", "dimensions": "longitude latitude time", "out_name": "mrlso", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -2990,16 +2553,17 @@ "ok_max_mean_abs": "" }, "mrroLut": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "runoff_flux", "units": "kg m-2 s-1", - "cell_methods": "area: time: mean where landuse", + "cell_methods": "area: time: mean where sector", "cell_measures": "area: areacella", - "long_name": "Total runoff from land use tile", + "long_name": "Total Runoff from Land-Use Tile", "comment": "the total runoff (including 'drainage' through the base of the soil model) leaving the land use tile portion of the grid cell", "dimensions": "longitude latitude landUse time", "out_name": "mrroLut", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -3007,16 +2571,17 @@ "ok_max_mean_abs": "" }, "mrsfl": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "frozen_moisture_content_of_soil_layer", + "standard_name": "frozen_water_content_of_soil_layer", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Frozen water content of soil layer", + "long_name": "Frozen Water Content of Soil Layer", "comment": "in each soil layer, the mass of water in ice phase. Reported as 'missing' for grid cells occupied entirely by 'sea'", "dimensions": "longitude latitude sdepth time", "out_name": "mrsfl", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -3024,16 +2589,17 @@ "ok_max_mean_abs": "" }, "mrsll": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "liquid_moisture_content_of_soil_layer", + "standard_name": "liquid_water_content_of_soil_layer", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Liquid water content of soil layer", + "long_name": "Liquid Water Content of Soil Layer", "comment": "in each soil layer, the mass of water in liquid phase. Reported as 'missing' for grid cells occupied entirely by 'sea'", "dimensions": "longitude latitude sdepth time", "out_name": "mrsll", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -3041,16 +2607,17 @@ "ok_max_mean_abs": "" }, "mrsoLut": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "soil_moisture_content", + "standard_name": "mass_content_of_water_in_soil", "units": "kg m-2", - "cell_methods": "area: time: mean where landuse", + "cell_methods": "area: time: mean where sector", "cell_measures": "area: areacella", - "long_name": "Total soil moisture", - "comment": "", + "long_name": "Total Soil Moisture", + "comment": "'Water' means water in all phases. 'Content' indicates a quantity per unit area. The mass content of water in soil refers to the vertical integral from the surface down to the bottom of the soil model. For the content between specified levels in the soil, standard names including 'content_of_soil_layer' are used.", "dimensions": "longitude latitude landUse time", "out_name": "mrsoLut", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -3058,16 +2625,17 @@ "ok_max_mean_abs": "" }, "mrsol": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "moisture_content_of_soil_layer", + "standard_name": "mass_content_of_water_in_soil_layer", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Total water content of soil layer", + "long_name": "Total Water Content of Soil Layer", "comment": "in each soil layer, the mass of water in all phases, including ice. Reported as 'missing' for grid cells occupied entirely by 'sea'", "dimensions": "longitude latitude sdepth time", "out_name": "mrsol", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -3075,16 +2643,17 @@ "ok_max_mean_abs": "" }, "mrsosLut": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "moisture_content_of_soil_layer", + "standard_name": "mass_content_of_water_in_soil_layer", "units": "kg m-2", - "cell_methods": "area: time: mean where landuse", + "cell_methods": "area: time: mean where sector", "cell_measures": "area: areacella", - "long_name": "Moisture in Upper Portion of Soil Column of land use tile", + "long_name": "Moisture in Upper Portion of Soil Column of Land-Use Tile", "comment": "the mass of water in all phases in a thin surface layer; integrate over uppermost 10cm", "dimensions": "longitude latitude landUse time sdepth1", "out_name": "mrsosLut", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -3092,16 +2661,17 @@ "ok_max_mean_abs": "" }, "mrtws": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "total_water_storage", + "standard_name": "land_water_amount", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Total water storage in a grid cell", + "long_name": "Terrestrial Water Storage", "comment": "Mass of water in all phases and in all components including soil, canopy, vegetation, ice sheets, rivers and ground water.", "dimensions": "longitude latitude time", "out_name": "mrtws", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -3109,16 +2679,17 @@ "ok_max_mean_abs": "" }, "nLand": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "total_land_nitrogen", + "standard_name": "mass_content_of_nitrogen_in_vegetation_and_litter_and_soil_and_forestry_and_agricultural_products", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Total nitrogen in all terrestrial nitrogen pools", + "long_name": "Total Nitrogen in All Terrestrial Nitrogen Pools", "comment": "Report missing data over ocean grid cells. For fractional land report value averaged over the land fraction.", "dimensions": "longitude latitude time", "out_name": "nLand", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -3126,16 +2697,17 @@ "ok_max_mean_abs": "" }, "nLeaf": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "leaf_nitrogen_content", + "standard_name": "leaf_mass_content_of_nitrogen", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", "long_name": "Nitrogen Mass in Leaves", - "comment": "", + "comment": "'Content' indicates a quantity per unit area.", "dimensions": "longitude latitude time", "out_name": "nLeaf", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -3143,8 +2715,9 @@ "ok_max_mean_abs": "" }, "nLitter": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "litter_nitrogen_content", + "standard_name": "litter_mass_content_of_nitrogen", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", @@ -3152,7 +2725,7 @@ "comment": "Report missing data over ocean grid cells. For fractional land report value averaged over the land fraction.", "dimensions": "longitude latitude time", "out_name": "nLitter", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -3160,16 +2733,17 @@ "ok_max_mean_abs": "" }, "nLitterCwd": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "litter_wood_debris_nitrogen_content", + "standard_name": "wood_debris_mass_content_of_nitrogen", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", "long_name": "Nitrogen Mass in Coarse Woody Debris", - "comment": "", + "comment": "'Content' indicates a quantity per unit area. 'Wood debris' means dead organic matter composed of coarse wood. It is distinct from fine litter. The precise distinction between 'fine' and 'coarse' is model dependent. The sum of the quantities with standard names wood_debris_mass_content_of_nitrogen, surface_litter_mass_content_of_nitrogen and subsurface_litter_mass_content_of_nitrogen is the total nitrogen mass content of dead plant material.", "dimensions": "longitude latitude time", "out_name": "nLitterCwd", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -3177,16 +2751,17 @@ "ok_max_mean_abs": "" }, "nLitterSubSurf": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "subsurface_litter_nitrogen_content", + "standard_name": "subsurface_litter_mass_content_of_nitrogen", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Nitrogen Mass in below ground litter (non CWD)", - "comment": "", + "long_name": "Nitrogen Mass in Below-Ground Litter (non CWD)", + "comment": "'Content' indicates a quantity per unit area. 'Litter' is dead plant material in or above the soil. It is distinct from coarse wood debris. The precise distinction between 'fine' and 'coarse' is model dependent. 'Subsurface litter' means the part of the litter mixed within the soil below the surface. The sum of the quantities with standard names wood_debris_mass_content_of_nitrogen, surface_litter_mass_content_of_nitrogen and subsurface_litter_mass_content_of_nitrogen is the total nitrogen mass content of dead plant material.", "dimensions": "longitude latitude time", "out_name": "nLitterSubSurf", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -3194,16 +2769,17 @@ "ok_max_mean_abs": "" }, "nLitterSurf": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "surface_litter_nitrogen_content", + "standard_name": "surface_litter_mass_content_of_nitrogen", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Nitrogen Mass in above ground litter (non CWD)", - "comment": "", + "long_name": "Nitrogen Mass in Above-Ground Litter (non CWD)", + "comment": "'Content' indicates a quantity per unit area. 'Litter' is dead plant material in or above the soil. It is distinct from coarse wood debris. The precise distinction between 'fine' and 'coarse' is model dependent. 'Surface litter' means the part of the litter resting above the soil surface. The sum of the quantities with standard names wood_debris_mass_content_of_nitrogen, surface_litter_mass_content_of_nitrogen and subsurface_litter_mass_content_of_nitrogen is the total nitrogen mass content of dead plant material.", "dimensions": "longitude latitude time", "out_name": "nLitterSurf", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -3211,16 +2787,17 @@ "ok_max_mean_abs": "" }, "nMineral": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "mineral_soil_nitrogen_content", + "standard_name": "soil_mass_content_of_inorganic_nitrogen_expressed_as_nitrogen", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Mineral nitrogen in the soil", + "long_name": "Mineral Nitrogen in the Soil", "comment": "SUM of ammonium, nitrite, nitrate, etc over all soil layers", "dimensions": "longitude latitude time", "out_name": "nMineral", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -3228,16 +2805,17 @@ "ok_max_mean_abs": "" }, "nMineralNH4": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "mineral_nh4_soil_nitrogen_content", + "standard_name": "soil_mass_content_of_inorganic_ammonium_expressed_as_nitrogen", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Mineral ammonium in the soil", + "long_name": "Mineral Ammonium in the Soil", "comment": "SUM of ammonium over all soil layers", "dimensions": "longitude latitude time", "out_name": "nMineralNH4", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -3245,16 +2823,17 @@ "ok_max_mean_abs": "" }, "nMineralNO3": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "mineral_no3_soil_nitrogen_content", + "standard_name": "soil_mass_content_of_inorganic_nitrate_expressed_as_nitrogen", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Mineral nitrate in the soil", + "long_name": "Mineral Nitrate in the Soil", "comment": "SUM of nitrate over all soil layers", "dimensions": "longitude latitude time", "out_name": "nMineralNO3", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -3262,16 +2841,17 @@ "ok_max_mean_abs": "" }, "nOther": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "other_vegegtation_components_nitrogen_content", + "standard_name": "miscellaneous_living_matter_mass_content_of_nitrogen", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Nitrogen mass in vegetation components other than leaves, stem and root", + "long_name": "Nitrogen Mass in Vegetation Components Other than Leaves, Stem and Root", "comment": "E.g. fruits, seeds, etc.", "dimensions": "longitude latitude time", "out_name": "nOther", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -3279,16 +2859,17 @@ "ok_max_mean_abs": "" }, "nProduct": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "nitrogen_content_of_products_of_anthropogenic_land_use_change", + "standard_name": "nitrogen_mass_content_of_forestry_and_agricultural_products", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Nitrogen Mass in Products of Land Use Change", + "long_name": "Nitrogen Mass in Products of Land-Use Change", "comment": "Report missing data over ocean grid cells. For fractional land report value averaged over the land fraction.", "dimensions": "longitude latitude time", "out_name": "nProduct", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -3296,8 +2877,9 @@ "ok_max_mean_abs": "" }, "nRoot": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "root_nitrogen_content", + "standard_name": "root_mass_content_of_nitrogen", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", @@ -3305,7 +2887,7 @@ "comment": "including fine and coarse roots.", "dimensions": "longitude latitude time", "out_name": "nRoot", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -3313,8 +2895,9 @@ "ok_max_mean_abs": "" }, "nSoil": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "soil_nitrogen_content", + "standard_name": "soil_mass_content_of_nitrogen", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", @@ -3322,7 +2905,7 @@ "comment": "Report missing data over ocean grid cells. For fractional land report value averaged over the land fraction.", "dimensions": "longitude latitude time", "out_name": "nSoil", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -3330,8 +2913,9 @@ "ok_max_mean_abs": "" }, "nStem": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "stem_nitrogen_content", + "standard_name": "stem_mass_content_of_nitrogen", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", @@ -3339,7 +2923,7 @@ "comment": "including sapwood and hardwood.", "dimensions": "longitude latitude time", "out_name": "nStem", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -3347,8 +2931,9 @@ "ok_max_mean_abs": "" }, "nVeg": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "vegetation_nitrogen_content", + "standard_name": "vegetation_mass_content_of_nitrogen", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", @@ -3356,7 +2941,7 @@ "comment": "Report missing data over ocean grid cells. For fractional land report value averaged over the land fraction.", "dimensions": "longitude latitude time", "out_name": "nVeg", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -3364,30 +2949,32 @@ "ok_max_mean_abs": "" }, "necbLut": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "surface_net_downward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_all_land_processes", "units": "kg m-2 s-1", - "cell_methods": "area: time: mean where landuse", + "cell_methods": "area: time: mean where sector", "cell_measures": "area: areacella", - "long_name": "net rate of C accumulation (or loss) on land use tile", + "long_name": "Net Rate of Carbon Accumulation (or Loss) on Land-Use Tile", "comment": "Computed as npp minus heterotrophic respiration minus fire minus C leaching minus harvesting/clearing. Positive rate is into the land, negative rate is from the land. Do not include fluxes from anthropogenic product pools to atmosphere", "dimensions": "longitude latitude landUse time", "out_name": "necbLut", - "type": "", - "positive": "", + "type": "real", + "positive": "down", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "nep": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "surface_net_downward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_all_land_processes_excluding_anthropogenic_land_use_change", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Net Carbon Mass Flux out of Atmophere due to Net Ecosystem Productivity on Land.", - "comment": "Natural flux of CO2 (expressed as a mass flux of carbon) from the atmosphere to the land calculated as the difference between uptake associated will photosynthesis and the release of CO2 from the sum of plant and soil respiration and fire. Positive flux is into the land. emissions from natural fires and human ignition fires as calculated by the fire module of the dynamic vegetation model, but excluding any CO2 flux from fire included in fLuc (CO2 Flux to Atmosphere from Land Use Change).", + "long_name": "Net Carbon Mass Flux out of Atmosphere Due to Net Ecosystem Productivity on Land", + "comment": "Natural flux of CO2 (expressed as a mass flux of carbon) from the atmosphere to the land calculated as the difference between uptake associated will photosynthesis and the release of CO2 from the sum of plant and soil respiration and fire. Positive flux is into the land. Emissions from natural fires and human ignition fires as calculated by the fire module of the dynamic vegetation model, but excluding any CO2 flux from fire included in fLuc (CO2 Flux to Atmosphere from Land Use Change).", "dimensions": "longitude latitude time", "out_name": "nep", "type": "real", @@ -3398,67 +2985,71 @@ "ok_max_mean_abs": "" }, "netAtmosLandC13Flux": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "net_atmos_to_land_C13_flux", + "standard_name": "surface_net_downward_mass_flux_of_carbon_dioxide_expressed_as_13C_due_to_all_land_processes", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Net Mass Flux of 13C between atmosphere and land (positive into land) as a result of all processes.", - "comment": "", + "long_name": "Net Mass Flux of 13C Between Atmosphere and Land (Positive into Land) as a Result of All Processes", + "comment": "Flux of carbon 31as carbon dioxide into the land. This flux should be reproducible by differencing the sum of all carbon pools (cVeg, cLitter, cSoil, and cProducts or equivalently cLand) from one time step to the next, except in the case of lateral transfer of carbon due to harvest, riverine transport of dissolved organic and/or inorganic carbon, or any other process (in which case the lateral_carbon_transfer_over_land term, see below, will be zero data).-", "dimensions": "longitude latitude time", "out_name": "netAtmosLandC13Flux", - "type": "", - "positive": "", + "type": "real", + "positive": "down", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "netAtmosLandC14Flux": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "net_atmos_to_land_C14_flux", + "standard_name": "surface_net_downward_mass_flux_of_carbon_dioxide_expressed_as_14C_due_to_all_land_processes", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Net Mass Flux of 14C between atmosphere and land (positive into land) as a result of all processes.", - "comment": "", + "long_name": "Net Mass Flux of 14C Between Atmosphere and Land (Positive into Land) as a Result of All Processes", + "comment": "Flux of carbon-14 as carbon dioxide into the land. This flux should be reproducible by differencing the sum of all carbon pools (cVeg, cLitter, cSoil, and cProducts or equivalently cLand) from one time step to the next, except in the case of lateral transfer of carbon due to harvest, riverine transport of dissolved organic and/or inorganic carbon, or any other process (in which case the lateral_carbon_transfer_over_land term, see below, will be zero data).", "dimensions": "longitude latitude time", "out_name": "netAtmosLandC14Flux", - "type": "", - "positive": "", + "type": "real", + "positive": "down", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "netAtmosLandCO2Flux": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "surface_net_downward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_all_land_processes", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Net flux of CO2 between atmosphere and land (positive into land) as a result of all processes.", - "comment": "This flux should be reproducible by differencing the sum of all carbon pools (cVeg, cLitter, cSoil, and cProducts or equivalently cLand) from one time step to the next, except in the case of lateral transfer of carbon due to harvest, riverine transport of dissolved organic and/or inorganic carbon, or any other process (in which case the lateral_carbon_transfer_over_land term, see below, will be zero data).", + "long_name": "Net Flux of CO2 Between Atmosphere and Land (Positive into Land) as a Result of All Processes", + "comment": "Flux of carbon as carbon dioxide into the land. This flux should be reproducible by differencing the sum of all carbon pools (cVeg, cLitter, cSoil, and cProducts or equivalently cLand) from one time step to the next, except in the case of lateral transfer of carbon due to harvest, riverine transport of dissolved organic and/or inorganic carbon, or any other process (in which case the lateral_carbon_transfer_over_land term, see below, will be zero data).", "dimensions": "longitude latitude time", "out_name": "netAtmosLandCO2Flux", - "type": "", - "positive": "", + "type": "real", + "positive": "down", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "nppGrass": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "net_primary_productivity_of_biomass_expressed_as_carbon", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where natural_grasses (comment: mask=grassFrac)", "cell_measures": "area: areacella", - "long_name": "net primary production on grass tiles", - "comment": "Total NPP of grass in the gridcell", + "long_name": "Net Primary Production on Grass Tiles", + "comment": "Total NPP of grass in the grid cell", "dimensions": "longitude latitude time", "out_name": "nppGrass", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -3466,16 +3057,17 @@ "ok_max_mean_abs": "" }, "nppLut": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "net_primary_productivity_of_biomass_expressed_as_carbon", "units": "kg m-2 s-1", - "cell_methods": "area: time: mean where landuse", + "cell_methods": "area: time: mean where sector", "cell_measures": "area: areacella", - "long_name": "net primary productivity on land use tile", - "comment": "", + "long_name": "Net Primary Productivity on Land-Use Tile", + "comment": "'Production of carbon' means the production of biomass expressed as the mass of carbon which it contains. Net primary production is the excess of gross primary production (rate of synthesis of biomass from inorganic precursors) by autotrophs ('producers'), for example, photosynthesis in plants or phytoplankton, over the rate at which the autotrophs themselves respire some of this biomass. 'Productivity' means production per unit area. The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", "dimensions": "longitude latitude landUse time", "out_name": "nppLut", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -3483,16 +3075,17 @@ "ok_max_mean_abs": "" }, "nppOther": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "net_primary_production_allocated_to_other", + "standard_name": "net_primary_productivity_of_biomass_expressed_as_carbon_accumulated_in_miscellaneous_living_matter", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "net primary production allcoated to other pools (not leaves stem or roots)", + "long_name": "Net Primary Production Allocated to Other Pools (not Leaves Stem or Roots)", "comment": "added for completeness with npp_root", "dimensions": "longitude latitude time", "out_name": "nppOther", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -3500,16 +3093,17 @@ "ok_max_mean_abs": "" }, "nppShrub": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "net_primary_productivity_of_biomass_expressed_as_carbon", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where shrubs (comment: mask=shrubFrac)", "cell_measures": "area: areacella", - "long_name": "net primary production on Shrub tiles", - "comment": "Total NPP of shrubs in the gridcell", + "long_name": "Net Primary Production on Shrub Tiles", + "comment": "Total NPP of shrubs in the grid cell", "dimensions": "longitude latitude time", "out_name": "nppShrub", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -3517,16 +3111,17 @@ "ok_max_mean_abs": "" }, "nppStem": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "net_primary_production_allocated_to_stem", + "standard_name": "net_primary_productivity_of_biomass_expressed_as_carbon_accumulated_in_stems", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "net primary production allcoated to stem", + "long_name": "Net Primary Production Allocated to Stem", "comment": "added for completeness with npp_root", "dimensions": "longitude latitude time", "out_name": "nppStem", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -3534,16 +3129,17 @@ "ok_max_mean_abs": "" }, "nppTree": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "net_primary_productivity_of_biomass_expressed_as_carbon", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where trees (comment: mask=treeFrac)", "cell_measures": "area: areacella", - "long_name": "net primary production on tree tiles", - "comment": "Total NPP of trees in the gridcell", + "long_name": "Net Primary Production on Tree Tiles", + "comment": "Total NPP of trees in the grid cell", "dimensions": "longitude latitude time", "out_name": "nppTree", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -3551,32 +3147,16 @@ "ok_max_mean_abs": "" }, "nwdFracLut": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "missing", - "units": "1", + "standard_name": "area_fraction", + "units": "%", "cell_methods": "area: mean where land over all_area_types time: mean", "cell_measures": "area: areacella", - "long_name": "fraction of land use tile tile that is non-woody vegetation ( e.g. herbaceous crops)", - "comment": "", + "long_name": "Non-Woody Vegetation Percentage Cover", + "comment": "Percentage of land use tile tile that is non-woody vegetation ( e.g. herbaceous crops)", "dimensions": "longitude latitude landUse time typenwd", "out_name": "nwdFracLut", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "o2sat": { - "modeling_realm": "ocnBgChem", - "standard_name": "mole_concentration_of_dissolved_molecular_oxygen_in_sea_water_at_saturation", - "units": "mol m-3", - "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello volume: volcello", - "long_name": "Dissolved Oxygen Concentration at Saturation", - "comment": "", - "dimensions": "longitude latitude olevel time", - "out_name": "o2sat", "type": "real", "positive": "", "valid_min": "", @@ -3585,12 +3165,13 @@ "ok_max_mean_abs": "" }, "ocontempdiff": { + "frequency": "mon", "modeling_realm": "ocean", - "standard_name": "tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_dianeutral_mixing", + "standard_name": "tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_eddy_dianeutral_mixing", "units": "W m-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "tendency of sea water conservative temperature expressed as heat content due to parameterized dianeutral mixing", + "long_name": "Tendency of Sea Water Conservative Temperature Expressed as Heat Content Due to Parameterized Dianeutral Mixing", "comment": "Tendency of heat content for a grid cell from parameterized dianeutral mixing. Reported only for models that use conservative temperature as prognostic field.", "dimensions": "longitude latitude olevel time", "out_name": "ocontempdiff", @@ -3602,12 +3183,13 @@ "ok_max_mean_abs": "" }, "ocontempmint": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "integral_wrt_depth_of_product_of_sea_water_density_and_conservative_temperature", "units": "degC kg m-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "integral wrt depth of product of sea water density and conservative temperature", + "long_name": "Depth Integral of Product of Sea Water Density and Conservative Temperature", "comment": "Full column sum of density*cell thickness*conservative temperature. If the model is Boussinesq, then use Boussinesq reference density for the density factor.", "dimensions": "longitude latitude time", "out_name": "ocontempmint", @@ -3619,12 +3201,13 @@ "ok_max_mean_abs": "" }, "ocontemppadvect": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_eddy_advection", "units": "W m-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "tendency of sea water conservative temperature expressed as heat content due to parameterized eddy advection", + "long_name": "Tendency of Sea Water Conservative Temperature Expressed as Heat Content Due to Parameterized Eddy Advection", "comment": "Tendency of heat content for a grid cell from parameterized eddy advection (any form of eddy advection). Reported only for models that use conservative temperature as prognostic field.", "dimensions": "longitude latitude olevel time", "out_name": "ocontemppadvect", @@ -3636,12 +3219,13 @@ "ok_max_mean_abs": "" }, "ocontemppmdiff": { + "frequency": "mon", "modeling_realm": "ocean", - "standard_name": "tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_mesoscale_diffusion", + "standard_name": "tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_mesoscale_eddy_diffusion", "units": "W m-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "tendency of sea water conservative temperature expressed as heat content due to parameterized mesoscale diffusion", + "long_name": "Tendency of Sea Water Conservative Temperature Expressed as Heat Content Due to Parameterized Mesoscale Diffusion", "comment": "Tendency of heat content for a grid cell from parameterized mesoscale eddy diffusion. Reported only for models that use conservative temperature as prognostic field.", "dimensions": "longitude latitude olevel time", "out_name": "ocontemppmdiff", @@ -3653,12 +3237,13 @@ "ok_max_mean_abs": "" }, "ocontemppsmadvect": { + "frequency": "mon", "modeling_realm": "ocean", - "standard_name": "tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_submesoscale_advection", + "standard_name": "tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_submesoscale_eddy_advection", "units": "W m-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "tendency of sea water conservative temperature expressed as heat content due to parameterized submesoscale advection", + "long_name": "Tendency of Sea Water Conservative Temperature Expressed as Heat Content Due to Parameterized Submesoscale Advection", "comment": "Tendency of heat content for a grid cell from parameterized submesoscale eddy advection. Reported only for models that use conservative temperature as prognostic field.", "dimensions": "longitude latitude olevel time", "out_name": "ocontemppsmadvect", @@ -3670,13 +3255,14 @@ "ok_max_mean_abs": "" }, "ocontemprmadvect": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_residual_mean_advection", "units": "W m-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "tendency of sea water conservative temperature expressed as heat content due to residual mean (sum of Eulerian + parameterized) advection", - "comment": "", + "long_name": "Tendency of Sea Water Conservative Temperature Expressed as Heat Content Due to Residual Mean Advection", + "comment": "Conservative Temperature is defined as part of the Thermodynamic Equation of Seawater 2010 (TEOS-10) which was adopted in 2010 by the International Oceanographic Commission (IOC). The phrase 'residual mean advection' refers to the sum of the model's resolved advective transport plus any parameterized advective transport. Parameterized advective transport includes processes such as parameterized mesoscale and submesoscale transport, as well as any other advectively parameterized transport. When the parameterized advective transport is represented in the model as a skew-diffusion rather than an advection, then the parameterized skew diffusion should be included in this diagnostic, since the convergence of skew-fluxes are identical (in the continuous formulation) to the convergence of advective fluxes.", "dimensions": "longitude latitude olevel time", "out_name": "ocontemprmadvect", "type": "real", @@ -3687,12 +3273,13 @@ "ok_max_mean_abs": "" }, "ocontemptend": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "tendency_of_sea_water_conservative_temperature_expressed_as_heat_content", "units": "W m-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "tendency of sea water conservative temperature expressed as heat content", + "long_name": "Tendency of Sea Water Conservative Temperature Expressed as Heat Content", "comment": "Tendency of heat content for a grid cell from all processes. Reported only for models that use conservative temperature as prognostic field.", "dimensions": "longitude latitude olevel time", "out_name": "ocontemptend", @@ -3704,16 +3291,17 @@ "ok_max_mean_abs": "" }, "od443dust": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "atmosphere_optical_thickness_due_to_dust_ambient_aerosol_particles", - "units": "1.0", + "units": "1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Optical thickness at 443 nm Dust", - "comment": "Balkanski - LSCE", + "long_name": "Optical Thickness at 443nm Dust", + "comment": "Total aerosol AOD due to dust aerosol at a wavelength of 443 nanometres.", "dimensions": "longitude latitude time", "out_name": "od443dust", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -3721,33 +3309,17 @@ "ok_max_mean_abs": "" }, "od550aerso": { + "frequency": "mon", "modeling_realm": "atmos", - "standard_name": "missing", - "units": "1.0", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "Stratospheric Optical depth at 550 nm (all aerosols) 2D-field (here we limit the computation of OD to the stratosphere only)", - "comment": "Balkanski - LSCE", - "dimensions": "longitude latitude time", - "out_name": "od550aerso", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "od550aerstrat": { - "modeling_realm": "atmos", - "standard_name": "strat_aerosol_optical_depth", - "units": "1.0", + "standard_name": "stratosphere_optical_thickness_due_to_ambient_aerosol_particles", + "units": "1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Stratospheric Aerosol Optical Depth at 550nm", + "long_name": "Stratospheric Optical Depth at 550nm (All Aerosols) 2D-Field (Stratosphere Only)", "comment": "From tropopause to stratopause as defined by the model", - "dimensions": "longitude latitude time", - "out_name": "od550aerstrat", - "type": "", + "dimensions": "longitude latitude time lambda550nm", + "out_name": "od550aerso", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -3755,16 +3327,17 @@ "ok_max_mean_abs": "" }, "od550so4so": { + "frequency": "mon", "modeling_realm": "atmos", - "standard_name": "missing", - "units": "1.0", + "standard_name": "stratosphere_optical_thickness_due_to_sulfate_ambient_aerosol_particles", + "units": "1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Stratospheric Optical depth at 550 nm (sulphate only) 2D-field (here we limit the computation of OD to the stratosphere only)", - "comment": "Balkanski - LSCE", - "dimensions": "longitude latitude time", + "long_name": "Stratospheric Optical Depth at 550nm (Sulphate Only) 2D-Field (Stratosphere Only)", + "comment": "Stratospheric aerosol AOD due to sulfate aerosol at a wavelength of 550 nanometres.", + "dimensions": "longitude latitude time lambda550nm", "out_name": "od550so4so", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -3772,16 +3345,17 @@ "ok_max_mean_abs": "" }, "od865dust": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "atmosphere_optical_thickness_due_to_dust_ambient_aerosol_particles", - "units": "1.0", + "units": "1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Optical thickness at 865 nm Dust", - "comment": "Balkanski - LSCE", + "long_name": "Dust Optical Depth at 865nm", + "comment": "Total aerosol AOD due to dust aerosol at a wavelength of 865 nanometres.", "dimensions": "longitude latitude time", "out_name": "od865dust", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -3789,12 +3363,13 @@ "ok_max_mean_abs": "" }, "opottempdiff": { + "frequency": "mon", "modeling_realm": "ocean", - "standard_name": "tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_dianeutral_mixing", + "standard_name": "tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_eddy_dianeutral_mixing", "units": "W m-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "tendency of sea water potential temperature expressed as heat content due to parameterized dianeutral mixing", + "long_name": "Tendency of Sea Water Potential Temperature Expressed as Heat Content Due to Parameterized Dianeutral Mixing", "comment": "Tendency of heat content for a grid cell from parameterized dianeutral mixing. Reported only for models that use potential temperature as prognostic field.", "dimensions": "longitude latitude olevel time", "out_name": "opottempdiff", @@ -3806,13 +3381,14 @@ "ok_max_mean_abs": "" }, "opottempmint": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "integral_wrt_depth_of_product_of_sea_water_density_and_potential_temperature", "units": "degC kg m-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "integral wrt depth of product of sea water density and potential temperature", - "comment": "", + "long_name": "Integral with Respect to Depth of Product of Sea Water Density and Potential Temperature", + "comment": "Integral over the full ocean depth of the product of sea water density and potential temperature.", "dimensions": "longitude latitude time", "out_name": "opottempmint", "type": "real", @@ -3823,12 +3399,13 @@ "ok_max_mean_abs": "" }, "opottemppadvect": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_eddy_advection", "units": "W m-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "tendency of sea water potential temperature expressed as heat content due to parameterized eddy advection", + "long_name": "Tendency of Sea Water Potential Temperature Expressed as Heat Content Due to Parameterized Eddy Advection", "comment": "Tendency of heat content for a grid cell from parameterized eddy advection (any form of eddy advection). Reported only for models that use potential temperature as prognostic field.", "dimensions": "longitude latitude olevel time", "out_name": "opottemppadvect", @@ -3840,12 +3417,13 @@ "ok_max_mean_abs": "" }, "opottemppmdiff": { + "frequency": "mon", "modeling_realm": "ocean", - "standard_name": "tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_mesoscale_diffusion", + "standard_name": "tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_mesoscale_eddy_diffusion", "units": "W m-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "tendency of sea water potential temperature expressed as heat content due to parameterized mesoscale diffusion", + "long_name": "Tendency of Sea Water Potential Temperature Expressed as Heat Content Due to Parameterized Mesoscale Diffusion", "comment": "Tendency of heat content for a grid cell from parameterized mesoscale eddy diffusion. Reported only for models that use potential temperature as prognostic field.", "dimensions": "longitude latitude olevel time", "out_name": "opottemppmdiff", @@ -3857,12 +3435,13 @@ "ok_max_mean_abs": "" }, "opottemppsmadvect": { + "frequency": "mon", "modeling_realm": "ocean", - "standard_name": "tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_submesoscale_advection", + "standard_name": "tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_submesoscale_eddy_advection", "units": "W m-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "tendency of sea water potential temperature expressed as heat content due to parameterized submesoscale advection", + "long_name": "Tendency of Sea Water Potential Temperature Expressed as Heat Content Due to Parameterized Submesoscale Advection", "comment": "Tendency of heat content for a grid cell from parameterized submesoscale eddy advection. Reported only for models that use potential temperature as prognostic field.", "dimensions": "longitude latitude olevel time", "out_name": "opottemppsmadvect", @@ -3874,13 +3453,14 @@ "ok_max_mean_abs": "" }, "opottemprmadvect": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_residual_mean_advection", "units": "W m-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "tendency of sea water potential temperature expressed as heat content due to residual mean advection", - "comment": "", + "long_name": "Tendency of Sea Water Potential Temperature Expressed as Heat Content Due to Residual Mean Advection", + "comment": "The phrase 'residual mean advection' refers to the sum of the model's resolved advective transport plus any parameterized advective transport. Parameterized advective transport includes processes such as parameterized mesoscale and submesoscale transport, as well as any other advectively parameterized transport. When the parameterized advective transport is represented in the model as a skew-diffusion rather than an advection, then the parameterized skew diffusion should be included in this diagnostic, since the convergence of skew-fluxes are identical (in the continuous formulation) to the convergence of advective fluxes.", "dimensions": "longitude latitude olevel time", "out_name": "opottemprmadvect", "type": "real", @@ -3891,12 +3471,13 @@ "ok_max_mean_abs": "" }, "opottemptend": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "tendency_of_sea_water_potential_temperature_expressed_as_heat_content", "units": "W m-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "tendency of sea water potential temperature expressed as heat content", + "long_name": "Tendency of Sea Water Potential Temperature Expressed as Heat Content", "comment": "Tendency of heat content for a grid cell from all processes. Reported only for models that use potential temperature as prognostic field.", "dimensions": "longitude latitude olevel time", "out_name": "opottemptend", @@ -3908,6 +3489,7 @@ "ok_max_mean_abs": "" }, "orog": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "surface_altitude", "units": "m", @@ -3925,12 +3507,13 @@ "ok_max_mean_abs": "" }, "osaltdiff": { + "frequency": "mon", "modeling_realm": "ocean", - "standard_name": "tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_dianeutral_mixing", + "standard_name": "tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_eddy_dianeutral_mixing", "units": "kg m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "tendency of sea water salinity expressed as salt content due to parameterized dianeutral mixing", + "long_name": "Tendency of Sea Water Salinity Expressed as Salt Content Due to Parameterized Dianeutral Mixing", "comment": "Tendency of salt content for a grid cell from parameterized dianeutral mixing.", "dimensions": "longitude latitude olevel time", "out_name": "osaltdiff", @@ -3942,12 +3525,13 @@ "ok_max_mean_abs": "" }, "osaltpadvect": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_eddy_advection", "units": "kg m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "tendency of sea water salinity expressed as salt content due to parameterized eddy advection", + "long_name": "Tendency of Sea Water Salinity Expressed as Salt Content Due to Parameterized Eddy Advection", "comment": "Tendency of salt content for a grid cell from parameterized eddy advection (any form of eddy advection).", "dimensions": "longitude latitude olevel time", "out_name": "osaltpadvect", @@ -3959,12 +3543,13 @@ "ok_max_mean_abs": "" }, "osaltpmdiff": { + "frequency": "mon", "modeling_realm": "ocean", - "standard_name": "tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_mesoscale_diffusion", + "standard_name": "tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_mesoscale_eddy_diffusion", "units": "kg m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "tendency of sea water salinity expressed as salt content due to parameterized mesoscale diffusion", + "long_name": "Tendency of Sea Water Salinity Expressed as Salt Content Due to Parameterized Mesoscale Diffusion", "comment": "Tendency of salt content for a grid cell from parameterized mesoscale eddy diffusion.", "dimensions": "longitude latitude olevel time", "out_name": "osaltpmdiff", @@ -3976,12 +3561,13 @@ "ok_max_mean_abs": "" }, "osaltpsmadvect": { + "frequency": "mon", "modeling_realm": "ocean", - "standard_name": "tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_submesoscale_advection", + "standard_name": "tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_submesoscale_eddy_advection", "units": "kg m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "tendency of sea water salinity expressed as salt content due to parameterized submesoscale advection", + "long_name": "Tendency of Sea Water Salinity Expressed as Salt Content Due to Parameterized Submesoscale Advection", "comment": "Tendency of salt content for a grid cell from parameterized submesoscale eddy advection.", "dimensions": "longitude latitude olevel time", "out_name": "osaltpsmadvect", @@ -3993,13 +3579,14 @@ "ok_max_mean_abs": "" }, "osaltrmadvect": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_residual_mean_advection", "units": "kg m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "tendency of sea water salinity expressed as salt content due to residual mean advection", - "comment": "", + "long_name": "Tendency of Sea Water Salinity Expressed as Salt Content Due to Residual Mean Advection", + "comment": "The phrase 'residual mean advection' refers to the sum of the model's resolved advective transport plus any parameterized advective transport. Parameterized advective transport includes processes such as parameterized mesoscale and submesoscale transport, as well as any other advectively parameterized transport. When the parameterized advective transport is represented in the model as a skew-diffusion rather than an advection, then the parameterized skew diffusion should be included in this diagnostic, since the convergence of skew-fluxes are identical (in the continuous formulation) to the convergence of advective fluxes.", "dimensions": "longitude latitude olevel time", "out_name": "osaltrmadvect", "type": "real", @@ -4010,12 +3597,13 @@ "ok_max_mean_abs": "" }, "osalttend": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "tendency_of_sea_water_salinity_expressed_as_salt_content", "units": "kg m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "tendency of sea water salinity expressed as salt content", + "long_name": "Tendency of Sea Water Salinity Expressed as Salt Content", "comment": "Tendency of salt content for a grid cell from all processes.", "dimensions": "longitude latitude olevel time", "out_name": "osalttend", @@ -4027,16 +3615,17 @@ "ok_max_mean_abs": "" }, "pabigthetao": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "sea_water_added_conservative_temperature", "units": "degC", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", "long_name": "Sea Water Added Conservative Temperature", - "comment": "", + "comment": "A passive tracer in an ocean model whose surface flux does not come from the atmosphere but is imposed externally upon the simulated climate system. The surface flux is expressed as a heat flux and converted to a passive tracer increment as if it were a heat flux being added to conservative temperature. The passive tracer is transported within the ocean as if it were conservative temperature. The passive tracer is zero in the control climate of the model. ", "dimensions": "longitude latitude olevel time", "out_name": "pabigthetao", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -4044,9 +3633,10 @@ "ok_max_mean_abs": "" }, "parasolRefl": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "toa_bidirectional_reflectance", - "units": "1.0", + "units": "1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacella", "long_name": "PARASOL Reflectance", @@ -4061,6 +3651,7 @@ "ok_max_mean_abs": "" }, "pastureFracC3": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "area_fraction", "units": "%", @@ -4068,9 +3659,9 @@ "cell_measures": "area: areacella", "long_name": "C3 Pasture Area Percentage", "comment": "Percentage of entire grid cell covered by C3 pasture", - "dimensions": "longitude latitude time typec3pft typepasture", + "dimensions": "longitude latitude time typec3pastures", "out_name": "pastureFracC3", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -4078,6 +3669,7 @@ "ok_max_mean_abs": "" }, "pastureFracC4": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "area_fraction", "units": "%", @@ -4085,9 +3677,9 @@ "cell_measures": "area: areacella", "long_name": "C4 Pasture Area Percentage", "comment": "Percentage of entire grid cell covered by C4 pasture", - "dimensions": "longitude latitude time typec4pft typepasture", + "dimensions": "longitude latitude time typec4pastures", "out_name": "pastureFracC4", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -4095,16 +3687,17 @@ "ok_max_mean_abs": "" }, "pathetao": { + "frequency": "mon", "modeling_realm": "ocean", - "standard_name": "sea_water_additional_potential_temperature", + "standard_name": "sea_water_added_potential_temperature", "units": "degC", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "", - "comment": "", + "long_name": "Sea Water Additional Potential Temperature", + "comment": "The quantity with standard name sea_water_added_potential_temperature is a passive tracer in an ocean model whose surface flux does not come from the atmosphere but is imposed externally upon the simulated climate system. The surface flux is expressed as a heat flux and converted to a passive tracer increment as if it were a heat flux being added to potential temperature. The passive tracer is transported within the ocean as if it were potential temperature. The passive tracer is zero in the control climate of the model. The passive tracer records added heat, as described for the CMIP6 FAFMIP experiment (doi:10.5194/gmd-9-3993-2016), following earlier ideas. Potential temperature is the temperature a parcel of air or sea water would have if moved adiabatically to sea level pressure.", "dimensions": "longitude latitude olevel time", "out_name": "pathetao", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -4112,7 +3705,8 @@ "ok_max_mean_abs": "" }, "ppcalc": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_calcareous_phytoplankton", "units": "mol m-3 s-1", "cell_methods": "area: mean where sea time: mean", @@ -4129,7 +3723,8 @@ "ok_max_mean_abs": "" }, "ppdiat": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_diatoms", "units": "mol m-3 s-1", "cell_methods": "area: mean where sea time: mean", @@ -4146,7 +3741,8 @@ "ok_max_mean_abs": "" }, "ppdiaz": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_diazotrophs", "units": "mol m-3 s-1", "cell_methods": "area: mean where sea time: mean", @@ -4163,7 +3759,8 @@ "ok_max_mean_abs": "" }, "ppmisc": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_miscellaneous_phytoplankton", "units": "mol m-3 s-1", "cell_methods": "area: mean where sea time: mean", @@ -4180,7 +3777,8 @@ "ok_max_mean_abs": "" }, "pppico": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_picophytoplankton", "units": "mol m-3 s-1", "cell_methods": "area: mean where sea time: mean", @@ -4196,17 +3794,72 @@ "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, + "pr17O": { + "frequency": "mon", + "modeling_realm": "atmos", + "standard_name": "precipitation_flux_containing_17O", + "units": "kg m-2 s-1", + "cell_methods": "area: time: mean", + "cell_measures": "area: areacella", + "long_name": "Precipitation Flux of Water Containing Oxygen-17 (H2 17O)", + "comment": "Precipitation mass flux of water molecules that contain the oxygen-17 isotope (H2 17O), including solid and liquid phases.", + "dimensions": "longitude latitude time", + "out_name": "pr17O", + "type": "real", + "positive": "", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, + "pr18O": { + "frequency": "mon", + "modeling_realm": "atmos", + "standard_name": "precipitation_flux_containing_18O", + "units": "kg m-2 s-1", + "cell_methods": "area: time: mean", + "cell_measures": "area: areacella", + "long_name": "Precipitation Flux of Water Containing Oxygen-18 (H2 18O)", + "comment": "Precipitation mass flux of water molecules that contain the oxygen-18 isotope (H2 18O), including solid and liquid phases.", + "dimensions": "longitude latitude time", + "out_name": "pr18O", + "type": "real", + "positive": "", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, + "pr2h": { + "frequency": "mon", + "modeling_realm": "atmos", + "standard_name": "precipitation_flux_containing_single_2H", + "units": "kg m-2 s-1", + "cell_methods": "area: time: mean", + "cell_measures": "area: areacella", + "long_name": "Precipitation Flux of Water Containing Deuterium (1H 2H O)", + "comment": "Precipitation mass flux of water molecules that contain one atom of the hydrogen-2 isotope (1H 2H O), including solid and liquid phases.", + "dimensions": "longitude latitude time", + "out_name": "pr2h", + "type": "real", + "positive": "", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, "prCrop": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "precipitation_flux", "units": "kg m-2 s-1", - "cell_methods": "area: time: mean", + "cell_methods": "area: time: mean where crops (comment: mask=cropFrac)", "cell_measures": "area: areacella", "long_name": "Precipitation over Crop Tile", "comment": "includes both liquid and solid phases", "dimensions": "longitude latitude time", "out_name": "prCrop", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -4214,16 +3867,17 @@ "ok_max_mean_abs": "" }, "prbigthetao": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "sea_water_redistributed_conservative_temperature", "units": "degC", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", "long_name": "Sea Water Redistributed Conservative Temperature", - "comment": "", + "comment": "A passive tracer in an ocean model which is subject to an externally imposed perturbative surface heat flux. The passive tracer is initialised to the conservative temperature in the control climate before the perturbation is imposed. Its surface flux is the heat flux from the atmosphere, not including the imposed perturbation, and is converted to a passive tracer increment as if it were being added to conservative temperature. The passive tracer is transported within the ocean as if it were conservative temperature. ", "dimensions": "longitude latitude olevel time", "out_name": "prbigthetao", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -4231,16 +3885,71 @@ "ok_max_mean_abs": "" }, "prhmax": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "precipitation_flux", "units": "kg m-2 s-1", "cell_methods": "area: mean time: mean within hours time: maximum over hours", "cell_measures": "area: areacella", "long_name": "Maximum Hourly Precipitation Rate", - "comment": "", + "comment": "In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions": "longitude latitude time", "out_name": "prhmax", - "type": "", + "type": "real", + "positive": "", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, + "prsn17O": { + "frequency": "mon", + "modeling_realm": "atmos", + "standard_name": "solid_precipitation_flux_containing_17O", + "units": "kg m-2 s-1", + "cell_methods": "area: time: mean", + "cell_measures": "area: areacella", + "long_name": "Precipitation Flux of Snow and Ice Containing Oxygen-17 (H2 17O)", + "comment": "Precipitation mass flux of water molecules that contain the oxygen-17 isotope (H2 17O), including solid phase only.", + "dimensions": "longitude latitude time", + "out_name": "prsn17O", + "type": "real", + "positive": "", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, + "prsn18O": { + "frequency": "mon", + "modeling_realm": "atmos", + "standard_name": "solid_precipitation_flux_containing_18O", + "units": "kg m-2 s-1", + "cell_methods": "area: time: mean", + "cell_measures": "area: areacella", + "long_name": "Precipitation Flux of Snow and Ice Containing Oxygen-18 (H2 18O)", + "comment": "Precipitation mass flux of water molecules that contain the oxygen-18 isotope (H2 18O), including solid phase only.", + "dimensions": "longitude latitude time", + "out_name": "prsn18O", + "type": "real", + "positive": "", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, + "prsn2h": { + "frequency": "mon", + "modeling_realm": "atmos", + "standard_name": "solid_precipitation_flux_containing_single_2H", + "units": "kg m-2 s-1", + "cell_methods": "area: time: mean", + "cell_measures": "area: areacella", + "long_name": "Precipitation Flux of Snow and Ice Containing Deuterium (1H 2H O)", + "comment": "Precipitation mass flux of water molecules that contain one atom of the hydrogen-2 isotope (1H 2H O), including solid phase only.", + "dimensions": "longitude latitude time", + "out_name": "prsn2h", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -4248,16 +3957,71 @@ "ok_max_mean_abs": "" }, "prthetao": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "sea_water_redistributed_potential_temperature", "units": "degC", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "", - "comment": "", + "long_name": "Sea Water Redistributed Potential Temperature", + "comment": "A passive tracer in an ocean model which is subject to an externally imposed perturbative surface heat flux. The passive tracer is initialised to the potential temperature in the control climate before the perturbation is imposed. Its surface flux is the heat flux from the atmosphere, not including the imposed perturbation, and is converted to a passive tracer increment as if it were being added to potential temperature. The passive tracer is transported within the ocean as if it were potential temperature. ", "dimensions": "longitude latitude olevel time", "out_name": "prthetao", - "type": "", + "type": "real", + "positive": "", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, + "prw17O": { + "frequency": "mon", + "modeling_realm": "atmos", + "standard_name": "mass_content_of_water_vapor_containing_17O_in_atmosphere_layer", + "units": "kg m-2", + "cell_methods": "area: time: mean", + "cell_measures": "area: areacella", + "long_name": "Mass of Water Vapor Containing Oxygen-17 (H2 17O) in Layer", + "comment": "Water vapor path for water molecules that contain oxygen-17 (H2 17O)", + "dimensions": "longitude latitude alevel time", + "out_name": "prw17O", + "type": "real", + "positive": "", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, + "prw18O": { + "frequency": "mon", + "modeling_realm": "ocean", + "standard_name": "mass_content_of_water_vapor_containing_18O_in_atmosphere_layer", + "units": "kg m-2", + "cell_methods": "area: mean where sea time: mean", + "cell_measures": "area: areacello volume: volcello", + "long_name": "Mass of Water Vapor Containing Oxygen-18 (H2 18O) in Layer", + "comment": "Water vapor path for water molecules that contain oxygen-18 (H2 18O)", + "dimensions": "longitude latitude olevel time", + "out_name": "prw18O", + "type": "real", + "positive": "", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, + "prw2H": { + "frequency": "mon", + "modeling_realm": "atmos", + "standard_name": "mass_content_of_water_vapor_containing_single_2H_in_atmosphere_layer", + "units": "kg m-2", + "cell_methods": "area: time: mean", + "cell_measures": "area: areacella", + "long_name": "Mass of Water Containing Deuterium (1H 2H O) in Layer", + "comment": "Water vapor path for water molecules that contain one atom of the hydrogen-2 isotope (1H 2H O)", + "dimensions": "longitude latitude alevel time", + "out_name": "prw2H", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -4265,6 +4029,7 @@ "ok_max_mean_abs": "" }, "ps": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "surface_air_pressure", "units": "Pa", @@ -4282,16 +4047,17 @@ "ok_max_mean_abs": "" }, "raGrass": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "plant_respiration_carbon_flux", + "standard_name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where natural_grasses (comment: mask=grassFrac)", "cell_measures": "area: areacella", - "long_name": "autotrophic respiration on grass tiles", - "comment": "Total RA of grass in the gridcell", + "long_name": "Autotrophic Respiration on Grass Tiles", + "comment": "Total RA of grass in the grid cell", "dimensions": "longitude latitude time", "out_name": "raGrass", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -4299,16 +4065,17 @@ "ok_max_mean_abs": "" }, "raLeaf": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "autotrophic_respiration_from_leaves", + "standard_name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_in_leaves", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Total respiration from leaves", + "long_name": "Total Respiration from Leaves", "comment": "added for completeness with Ra_root", "dimensions": "longitude latitude time", "out_name": "raLeaf", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -4316,16 +4083,17 @@ "ok_max_mean_abs": "" }, "raLut": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "plant_respiration_carbon_flux", + "standard_name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration", "units": "kg m-2 s-1", - "cell_methods": "area: time: mean where landuse", + "cell_methods": "area: time: mean where sector", "cell_measures": "area: areacella", - "long_name": "plant respiration on land use tile", - "comment": "", + "long_name": "Plant Respiration on Land-Use Tile", + "comment": "Carbon mass flux per unit area into atmosphere due to autotrophic respiration on land (respiration by producers) [see rh for heterotrophic production]. Calculated on land-use tiles.", "dimensions": "longitude latitude landUse time", "out_name": "raLut", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -4333,16 +4101,17 @@ "ok_max_mean_abs": "" }, "raOther": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "autotrophic_respiration", + "standard_name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_in_miscellaneous_living_matter", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Total respiration from other pools (not leaves stem or roots)", + "long_name": "Total Respiration from Other Pools (not Leaves Stem or Roots)", "comment": "added for completeness with Ra_root", "dimensions": "longitude latitude time", "out_name": "raOther", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -4350,8 +4119,9 @@ "ok_max_mean_abs": "" }, "raRoot": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "autotrophic_respiration_from_roots", + "standard_name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_in_roots", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", @@ -4359,7 +4129,7 @@ "comment": "Total autotrophic respiration from all belowground plant parts. This has benchmarking value because the sum of Rh and root respiration can be compared to observations of total soil respiration.", "dimensions": "longitude latitude time", "out_name": "raRoot", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -4367,16 +4137,17 @@ "ok_max_mean_abs": "" }, "raShrub": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "plant_respiration_carbon_flux", + "standard_name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where shrubs (comment: mask=shrubFrac)", "cell_measures": "area: areacella", - "long_name": "autotrophic respiration on Shrub tiles", - "comment": "Total RA of shrubs in the gridcell", + "long_name": "Autotrophic Respiration on Shrub Tiles", + "comment": "Total RA of shrubs in the grid cell", "dimensions": "longitude latitude time", "out_name": "raShrub", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -4384,8 +4155,9 @@ "ok_max_mean_abs": "" }, "raStem": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "autotrophic_respiration_from_stem", + "standard_name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_in_stems", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", @@ -4393,7 +4165,7 @@ "comment": "added for completeness with Ra_root", "dimensions": "longitude latitude time", "out_name": "raStem", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -4401,16 +4173,17 @@ "ok_max_mean_abs": "" }, "raTree": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "plant_respiration_carbon_flux", + "standard_name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where trees (comment: mask=treeFrac)", "cell_measures": "area: areacella", - "long_name": "autotrophic respiration on tree tiles", - "comment": "Total RA of trees in the gridcell", + "long_name": "Autotrophic Respiration on Tree Tiles", + "comment": "Total RA of trees in the grid cell", "dimensions": "longitude latitude time", "out_name": "raTree", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -4418,16 +4191,17 @@ "ok_max_mean_abs": "" }, "rac13": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "plant_respiration_c13_flux", + "standard_name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_13C_due_to_plant_respiration", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Mass Flux of 13C into Atmosphere due to Autotrophic (Plant) Respiration on Land", - "comment": "", + "long_name": "Mass Flux of 13C into Atmosphere Due to Autotrophic (Plant) Respiration on Land", + "comment": "Flux of carbon-13 into the atmosphere due to plant respiration. Plant respiration is the sum of respiration by parts of plants both above and below the soil. It is assumed that all the respired carbon dioxide is emitted to the atmosphere. ", "dimensions": "longitude latitude time", "out_name": "rac13", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -4435,16 +4209,17 @@ "ok_max_mean_abs": "" }, "rac14": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "plant_respiration_c14_flux", + "standard_name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_14C_due_to_plant_respiration", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Mass Flux of 14C into Atmosphere due to Autotrophic (Plant) Respiration on Land", - "comment": "", + "long_name": "Mass Flux of 14C into Atmosphere Due to Autotrophic (Plant) Respiration on Land", + "comment": "Flux of carbon-14 into the atmosphere due to plant respiration. Plant respiration is the sum of respiration by parts of plants both above and below the soil. It is assumed that all the respired carbon dioxide is emitted to the atmosphere. ", "dimensions": "longitude latitude time", "out_name": "rac14", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -4452,16 +4227,17 @@ "ok_max_mean_abs": "" }, "rainmxrat27": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "mass_fraction_of_rain_in_air", - "units": "1.0", + "units": "1", "cell_methods": "time: mean", "cell_measures": "area: areacella", - "long_name": "rain_mixing_ratio", + "long_name": "Mass Fraction of Rain in Air", "comment": "Rain mixing ratio", "dimensions": "longitude latitude plev27 time", "out_name": "rainmxrat", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -4469,6 +4245,7 @@ "ok_max_mean_abs": "" }, "reffclic": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "effective_radius_of_convective_cloud_ice_particle", "units": "m", @@ -4486,6 +4263,7 @@ "ok_max_mean_abs": "" }, "reffclis": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "effective_radius_of_stratiform_cloud_ice_particle", "units": "m", @@ -4503,12 +4281,13 @@ "ok_max_mean_abs": "" }, "reffclwc": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "effective_radius_of_convective_cloud_liquid_water_particle", "units": "m", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Hydrometeor Effective Radius of Convective Cloud Liquid Water", + "long_name": "Convective Cloud Liquid Droplet Effective Radius", "comment": "Droplets are liquid. The effective radius is defined as the ratio of the third moment over the second moment of the particle size distribution and the time-mean should be calculated, weighting the individual samples by the cloudy fraction of the grid cell.", "dimensions": "longitude latitude alevel time", "out_name": "reffclwc", @@ -4520,12 +4299,13 @@ "ok_max_mean_abs": "" }, "reffclws": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "effective_radius_of_stratiform_cloud_liquid_water_particle", "units": "m", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Hydrometeor Effective Radius of Stratiform Cloud Liquid Water", + "long_name": "Stratiform Cloud Liquid Droplet Effective Radius", "comment": "Droplets are liquid. The effective radius is defined as the ratio of the third moment over the second moment of the particle size distribution and the time-mean should be calculated, weighting the individual samples by the cloudy fraction of the grid cell.", "dimensions": "longitude latitude alevel time", "out_name": "reffclws", @@ -4537,16 +4317,17 @@ "ok_max_mean_abs": "" }, "rhGrass": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "heterotrophic_respiration_carbon_flux", + "standard_name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_heterotrophic_respiration", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where natural_grasses (comment: mask=grassFrac)", "cell_measures": "area: areacella", - "long_name": "heterotrophic respiration on grass tiles", - "comment": "Total RH of grass in the gridcell", + "long_name": "Heterotrophic Respiration on Grass Tiles", + "comment": "Total RH of grass in the grid cell", "dimensions": "longitude latitude time", "out_name": "rhGrass", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -4554,16 +4335,17 @@ "ok_max_mean_abs": "" }, "rhLitter": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "heterotrophic_respiration_carbon_flux_from_litter", + "standard_name": "surface_upward_mass_flux_of_carbon_due_to_heterotrophic_respiration_in_litter", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Carbon Mass Flux into Atmosphere due to Heterotrophic Respiration from Litter on Land", + "long_name": "Carbon Mass Flux into Atmosphere Due to Heterotrophic Respiration from Litter on Land", "comment": "Needed to calculate litter bulk turnover time. Includes respiration from CWD as well.", "dimensions": "longitude latitude time", "out_name": "rhLitter", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -4571,16 +4353,17 @@ "ok_max_mean_abs": "" }, "rhLut": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "heterotrophic_respiration_carbon_flux", + "standard_name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_heterotrophic_respiration", "units": "kg m-2 s-1", - "cell_methods": "area: time: mean where landuse", + "cell_methods": "area: time: mean where sector", "cell_measures": "area: areacella", - "long_name": "soil heterotrophic respiration on land use tile", - "comment": "", + "long_name": "Soil Heterotrophic Respiration on Land-Use Tile", + "comment": "Carbon mass flux per unit area into atmosphere due to heterotrophic respiration on land (respiration by consumers), calculated on land-use tiles.", "dimensions": "longitude latitude landUse time", "out_name": "rhLut", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -4588,16 +4371,17 @@ "ok_max_mean_abs": "" }, "rhShrub": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "heterotrophic_respiration_carbon_flux", + "standard_name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_heterotrophic_respiration", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where shrubs (comment: mask=shrubFrac)", "cell_measures": "area: areacella", - "long_name": "heterotrophic respiration on Shrub tiles", - "comment": "Total RH of shrubs in the gridcell", + "long_name": "Heterotrophic Respiration on Shrub Tiles", + "comment": "Total RH of shrubs in the grid cell", "dimensions": "longitude latitude time", "out_name": "rhShrub", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -4605,16 +4389,17 @@ "ok_max_mean_abs": "" }, "rhSoil": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "heterotrophic_respiration_carbon_flux_from_soil", + "standard_name": "surface_upward_mass_flux_of_carbon_due_to_heterotrophic_respiration_in_soil", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Carbon Mass Flux into Atmosphere due to Heterotrophic Respiration from Soil on Land", + "long_name": "Carbon Mass Flux into Atmosphere Due to Heterotrophic Respiration from Soil on Land", "comment": "Needed to calculate soil bulk turnover time", "dimensions": "longitude latitude time", "out_name": "rhSoil", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -4622,16 +4407,17 @@ "ok_max_mean_abs": "" }, "rhTree": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "heterotrophic_respiration_carbon_flux", + "standard_name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_heterotrophic_respiration", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where trees (comment: mask=treeFrac)", "cell_measures": "area: areacella", - "long_name": "heterotrophic respiration on tree tiles", - "comment": "Total RH of trees in the gridcell", + "long_name": "Heterotrophic Respiration on Tree Tiles", + "comment": "Total RH of trees in the grid cell", "dimensions": "longitude latitude time", "out_name": "rhTree", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -4639,16 +4425,17 @@ "ok_max_mean_abs": "" }, "rhc13": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "heterotrophic_respiration_c13_flux", + "standard_name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_13C_due_to_heterotrophic_respiration", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Mass Flux of 13C into Atmosphere due to Heterotrophic Respiration on Land", - "comment": "", + "long_name": "Mass Flux of 13C into Atmosphere Due to Heterotrophic Respiration on Land", + "comment": "Heterotrophic respiration is respiration by heterotrophs ('consumers'), which are organisms (including animals and decomposers) that consume other organisms or dead organic material, rather than synthesising organic material from inorganic precursors using energy from the environment (especially sunlight) as autotrophs ('producers') do. Heterotrophic respiration goes on within both the soil and litter pools.", "dimensions": "longitude latitude time", "out_name": "rhc13", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -4656,16 +4443,17 @@ "ok_max_mean_abs": "" }, "rhc14": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "heterotrophic_respiration_c14_flux", + "standard_name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_14C_due_to_heterotrophic_respiration", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Mass Flux of 14C into Atmosphere due to Heterotrophic Respiration on Land", - "comment": "", + "long_name": "Mass Flux of 14C into Atmosphere Due to Heterotrophic Respiration on Land", + "comment": "Heterotrophic respiration is respiration by heterotrophs ('consumers'), which are organisms (including animals and decomposers) that consume other organisms or dead organic material, rather than synthesising organic material from inorganic precursors using energy from the environment (especially sunlight) as autotrophs ('producers') do. Heterotrophic respiration goes on within both the soil and litter pools.", "dimensions": "longitude latitude time", "out_name": "rhc14", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -4673,6 +4461,7 @@ "ok_max_mean_abs": "" }, "rls": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "surface_net_downward_longwave_flux", "units": "W m-2", @@ -4682,38 +4471,40 @@ "comment": "Net longwave surface radiation", "dimensions": "longitude latitude time", "out_name": "rls", - "type": "", - "positive": "", + "type": "real", + "positive": "down", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "rlusLut": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "surface_upwelling_longwave_flux_in_air", "units": "W m-2", - "cell_methods": "area: time: mean where landuse", + "cell_methods": "area: time: mean where sector", "cell_measures": "area: areacella", - "long_name": "Surface Upwelling Longwave on Land Use Tile", - "comment": "", + "long_name": "Surface Upwelling Longwave on Land-Use Tile", + "comment": "The surface called 'surface' means the lower boundary of the atmosphere. 'longwave' means longwave radiation. Upwelling radiation is radiation from below. It does not mean 'net upward'. When thought of as being incident on a surface, a radiative flux is sometimes called 'irradiance'. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called 'vector irradiance'. In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions": "longitude latitude landUse time", "out_name": "rlusLut", - "type": "", - "positive": "", + "type": "real", + "positive": "up", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "rsdoabsorb": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "net_rate_of_absorption_of_shortwave_energy_in_ocean_layer", "units": "W m-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "net rate of absorption of shortwave energy in ocean layer", - "comment": "", + "long_name": "Net Rate of Absorption of Shortwave Energy in Ocean Layer", + "comment": "'shortwave' means shortwave radiation. 'Layer' means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be model_level_number, but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well. Net absorbed radiation is the difference between absorbed and emitted radiation.", "dimensions": "longitude latitude olevel time", "out_name": "rsdoabsorb", "type": "real", @@ -4724,40 +4515,43 @@ "ok_max_mean_abs": "" }, "rsdscsdiff": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "surface_diffuse_downwelling_shortwave_flux_in_air_assuming_clear_sky", "units": "W m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Surface Diffuse Downwelling Clear Sky Shortwave Radiation", - "comment": "", + "comment": "Surface downwelling solar irradiance from diffuse radiation for UV calculations in clear sky conditions", "dimensions": "longitude latitude time", "out_name": "rsdscsdiff", - "type": "", - "positive": "", + "type": "real", + "positive": "down", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "rsdsdiff": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "surface_diffuse_downwelling_shortwave_flux_in_air", "units": "W m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Surface Diffuse Downwelling Shortwave Radiation", - "comment": "", + "comment": "Surface downwelling solar irradiance from diffuse radiation for UV calculations.", "dimensions": "longitude latitude time", "out_name": "rsdsdiff", "type": "real", - "positive": "", + "positive": "down", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "rss": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "surface_net_downward_shortwave_flux", "units": "W m-2", @@ -4767,33 +4561,35 @@ "comment": "Net downward shortwave radiation at the surface", "dimensions": "longitude latitude time", "out_name": "rss", - "type": "", - "positive": "", + "type": "real", + "positive": "down", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "rsusLut": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "surface_upwelling_shortwave_flux_in_air", "units": "W m-2", - "cell_methods": "area: time: mean where landuse", + "cell_methods": "area: time: mean where sector", "cell_measures": "area: areacella", - "long_name": "Surface Upwelling Shortwave on Land Use Tile", - "comment": "", + "long_name": "Surface Upwelling Shortwave on Land-use Tile", + "comment": "The surface called 'surface' means the lower boundary of the atmosphere. 'shortwave' means shortwave radiation. Upwelling radiation is radiation from below. It does not mean 'net upward'. When thought of as being incident on a surface, a radiative flux is sometimes called 'irradiance'. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called 'vector irradiance'. In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions": "longitude latitude landUse time", "out_name": "rsusLut", - "type": "", - "positive": "", + "type": "real", + "positive": "up", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "sconcdust": { + "frequency": "mon", "modeling_realm": "atmos", - "standard_name": "mass_concentration_of_dust_dry_aerosol_in_air", + "standard_name": "mass_concentration_of_dust_dry_aerosol_particles_in_air", "units": "kg m-3", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", @@ -4801,7 +4597,7 @@ "comment": "mass concentration of dust dry aerosol in air in model lowest layer", "dimensions": "longitude latitude time", "out_name": "sconcdust", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -4809,8 +4605,9 @@ "ok_max_mean_abs": "" }, "sconcso4": { + "frequency": "mon", "modeling_realm": "atmos", - "standard_name": "mass_concentration_of_sulfate_dry_aerosol_in_air", + "standard_name": "mass_concentration_of_sulfate_dry_aerosol_particles_in_air", "units": "kg m-3", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", @@ -4818,7 +4615,7 @@ "comment": "mass concentration of sulfate dry aerosol in air in model lowest layer.", "dimensions": "longitude latitude time", "out_name": "sconcso4", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -4826,16 +4623,17 @@ "ok_max_mean_abs": "" }, "sconcss": { + "frequency": "mon", "modeling_realm": "atmos", - "standard_name": "mass_concentration_of_seasalt_dry_aerosol_in_air", + "standard_name": "mass_concentration_of_sea_salt_dry_aerosol_particles_in_air", "units": "kg m-3", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Surface Concentration of Seasalt", - "comment": "mass concentration of seasalt dry aerosol in air in model lowest layer", + "long_name": "Surface Concentration of Sea-Salt Aerosol", + "comment": "mass concentration of sea-salt dry aerosol in air in model lowest layer", "dimensions": "longitude latitude time", "out_name": "sconcss", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -4843,16 +4641,17 @@ "ok_max_mean_abs": "" }, "sedustCI": { - "modeling_realm": "atmos", - "standard_name": "tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_particles_due_to_sedimentation", + "frequency": "mon", + "modeling_realm": "aerosol", + "standard_name": "minus_tendency_of_atmosphere_mass_content_of_insoluble_dust_dry_aerosol_particles_due_to_deposition", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Sedimentation Flux of dust mode coarse insoluble", - "comment": "Balkanski - LSCE", + "long_name": "Sedimentation Flux of Dust Mode Coarse Insoluble", + "comment": "Dry mass deposition rate of dust aerosol.", "dimensions": "longitude latitude time", "out_name": "sedustCI", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -4860,10 +4659,11 @@ "ok_max_mean_abs": "" }, "sfcWindmax": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "wind_speed", "units": "m s-1", - "cell_methods": "area: time: mean", + "cell_methods": "area: mean time: maximum within days time: mean over days", "cell_measures": "area: areacella", "long_name": "Daily Maximum Near-Surface Wind Speed", "comment": "Daily maximum near-surface (usually, 10 meters) wind speed.", @@ -4877,16 +4677,17 @@ "ok_max_mean_abs": "" }, "snowmxrat27": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "mass_fraction_of_snow_in_air", - "units": "1.0", + "units": "1", "cell_methods": "time: mean", "cell_measures": "area: areacella", - "long_name": "snow_mixing_ratio", + "long_name": "Mass Fraction of Snow in Air", "comment": "Snow mixing ratio", "dimensions": "longitude latitude plev27 time", "out_name": "snowmxrat", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -4894,12 +4695,13 @@ "ok_max_mean_abs": "" }, "somint": { + "frequency": "mon", "modeling_realm": "ocean", - "standard_name": "integral_wrt_depth_of_product_of_sea_water_density_and_prognostic_salinity", - "units": "1e-3 kg m-2", + "standard_name": "integral_wrt_depth_of_product_of_sea_water_density_and_salinity", + "units": "g m-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "integral wrt depth of product of sea water density and salinity", + "long_name": "Depth Integral of Product of Sea Water Density and Prognostic Salinity", "comment": "Full column sum of density*cell thickness*prognostic salinity. If the model is Boussinesq, then use Boussinesq reference density for the density factor.", "dimensions": "longitude latitude time", "out_name": "somint", @@ -4910,17 +4712,72 @@ "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, + "sw17O": { + "frequency": "mon", + "modeling_realm": "ocean", + "standard_name": "isotope_ratio_of_17O_to_16O_in_sea_water_excluding_solutes_and_solids", + "units": "1", + "cell_methods": "area: mean where sea time: mean", + "cell_measures": "area: areacello volume: volcello", + "long_name": "Isotopic Ratio of Oxygen-17 in Sea Water", + "comment": "Ratio of abundance of oxygen-17 (17O) atoms to oxygen-16 (16O) atoms in sea water", + "dimensions": "longitude latitude olevel time", + "out_name": "sw17O", + "type": "real", + "positive": "", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, + "sw18O": { + "frequency": "mon", + "modeling_realm": "atmos", + "standard_name": "isotope_ratio_of_18O_to_16O_in_sea_water_excluding_solutes_and_solids", + "units": "1", + "cell_methods": "area: time: mean", + "cell_measures": "area: areacella", + "long_name": "Mass of Water Containing Oxygen-18 (H2 18O) in Layer", + "comment": "Water vapor path for water molecules that contain oxygen-18 (H2 18O)", + "dimensions": "longitude latitude alevel time", + "out_name": "sw18O", + "type": "real", + "positive": "", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, + "sw2H": { + "frequency": "mon", + "modeling_realm": "ocean", + "standard_name": "isotope_ratio_of_2H_to_1H_in_sea_water_excluding_solutes_and_solids", + "units": "1", + "cell_methods": "area: mean where sea time: mean", + "cell_measures": "area: areacello volume: volcello", + "long_name": "Isotopic Ratio of Deuterium in Sea Water", + "comment": "Ratio of abundance of hydrogen-2 (2H) atoms to hydrogen-1 (1H) atoms in sea water", + "dimensions": "longitude latitude olevel time", + "out_name": "sw2H", + "type": "real", + "positive": "", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, "sweLut": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "missing", + "standard_name": "lwe_thickness_of_surface_snow_amount", "units": "m", - "cell_methods": "area: time: mean where landuse", + "cell_methods": "area: time: mean where sector", "cell_measures": "area: areacella", - "long_name": "snow water equivalent on land use tile", - "comment": "", + "long_name": "Snow Water Equivalent on Land-Use Tile", + "comment": "The surface called 'surface' means the lower boundary of the atmosphere. 'lwe' means liquid water equivalent. 'Amount' means mass per unit area. The construction lwe_thickness_of_X_amount or _content means the vertical extent of a layer of liquid water having the same mass per unit area. Surface amount refers to the amount on the ground, excluding that on the plant or vegetation canopy.", "dimensions": "longitude latitude landUse time", "out_name": "sweLut", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -4928,16 +4785,17 @@ "ok_max_mean_abs": "" }, "swsrfasdust": { + "frequency": "mon", "modeling_realm": "atmos", - "standard_name": "tendency_of_all_sky_surface_shortwave_flux_due_to_dust_ambient_aerosol_particles", + "standard_name": "surface_net_downward_shortwave_dust_ambient_aerosol_particles_direct_radiative_effect", "units": "W m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "All-sky Surface Shortwave radiative flux due to Dust", - "comment": "Balkanski - LSCE", + "long_name": "All-Sky Surface Shortwave Radiative Flux Due to Dust", + "comment": "The direct radiative effect refers to the instantaneous radiative impact on the Earth's energy balance, excluding secondary effects such as changes in cloud cover.", "dimensions": "longitude latitude time", "out_name": "swsrfasdust", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -4945,16 +4803,17 @@ "ok_max_mean_abs": "" }, "swsrfcsdust": { + "frequency": "mon", "modeling_realm": "atmos", - "standard_name": "tendency_of_clear_sky_surface_shortwave_flux_due_to_dust_ambient_aerosol_particles", + "standard_name": "surface_net_downward_shortwave_dust_ambient_aerosol_particles_direct_radiative_effect_assuming_clear_sky", "units": "W m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Clear-sky Surface Shortwave radiative flux due to Dust", - "comment": "Balkanski - LSCE", + "long_name": "Clear-Sky Surface Shortwave Radiative Flux Due to Dust", + "comment": "The direct radiative effect refers to the instantaneous radiative impact on the Earth's energy balance, excluding secondary effects such as changes in cloud cover. Calculated in clear-sky conditions.", "dimensions": "longitude latitude time", "out_name": "swsrfcsdust", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -4962,16 +4821,17 @@ "ok_max_mean_abs": "" }, "swtoaasdust": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "toa_instantaneous_shortwave_forcing", "units": "W m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "all sky sw-rf dust at toa", - "comment": "proposed name: toa_instantaneous_shortwave_forcing_due_to_dust_ambient_aerosol", + "long_name": "All-Sky Shortwave Flux Due to Dust at Toa", + "comment": "Instantaneous forcing is the radiative flux change caused instantaneously by an imposed change in radiative forcing agent (greenhouse gases, aerosol, solar radiation, etc.).", "dimensions": "longitude latitude time", "out_name": "swtoaasdust", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -4979,16 +4839,17 @@ "ok_max_mean_abs": "" }, "swtoacsdust": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "toa_instantaneous_shortwave_forcing", "units": "W m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "clear sky sw-rf dust at toa", - "comment": "proposed name: toa_instantaneous_shortwave_forcing_due_to_dust_ambient_aerosol_assuming_clear_sky", + "long_name": "clear sky Shortwave flux due to dust at toa", + "comment": "Instantaneous forcing is the radiative flux change caused instantaneously by an imposed change in radiative forcing agent (greenhouse gases, aerosol, solar radiation, etc.).", "dimensions": "longitude latitude time", "out_name": "swtoacsdust", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -4996,16 +4857,17 @@ "ok_max_mean_abs": "" }, "t2": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "square_of_air_temperature", "units": "K2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "square_of_air_temperature", + "long_name": "Mean-Squared Air Temperature", "comment": "Air temperature squared", "dimensions": "longitude latitude alevel time", "out_name": "t2", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5013,16 +4875,17 @@ "ok_max_mean_abs": "" }, "t20d": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "depth_of_isosurface_of_sea_water_potential_temperature", "units": "m", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "20C isotherm depth", - "comment": "", + "long_name": "Depth of 20 degree Celsius Isotherm", + "comment": "This quantity, sometimes called the 'isotherm depth', is the depth (if it exists) at which the sea water potential temperature equals some specified value. This value should be specified in a scalar coordinate variable. Depth is the vertical distance below the surface. Potential temperature is the temperature a parcel of air or sea water would have if moved adiabatically to sea level pressure.", "dimensions": "longitude latitude time", "out_name": "t20d", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5030,16 +4893,17 @@ "ok_max_mean_abs": "" }, "tSoilPools": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "soil_carbon_turnover_rate_by_pool", + "standard_name": "soil_pool_carbon_decay_rate", "units": "s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "turnover rate of each model soil carbon pool", + "long_name": "Turnover Rate of Each Model Soil Carbon Pool", "comment": "defined as 1/(turnover time) for each soil pool. Use the same pools reported under cSoilPools", - "dimensions": "longitude latitude time", + "dimensions": "longitude latitude soilpools time", "out_name": "tSoilPools", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5047,6 +4911,7 @@ "ok_max_mean_abs": "" }, "ta27": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "air_temperature", "units": "K", @@ -5056,7 +4921,7 @@ "comment": "Air Temperature", "dimensions": "longitude latitude plev27 time", "out_name": "ta", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5064,16 +4929,17 @@ "ok_max_mean_abs": "" }, "tasLut": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "air_temperature", "units": "K", - "cell_methods": "area: time: mean where landuse", + "cell_methods": "area: time: mean where sector", "cell_measures": "area: areacella", - "long_name": "near-surface air temperature (2m above displacement height, i.e. t_ref) on land use tile", - "comment": "", + "long_name": "Near-Surface Air Temperature on Land Use Tile", + "comment": "Air temperature is the bulk temperature of the air, not the surface (skin) temperature.", "dimensions": "longitude latitude landUse time height2m", "out_name": "tasLut", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5081,16 +4947,17 @@ "ok_max_mean_abs": "" }, "tasmaxCrop": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "air_temperature", "units": "K", - "cell_methods": "area: mean time: maximum within days time: mean over days", + "cell_methods": "area: mean where crops time: maximum within days time: mean over days", "cell_measures": "area: areacella", "long_name": "Daily Maximum Near-Surface Air Temperature over Crop Tile", "comment": "maximum near-surface (usually, 2 meter) air temperature (add cell_method attribute 'time: max')", "dimensions": "longitude latitude time height2m", "out_name": "tasmaxCrop", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5098,16 +4965,17 @@ "ok_max_mean_abs": "" }, "tasminCrop": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "air_temperature", "units": "K", - "cell_methods": "area: mean time: minimum within days time: mean over days", + "cell_methods": "area: mean where crops time: minimum within days time: mean over days", "cell_measures": "area: areacella", "long_name": "Daily Minimum Near-Surface Air Temperature over Crop Tile", "comment": "minimum near-surface (usually, 2 meter) air temperature (add cell_method attribute 'time: min')", "dimensions": "longitude latitude time height2m", "out_name": "tasminCrop", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5115,16 +4983,17 @@ "ok_max_mean_abs": "" }, "tdps": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "dew_point_temperature", "units": "K", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "2m dewpoint temperature", - "comment": "", + "long_name": "2m Dewpoint Temperature", + "comment": "Dew point temperature is the temperature at which a parcel of air reaches saturation upon being cooled at constant pressure and specific humidity.", "dimensions": "longitude latitude time", "out_name": "tdps", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5132,16 +5001,17 @@ "ok_max_mean_abs": "" }, "thetaot": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "sea_water_potential_temperature", "units": "degC", - "cell_methods": "area: mean where sea time: mean", + "cell_methods": "area: depth: time: mean", "cell_measures": "area: areacello", "long_name": "Vertically Averaged Sea Water Potential Temperature", "comment": "Vertical average of the sea water potential temperature through the whole ocean depth", "dimensions": "longitude latitude time", "out_name": "thetaot", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5149,16 +5019,17 @@ "ok_max_mean_abs": "" }, "thetaot2000": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "sea_water_potential_temperature", "units": "degC", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "Depth average potential temperature of upper 2000m", + "cell_methods": "area: depth: time: mean", + "cell_measures": "area: areacello", + "long_name": "Depth Average Potential Temperature of Upper 2000m", "comment": "Upper 2000m, 2D field", "dimensions": "longitude latitude time depth2000m", "out_name": "thetaot2000", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5166,16 +5037,17 @@ "ok_max_mean_abs": "" }, "thetaot300": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "sea_water_potential_temperature", "units": "degC", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "Depth average potential temperature of upper 300m", + "cell_methods": "area: depth: time: mean", + "cell_measures": "area: areacello", + "long_name": "Depth Average Potential Temperature of Upper 300m", "comment": "Upper 300m, 2D field", "dimensions": "longitude latitude time depth300m", "out_name": "thetaot300", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5183,16 +5055,17 @@ "ok_max_mean_abs": "" }, "thetaot700": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "sea_water_potential_temperature", "units": "degC", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "Depth average potential temperature of upper 700m", + "cell_methods": "area: depth: time: mean", + "cell_measures": "area: areacello", + "long_name": "Depth Average Potential Temperature of Upper 700m", "comment": "Upper 700m, 2D field", "dimensions": "longitude latitude time depth700m", "out_name": "thetaot700", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5200,6 +5073,7 @@ "ok_max_mean_abs": "" }, "tnhuspbl": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "tendency_of_specific_humidity_due_to_boundary_layer_mixing", "units": "s-1", @@ -5209,7 +5083,7 @@ "comment": "Includes all boundary layer terms including diffusive terms.", "dimensions": "longitude latitude alevel time", "out_name": "tnhuspbl", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5217,16 +5091,17 @@ "ok_max_mean_abs": "" }, "tnhusscp": { + "frequency": "mon", "modeling_realm": "atmos", - "standard_name": "tendency_of_specific_humidity_due_to_stratiform_clouds_and_precipitation", + "standard_name": "tendency_of_specific_humidity_due_to_stratiform_cloud_and_precipitation", "units": "s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Tendency of Specific Humidity Due to Stratiform Clouds and Precipitation", - "comment": "", + "comment": "The phrase 'tendency_of_X' means derivative of X with respect to time. 'Specific' means per unit mass. Specific humidity is the mass fraction of water vapor in (moist) air. The specification of a physical process by the phrase 'due_to_' process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. A variable with the standard name of tendency_of_specific_humidity_due_to_stratiform_cloud_and_precipitation should contain the effects of all processes which convert stratiform clouds and precipitation to or from water vapor. In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes).", "dimensions": "longitude latitude alevel time", "out_name": "tnhusscp", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5234,16 +5109,17 @@ "ok_max_mean_abs": "" }, "tntd": { + "frequency": "mon", "modeling_realm": "atmos", - "standard_name": "tendency_of_air_temperature_due_to_numerical_diffusion", + "standard_name": "tendency_of_air_temperature_due_to_diffusion", "units": "K s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Tendency of Air Temperature due to Numerical Diffusion", + "long_name": "Tendency of Air Temperature Due to Numerical Diffusion", "comment": "This includes any horizontal or vertical numerical temperature diffusion not associated with the parametrized moist physics or the resolved dynamics. For example, any vertical diffusion which is part of the boundary layer mixing scheme should be excluded, as should any diffusion which is included in the terms from the resolved dynamics. This term is required to check the closure of the temperature budget.", "dimensions": "longitude latitude alevel time", "out_name": "tntd", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5251,12 +5127,13 @@ "ok_max_mean_abs": "" }, "tntmp27": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "tendency_of_air_temperature_due_to_model_physics", "units": "K s-1", "cell_methods": "time: mean", "cell_measures": "area: areacella", - "long_name": "Tendency of Air Temperature due to Model Physics", + "long_name": "Tendency of Air Temperature Due to Model Physics", "comment": "Tendency of air temperature due to model physics. This includes sources and sinks from parametrized physics (e.g. radiation, convection, boundary layer, stratiform condensation/evaporation, etc.). It excludes sources and sinks from resolved dynamics and numerical diffusion not associated with parametrized physics. For example, any vertical diffusion which is part of the boundary layer mixing scheme should be included, while numerical diffusion applied in addition to physics or resolved dynamics should be excluded. This term is required to check the closure of the heat budget.", "dimensions": "longitude latitude plev27 time", "out_name": "tntmp", @@ -5268,6 +5145,7 @@ "ok_max_mean_abs": "" }, "tntpbl": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "tendency_of_air_temperature_due_to_boundary_layer_mixing", "units": "K s-1", @@ -5277,7 +5155,7 @@ "comment": "Includes all boundary layer terms including diffusive terms.", "dimensions": "longitude latitude alevel time", "out_name": "tntpbl", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5285,16 +5163,17 @@ "ok_max_mean_abs": "" }, "tntrl27": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "tendency_of_air_temperature_due_to_longwave_heating", "units": "K s-1", "cell_methods": "time: mean", "cell_measures": "area: areacella", - "long_name": "Longwave heating rate", + "long_name": "Tendency of Air Temperature Due to Longwave Radiative Heating", "comment": "Tendency of air temperature due to longwave radiative heating", "dimensions": "longitude latitude plev27 time", "out_name": "tntrl", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5302,16 +5181,17 @@ "ok_max_mean_abs": "" }, "tntrlcs": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "tendency_of_air_temperature_due_to_longwave_heating_assuming_clear_sky", "units": "K s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Tendency of Air Temperature due to Clear Sky Longwave Radiative Heating", + "long_name": "Tendency of Air Temperature Due to Clear Sky Longwave Radiative Heating", "comment": "Tendency of Air Temperature due to Clear Sky Longwave Radiative Heating", "dimensions": "longitude latitude alevel time", "out_name": "tntrlcs", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5319,16 +5199,17 @@ "ok_max_mean_abs": "" }, "tntrs27": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "tendency_of_air_temperature_due_to_shortwave_heating", "units": "K s-1", "cell_methods": "time: mean", "cell_measures": "area: areacella", - "long_name": "Shortwave heating rate", + "long_name": "Tendency of Air Temperature Due to Shortwave Radiative Heating", "comment": "Tendency of air temperature due to shortwave radiative heating", "dimensions": "longitude latitude plev27 time", "out_name": "tntrs", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5336,16 +5217,17 @@ "ok_max_mean_abs": "" }, "tntrscs": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "tendency_of_air_temperature_due_to_shortwave_heating_assuming_clear_sky", "units": "K s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Tendency of Air Temperature due to Clear Sky Shortwave Radiative Heating", + "long_name": "Tendency of Air Temperature Due to Clear Sky Shortwave Radiative Heating", "comment": "Tendency of Air Temperature due to Clear Sky Shortwave Radiative Heating", "dimensions": "longitude latitude alevel time", "out_name": "tntrscs", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5353,33 +5235,17 @@ "ok_max_mean_abs": "" }, "tntscp": { + "frequency": "mon", "modeling_realm": "atmos", - "standard_name": "tendency_of_air_temperature_due_to_stratiform_clouds_and_precipitation", + "standard_name": "tendency_of_air_temperature_due_to_stratiform_cloud_and_precipitation", "units": "K s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Tendency of Air Temperature Due to Stratiform Clouds and Precipitation", - "comment": "", + "comment": "The phrase 'tendency_of_X' means derivative of X with respect to time. Air temperature is the bulk temperature of the air, not the surface (skin) temperature. The specification of a physical process by the phrase 'due_to_' process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. A variable with the standard name tendency_of_air_temperature_due_to_stratiform_cloud_and_precipitation should contain net latent heating effects of all processes which convert stratiform clouds and precipitation between water vapour, liquid or ice phases. In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes).", "dimensions": "longitude latitude alevel time", "out_name": "tntscp", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "tomint": { - "modeling_realm": "ocean", - "standard_name": "integral_wrt_depth_of_product_of_sea_water_density_and_prognostic_temperature", - "units": "1e-3 kg m-2", - "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", - "long_name": "integral wrt depth of product of sea water density and prognostic temperature", - "comment": "Full column sum of density*cell thickness*prognostic temperature. If the model is Boussinesq, then use Boussinesq reference density for the density factor.", - "dimensions": "longitude latitude time", - "out_name": "tomint", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5387,16 +5253,17 @@ "ok_max_mean_abs": "" }, "treeFracBdlDcd": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "area_fraction", "units": "%", "cell_methods": "area: mean where land over all_area_types time: mean", "cell_measures": "area: areacella", - "long_name": "Broadleaf deciduous tree fraction", - "comment": "This is the fraction of the entire grid cell that is covered by broadleaf deciduous trees.", + "long_name": "Broadleaf Deciduous Tree Area Percentage", + "comment": "This is the percentage of the entire grid cell that is covered by broadleaf deciduous trees.", "dimensions": "longitude latitude time typetreebd", "out_name": "treeFracBdlDcd", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5404,16 +5271,17 @@ "ok_max_mean_abs": "" }, "treeFracBdlEvg": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "area_fraction", "units": "%", "cell_methods": "area: mean where land over all_area_types time: mean", "cell_measures": "area: areacella", - "long_name": "Broadleaf evergreen tree fraction", - "comment": "This is the fraction of the entire grid cell that is covered by broadleaf evergreen trees.", + "long_name": "Broadleaf Evergreen Tree Area Percentage", + "comment": "This is the percentage of the entire grid cell that is covered by broadleaf evergreen trees.", "dimensions": "longitude latitude time typetreebe", "out_name": "treeFracBdlEvg", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5421,16 +5289,17 @@ "ok_max_mean_abs": "" }, "treeFracNdlDcd": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "area_fraction", "units": "%", "cell_methods": "area: mean where land over all_area_types time: mean", "cell_measures": "area: areacella", - "long_name": "Needleleaf deciduous tree fraction", - "comment": "This is the fraction of the entire grid cell that is covered by needleleaf deciduous trees.", + "long_name": "Needleleaf Deciduous Tree Area Percentage", + "comment": "This is the percentage of the entire grid cell that is covered by needleleaf deciduous trees.", "dimensions": "longitude latitude time typetreend", "out_name": "treeFracNdlDcd", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5438,16 +5307,17 @@ "ok_max_mean_abs": "" }, "treeFracNdlEvg": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "area_fraction", "units": "%", "cell_methods": "area: mean where land over all_area_types time: mean", "cell_measures": "area: areacella", - "long_name": "Needleleaf evergreen tree fraction", - "comment": "This is the fraction of the entire grid cell that is covered by needleleaf evergreen trees.", + "long_name": "Needleleaf Evergreen Tree Area Percentage", + "comment": "This is the percentage of the entire grid cell that is covered by needleleaf evergreen trees.", "dimensions": "longitude latitude time typetreene", "out_name": "treeFracNdlEvg", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5455,16 +5325,17 @@ "ok_max_mean_abs": "" }, "tslsiLut": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "surface_temperature", "units": "K", - "cell_methods": "area: time: mean where landuse", + "cell_methods": "area: time: mean where sector", "cell_measures": "area: areacella", - "long_name": "surface skin temperature on land use tile", - "comment": "temperature at which long-wave radiation emitted", + "long_name": "Surface Temperature on Landuse Tile", + "comment": "Surface temperature (i.e. temperature at which long-wave radiation emitted)", "dimensions": "longitude latitude landUse time", "out_name": "tslsiLut", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5472,16 +5343,17 @@ "ok_max_mean_abs": "" }, "twap": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "product_of_omega_and_air_temperature", "units": "K Pa s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "air_temperature_times_omega", + "long_name": "Product of Air Temperature and Omega", "comment": "Product of air temperature and pressure tendency", "dimensions": "longitude latitude alevel time", "out_name": "twap", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5489,16 +5361,35 @@ "ok_max_mean_abs": "" }, "u2": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "square_of_eastward_wind", "units": "m2 s-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "square_of_eastward_wind", + "long_name": "Mean-Squared Eastward Wind Speed", "comment": "u*u", "dimensions": "longitude latitude alevel time", "out_name": "u2", - "type": "", + "type": "real", + "positive": "", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, + "ua": { + "frequency": "mon", + "modeling_realm": "atmos", + "standard_name": "eastward_wind", + "units": "m s-1", + "cell_methods": "area: time: mean", + "cell_measures": "area: areacella", + "long_name": "Eastward Wind", + "comment": "Zonal wind (positive in a eastward direction).", + "dimensions": "longitude latitude plev7h time", + "out_name": "ua", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5506,16 +5397,17 @@ "ok_max_mean_abs": "" }, "ua27": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "eastward_wind", "units": "m s-1", "cell_methods": "time: mean", "cell_measures": "area: areacella", "long_name": "Eastward Wind", - "comment": "", + "comment": "Zonal wind (positive in a eastward direction).", "dimensions": "longitude latitude plev27 time", "out_name": "ua", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5523,16 +5415,17 @@ "ok_max_mean_abs": "" }, "uqint": { + "frequency": "mon", "modeling_realm": "atmos", - "standard_name": "integral_of_product_of_eastward_wind_and_specific_humidity_wrt_height", + "standard_name": "integral_wrt_height_of_product_of_eastward_wind_and_specific_humidity", "units": "m2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "integrated_eastward_wind_times_humidity", + "long_name": "Eastward Humidity Transport", "comment": "Column integrated eastward wind times specific humidity", "dimensions": "longitude latitude time", "out_name": "uqint", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5540,16 +5433,17 @@ "ok_max_mean_abs": "" }, "ut": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "product_of_eastward_wind_and_air_temperature", "units": "K m s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "air_temperature_times_eastward_wind", + "long_name": "Product of Air Temperature and Eastward Wind", "comment": "Product of air temperature and eastward wind", "dimensions": "longitude latitude alevel time", "out_name": "ut", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5557,16 +5451,17 @@ "ok_max_mean_abs": "" }, "utendnogw": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "tendency_of_eastward_wind_due_to_nonorographic_gravity_wave_drag", "units": "m s-2", "cell_methods": "time: mean", "cell_measures": "area: areacella", - "long_name": "u-tendency nonorographic gravity wave drag", + "long_name": "Eastward Acceleration Due to Non-Orographic Gravity Wave Drag", "comment": "Tendency of the eastward wind by parameterized nonorographic gravity waves.", "dimensions": "longitude latitude plev19 time", "out_name": "utendnogw", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5574,16 +5469,17 @@ "ok_max_mean_abs": "" }, "utendogw": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "tendency_of_eastward_wind_due_to_orographic_gravity_wave_drag", "units": "m s-2", "cell_methods": "time: mean", "cell_measures": "area: areacella", - "long_name": "u-tendency orographic gravity wave drag", + "long_name": "Eastward Acceleration Due to Orographic Gravity Wave Drag", "comment": "Tendency of the eastward wind by parameterized orographic gravity waves.", "dimensions": "longitude latitude plev19 time", "out_name": "utendogw", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5591,16 +5487,17 @@ "ok_max_mean_abs": "" }, "uv": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "product_of_eastward_wind_and_northward_wind", "units": "m2 s-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "eastward_wind_times_northward_wind", + "long_name": "Product of Eastward Wind and Northward Wind", "comment": "u*v", "dimensions": "longitude latitude alevel time", "out_name": "uv", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5608,16 +5505,17 @@ "ok_max_mean_abs": "" }, "uwap": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "product_of_eastward_wind_and_omega", "units": "Pa m s-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "eastward_wind_times_omega", + "long_name": "Product of Eastward Wind and Omega", "comment": "u*omega", "dimensions": "longitude latitude alevel time", "out_name": "uwap", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5625,16 +5523,35 @@ "ok_max_mean_abs": "" }, "v2": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "square_of_northward_wind", "units": "m2 s-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "square_of_northwardwind", + "long_name": "Mean-Squared Northward Wind Speed", "comment": "v*v", "dimensions": "longitude latitude alevel time", "out_name": "v2", - "type": "", + "type": "real", + "positive": "", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, + "va": { + "frequency": "mon", + "modeling_realm": "atmos", + "standard_name": "northward_wind", + "units": "m s-1", + "cell_methods": "area: time: mean", + "cell_measures": "area: areacella", + "long_name": "Northward Wind", + "comment": "Meridional wind (positive in a northward direction).", + "dimensions": "longitude latitude plev7h time", + "out_name": "va", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5642,16 +5559,17 @@ "ok_max_mean_abs": "" }, "va27": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "northward_wind", "units": "m s-1", "cell_methods": "time: mean", "cell_measures": "area: areacella", "long_name": "Northward Wind", - "comment": "", + "comment": "Meridional wind (positive in a northward direction).", "dimensions": "longitude latitude plev27 time", "out_name": "va", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5659,16 +5577,17 @@ "ok_max_mean_abs": "" }, "vegFrac": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "area_fraction", "units": "%", "cell_methods": "area: mean where land over all_area_types time: mean", "cell_measures": "area: areacella", - "long_name": "Total vegetated fraction", - "comment": "fraction of grid cell that is covered by vegetation.This SHOULD be the sum of tree, grass, crop and shrub fractions.", + "long_name": "Total Vegetated Percentage Cover", + "comment": "Percentage of grid cell that is covered by vegetation.This SHOULD be the sum of tree, grass, crop and shrub fractions.", "dimensions": "longitude latitude time typeveg", "out_name": "vegFrac", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5676,16 +5595,17 @@ "ok_max_mean_abs": "" }, "vegHeight": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "canopy_height", "units": "m", - "cell_methods": "area: mean where land time: mean", + "cell_methods": "area: time: mean where vegetation (comment: mask=vegFrac)", "cell_measures": "area: areacella", - "long_name": "canopy height", - "comment": "", + "long_name": "Height of the Vegetation Canopy", + "comment": "Vegetation height averaged over all vegetation types and over the vegetated fraction of a grid cell.", "dimensions": "longitude latitude time", "out_name": "vegHeight", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5693,16 +5613,17 @@ "ok_max_mean_abs": "" }, "vegHeightCrop": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "canopy_height", "units": "m", "cell_methods": "area: time: mean where crops (comment: mask=cropFrac)", "cell_measures": "area: areacella", - "long_name": "Vegetation height averaged over the crop fraction of a grid cell.", - "comment": "", + "long_name": "Height of Crops", + "comment": "Vegetation height averaged over the crop fraction of a grid cell.", "dimensions": "longitude latitude time", "out_name": "vegHeightCrop", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5710,16 +5631,17 @@ "ok_max_mean_abs": "" }, "vegHeightGrass": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "canopy_height", "units": "m", "cell_methods": "area: time: mean where natural_grasses (comment: mask=grassFrac)", "cell_measures": "area: areacella", - "long_name": "Vegetation height averaged over the grass fraction of a grid cell.", - "comment": "", + "long_name": "Height of Grass", + "comment": "Vegetation height averaged over the grass fraction of a grid cell.", "dimensions": "longitude latitude time", "out_name": "vegHeightGrass", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5727,16 +5649,17 @@ "ok_max_mean_abs": "" }, "vegHeightPasture": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "canopy_height", "units": "m", - "cell_methods": "area: mean where land time: mean", + "cell_methods": "area: time: mean where pastures (comment: mask=pastureFrac)", "cell_measures": "area: areacella", - "long_name": "Vegetation height averaged over the pasture fraction of a grid cell.", - "comment": "", + "long_name": "Height of Pastures", + "comment": "Vegetation height averaged over the pasture fraction of a grid cell.", "dimensions": "longitude latitude time", "out_name": "vegHeightPasture", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5744,16 +5667,17 @@ "ok_max_mean_abs": "" }, "vegHeightShrub": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "canopy_height", "units": "m", "cell_methods": "area: time: mean where shrubs (comment: mask=shrubFrac)", "cell_measures": "area: areacella", - "long_name": "Vegetation height averaged over the shrub fraction of a grid cell.", - "comment": "", + "long_name": "Height of Shrubs", + "comment": "Vegetation height averaged over the shrub fraction of a grid cell.", "dimensions": "longitude latitude time", "out_name": "vegHeightShrub", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5761,16 +5685,17 @@ "ok_max_mean_abs": "" }, "vegHeightTree": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "canopy_height", "units": "m", "cell_methods": "area: time: mean where trees (comment: mask=treeFrac)", "cell_measures": "area: areacella", - "long_name": "Vegetation height averaged over the tree fraction of a grid cell.", - "comment": "", + "long_name": "Height of Trees", + "comment": "Vegetation height averaged over the tree fraction of a grid cell.", "dimensions": "longitude latitude time", "out_name": "vegHeightTree", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5778,16 +5703,17 @@ "ok_max_mean_abs": "" }, "vqint": { + "frequency": "mon", "modeling_realm": "atmos", - "standard_name": "integral_of_product_of_northward_wind_and_specific_humidity_wrt_height", + "standard_name": "integral_wrt_height_of_product_of_northward_wind_and_specific_humidity", "units": "m2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "integrated_northward_wind_times_humidity", + "long_name": "Northward Humidity Transport", "comment": "Column integrated northward wind times specific humidity", "dimensions": "longitude latitude time", "out_name": "vqint", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5795,16 +5721,17 @@ "ok_max_mean_abs": "" }, "vt": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "product_of_northward_wind_and_air_temperature", "units": "K m s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "air_temperature_times_northward_wind", + "long_name": "Product of Air Temperature and Northward Wind", "comment": "Product of air temperature and northward wind", "dimensions": "longitude latitude alevel time", "out_name": "vt", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5812,16 +5739,17 @@ "ok_max_mean_abs": "" }, "vtendnogw": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "tendency_of_northward_wind_due_to_nonorographic_gravity_wave_drag", "units": "m s-2", "cell_methods": "time: mean", "cell_measures": "area: areacella", - "long_name": "v-tendency nonorographic gravity wave drag", + "long_name": "Northward Acceleration Due to Non-Orographic Gravity Wave Drag", "comment": "Tendency of the northward wind by parameterized nonorographic gravity waves. (Note that CF name tables only have a general northward tendency for all gravity waves, and we need it separated by type.)", "dimensions": "longitude latitude plev19 time", "out_name": "vtendnogw", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5829,16 +5757,17 @@ "ok_max_mean_abs": "" }, "vtendogw": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "tendency_of_northward_wind_due_to_orographic_gravity_wave_drag", "units": "m s-2", "cell_methods": "time: mean", "cell_measures": "area: areacella", - "long_name": "v-tendency orographic gravity wave drag", + "long_name": "Northward Acceleration Due to Orographic Gravity Wave Drag", "comment": "Tendency of the northward wind by parameterized orographic gravity waves. (Note that CF name tables only have a general northward tendency for all gravity waves, and we need it separated by type.)", "dimensions": "longitude latitude plev19 time", "out_name": "vtendogw", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5846,16 +5775,17 @@ "ok_max_mean_abs": "" }, "vwap": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "product_of_northward_wind_and_omega", "units": "Pa m s-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "northward_wind_times_omega", + "long_name": "Product of Northward Wind and Omega", "comment": "v*omega", "dimensions": "longitude latitude alevel time", "out_name": "vwap", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5863,12 +5793,13 @@ "ok_max_mean_abs": "" }, "wap": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "lagrangian_tendency_of_air_pressure", "units": "Pa s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "omega (=dp/dt)", + "long_name": "Omega (=dp/dt)", "comment": "Omega (vertical velocity in pressure coordinates, positive downwards)", "dimensions": "longitude latitude alevel time", "out_name": "wap", @@ -5880,33 +5811,17 @@ "ok_max_mean_abs": "" }, "wap2": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "square_of_lagrangian_tendency_of_air_pressure", "units": "Pa2 s-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "square_of_omega", + "long_name": "Mean-Squared Vertical Velocity (Omega)", "comment": "omega*omega", "dimensions": "longitude latitude alevel time", "out_name": "wap2", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "waterDpth": { - "modeling_realm": "land", - "standard_name": "water_table_depth", - "units": "m", - "cell_methods": "area: mean where land time: mean", - "cell_measures": "area: areacella", - "long_name": "Water table depth from surface.", - "comment": "", - "dimensions": "longitude latitude time", - "out_name": "waterDpth", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5914,16 +5829,17 @@ "ok_max_mean_abs": "" }, "wetlandCH4": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "wetland_methane_emissions", + "standard_name": "surface_net_upward_mass_flux_of_methane_due_to_emission_from_wetland_biological_processes", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Grid averaged methane emissions from wetlands", - "comment": "", + "long_name": "Grid Averaged Methane Emissions from Wetlands", + "comment": "Net upward flux of methane (NH4) from wetlands (areas where water covers the soil, or is present either at or near the surface of the soil all year or for varying periods of time during the year, including during the growing season). ", "dimensions": "longitude latitude time", "out_name": "wetlandCH4", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5931,16 +5847,17 @@ "ok_max_mean_abs": "" }, "wetlandCH4cons": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "wetland_methane_consumption", + "standard_name": "surface_downward_mass_flux_of_methane_due_to_wetland_biological_consumption", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Grid averaged methane consuption (methanotrophy) from wetlands", - "comment": "", + "long_name": "Grid Averaged Methane Consumption (Methanotrophy) from Wetlands", + "comment": "Biological consumption (methanotrophy) of methane (NH4) by wetlands (areas where water covers the soil, or is present either at or near the surface of the soil all year or for varying periods of time during the year, including during the growing season). ", "dimensions": "longitude latitude time", "out_name": "wetlandCH4cons", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5948,16 +5865,17 @@ "ok_max_mean_abs": "" }, "wetlandCH4prod": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "wetland_methane_production", + "standard_name": "surface_upward_mass_flux_of_methane_due_to_emission_from_wetland_biological_production", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Grid averaged methane production (methanogenesis) from wetlands", - "comment": "", + "long_name": "Grid Averaged Methane Production (Methanogenesis) from Wetlands", + "comment": "Biological emissions (methanogenesis) of methane (NH4) from wetlands (areas where water covers the soil, or is present either at or near the surface of the soil all year or for varying periods of time during the year, including during the growing season). ", "dimensions": "longitude latitude time", "out_name": "wetlandCH4prod", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5965,16 +5883,35 @@ "ok_max_mean_abs": "" }, "wetlandFrac": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "wetland_fraction", + "standard_name": "area_fraction", "units": "%", "cell_methods": "area: mean where land over all_area_types time: mean", "cell_measures": "area: areacella", - "long_name": "Fraction of a grid cell covered by wetland.", - "comment": "Report only one year if specified fraction is used, or time series if values are determined dynamically.", + "long_name": "Wetland Percentage Cover", + "comment": "Percentage of grid cell covered by wetland. Report only one year if fixed percentage is used, or time series if values are determined dynamically.", "dimensions": "longitude latitude time typewetla", "out_name": "wetlandFrac", - "type": "", + "type": "real", + "positive": "", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, + "wtd": { + "frequency": "mon", + "modeling_realm": "land", + "standard_name": "water_table_depth", + "units": "m", + "cell_methods": "area: mean where land time: mean", + "cell_measures": "area: areacellr", + "long_name": "Water Table Depth", + "comment": "Depth is the vertical distance below the surface. The water table is the surface below which the soil is saturated with water such that all pore spaces are filled.", + "dimensions": "longitude latitude time", + "out_name": "wtd", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5982,16 +5919,17 @@ "ok_max_mean_abs": "" }, "xgwdparam": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "atmosphere_eastward_stress_due_to_gravity_wave_drag", "units": "Pa", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "x_gravity_wave_drag_param", + "long_name": "Eastward Gravity Wave Drag", "comment": "Parameterised x-component of gravity wave drag", "dimensions": "longitude latitude alevel time", "out_name": "xgwdparam", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -5999,16 +5937,17 @@ "ok_max_mean_abs": "" }, "ygwdparam": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "atmosphere_northward_stress_due_to_gravity_wave_drag", "units": "Pa", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "y_gravity_wave_drag_param", + "long_name": "Northward Gravity Wave Drag", "comment": "Parameterised y- component of gravity wave drag", "dimensions": "longitude latitude alevel time", "out_name": "ygwdparam", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -6016,67 +5955,17 @@ "ok_max_mean_abs": "" }, "zg27": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "geopotential_height", "units": "m", "cell_methods": "time: mean", "cell_measures": "area: areacella", "long_name": "Geopotential Height", - "comment": "", + "comment": "Geopotential is the sum of the specific gravitational potential energy relative to the geoid and the specific centripetal potential energy. Geopotential height is the geopotential divided by the standard acceleration due to gravity. It is numerically similar to the altitude (or geometric height) and not to the quantity with standard name height, which is relative to the surface.", "dimensions": "longitude latitude plev27 time", "out_name": "zg", - "type": "float", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "zoomeso": { - "modeling_realm": "ocean", - "standard_name": "mole_concentration_of_mesozooplankton_expressed_as_carbon_in_sea_water", - "units": "mol m-3", - "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello volume: volcello", - "long_name": "Mole Concentration of Mesozooplankton expressed as Carbon in Sea Water", - "comment": "carbon concentration from mesozooplankton (20-200 um) component alone", - "dimensions": "longitude latitude olevel time", - "out_name": "zoomeso", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "zoomicro": { - "modeling_realm": "ocean", - "standard_name": "mole_concentration_of_microzooplankton_expressed_as_carbon_in_sea_water", - "units": "mol m-3", - "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello volume: volcello", - "long_name": "Mole Concentration of Microzooplankton expressed as Carbon in Sea Water", - "comment": "carbon concentration from the microzooplankton (<20 um) component alone", - "dimensions": "longitude latitude olevel time", - "out_name": "zoomicro", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "zoomisc": { - "modeling_realm": "ocean", - "standard_name": "mole_concentration_of_miscellaneous_zooplankton_expressed_as_carbon_in_sea_water", - "units": "mol m-3", - "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello volume: volcello", - "long_name": "Other Zooplankton Carbon Concentration", - "comment": "carbon from additional zooplankton component concentrations alone (e.g. Micro, meso). Since the models all have different numbers of components, this variable has been included to provide a check for intercomparison between models since some phytoplankton groups are supersets.", - "dimensions": "longitude latitude olevel time", - "out_name": "zoomisc", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_EmonZ.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_EmonZ.json index f81692549b..231c86cd0a 100644 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_EmonZ.json +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_EmonZ.json @@ -1,47 +1,31 @@ { "Header": { - "data_specs_version": "01.00.10", + "data_specs_version": "01.00.30", + "cmor_version": "3.4", "table_id": "Table EmonZ", "realm": "atmos", - "frequency": "mon", - "cmor_version": "3.2", - "table_date": "10 May 2017", + "table_date": "11 March 2019", "missing_value": "1e20", + "int_missing_value": "-999", "product": "model-output", "approx_interval": "30.00000", "generic_levels": "alevel olevel", "mip_era": "CMIP6", - "Conventions": "CF-1.7 CMIP-6.0" + "Conventions": "CF-1.7 CMIP-6.2" }, "variable_entry": { - "co2totalmass": { - "modeling_realm": "atmos", - "standard_name": "CO2_total_mass_in_atmos", - "units": "kg", - "cell_methods": "area: time: mean", - "cell_measures": "", - "long_name": "Globally integrated Carbon Mass in Atmosphere", - "comment": "globally integrated mass of carbon as CO2 in atmsophere. Report as a single number for all emissions-driven runs", - "dimensions": "time", - "out_name": "co2totalmass", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, "epfy": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "northward_eliassen_palm_flux_in_air", "units": "m3 s-2", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", + "cell_measures": "", "long_name": "Northward Component of the Eliassen-Palm Flux", "comment": "Transformed Eulerian Mean Diagnostics Meridional component Fy of Eliassen-Palm (EP) flux (Fy, Fz) derived from 6hr or higher frequency fields (use daily fields or 12 hr fields if the 6 hr are not available). Please use the definitions given by equation 3.5.3a of Andrews, Holton and Leovy text book, but scaled by density to have units m3 s-2.", "dimensions": "latitude plev39 time", "out_name": "epfy", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -49,33 +33,35 @@ "ok_max_mean_abs": "" }, "epfz": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "upward_eliassen_palm_flux_in_air", "units": "m3 s-2", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", + "cell_measures": "", "long_name": "Upward Component of the Eliassen-Palm Flux", "comment": "Transformed Eulerian Mean Diagnostics Meridional component Fz of the Eliassen-Palm (EP) flux (Fy, Fz) derived from 6hr or higher frequency fields (use daily fields or 12 hr fields if the 6 hr are not available). Please use the definitions given by equation 3.5.3b of Andrews, Holton and Leovy text book, but scaled by density to have units m3 s-2.", "dimensions": "latitude plev39 time", "out_name": "epfz", - "type": "", - "positive": "", + "type": "real", + "positive": "up", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "jo2": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "photolysis_rate_of_molecular_oxygen", "units": "s-1", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", - "long_name": "photoloysis rate of O2", - "comment": "rate of o2 -> o1d+o", + "cell_measures": "", + "long_name": "Photolysis Rate of Diatomic Molecular Oxygen", + "comment": "Rate of photolysis of molecular oxygen to atomic oxygen (o2 -> o1d+o)", "dimensions": "latitude plev39 time", "out_name": "jo2", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -83,16 +69,17 @@ "ok_max_mean_abs": "" }, "jo3": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "photolysis_rate_of_ozone", "units": "s-1", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", - "long_name": "photoloysis rate of O3", - "comment": "sum of rates o3 -> o1d+o2 and o3 -> o+o2", + "cell_measures": "", + "long_name": "Photolysis Rate of Ozone (O3)", + "comment": "Sum of photolysis rates o3 -> o1d+o2 and o3 -> o+o2", "dimensions": "latitude plev39 time", "out_name": "jo3", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -100,16 +87,17 @@ "ok_max_mean_abs": "" }, "oxloss": { + "frequency": "mon", "modeling_realm": "atmosChem", - "standard_name": "tendency_of_mole_concentration_of_ozone_and_atomic_oxygen_and_1D_oxygen_atom_due_to_chemical_destruction", + "standard_name": "tendency_of_mole_concentration_of_ox_in_air_due_to_chemical_destruction", "units": "mol m-3 s-1", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", - "long_name": "total Ox loss rate", + "cell_measures": "", + "long_name": "Total Odd Oxygen (Ox) Loss Rate", "comment": "total chemical loss rate for o+o1d+o3", "dimensions": "latitude plev39 time", "out_name": "oxloss", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -117,16 +105,17 @@ "ok_max_mean_abs": "" }, "oxprod": { + "frequency": "mon", "modeling_realm": "atmosChem", - "standard_name": "tendency_of_mole_concentration_of_ozone_and_atomic_oxygen_and_1D_oxygen_atom_due_to_chemical_production_and_photolysis", + "standard_name": "tendency_of_mole_concentration_of_ox_in_air_due_to_chemical_and_photolytic_production", "units": "mol m-3 s-1", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", - "long_name": "total Ox production rate", + "cell_measures": "", + "long_name": "Total Odd Oxygen (Ox) Production Rate", "comment": "total production rate of o+o1d+o3 including o2 photolysis and all o3 producing reactions", "dimensions": "latitude plev39 time", "out_name": "oxprod", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -134,50 +123,17 @@ "ok_max_mean_abs": "" }, "sltbasin": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "northward_ocean_salt_transport", "units": "kg s-1", - "cell_methods": "longitude: mean (basin) time: mean", - "cell_measures": "area: areacella", + "cell_methods": "longitude: sum (comment: basin sum [along zig-zag grid path]) depth: sum time: mean", + "cell_measures": "", "long_name": "Northward Ocean Salt Transport", "comment": "function of latitude, basin", "dimensions": "latitude basin time", "out_name": "sltbasin", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "sltnorth": { - "modeling_realm": "ocean", - "standard_name": "northward_ocean_salt_transport", - "units": "kg s-1", - "cell_methods": "longitude: mean (basin) time: mean", - "cell_measures": "area: areacella", - "long_name": "Northward Ocean Salt Transport", - "comment": "", - "dimensions": "latitude basin time", - "out_name": "sltnorth", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "sltnortha": { - "modeling_realm": "ocean", - "standard_name": "northward_ocean_salt_transport", - "units": "kg s-1", - "cell_methods": "longitude: mean (basin) time: mean", - "cell_measures": "area: areacella", - "long_name": "Atlantic Northward Ocean Salt Transport", - "comment": "", - "dimensions": "latitude basin time", - "out_name": "sltnortha", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -185,12 +141,13 @@ "ok_max_mean_abs": "" }, "tntc": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "tendency_of_air_temperature_due_to_convection", "units": "K s-1", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", - "long_name": "Tendency of Air Temperature due to Convection", + "cell_measures": "", + "long_name": "Tendency of Air Temperature Due to Convection", "comment": "Tendencies from cumulus convection scheme.", "dimensions": "latitude plev39 time", "out_name": "tntc", @@ -202,12 +159,13 @@ "ok_max_mean_abs": "" }, "tntmp": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "tendency_of_air_temperature_due_to_model_physics", "units": "K s-1", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", - "long_name": "Tendency of Air Temperature due to Model Physics", + "cell_measures": "", + "long_name": "Tendency of Air Temperature Due to Model Physics", "comment": "Tendency of air temperature due to model physics. This includes sources and sinks from parametrized physics (e.g. radiation, convection, boundary layer, stratiform condensation/evaporation, etc.). It excludes sources and sinks from resolved dynamics and numerical diffusion not associated with parametrized physics. For example, any vertical diffusion which is part of the boundary layer mixing scheme should be included, while numerical diffusion applied in addition to physics or resolved dynamics should be excluded. This term is required to check the closure of the heat budget.", "dimensions": "latitude plev39 time", "out_name": "tntmp", @@ -219,16 +177,17 @@ "ok_max_mean_abs": "" }, "tntnogw": { + "frequency": "mon", "modeling_realm": "atmos", - "standard_name": "temperature_tendency_due_to_dissipation_nonorographic_gravity_wave_drag", + "standard_name": "tendency_of_air_temperature_due_to_dissipation_of_nonorographic_gravity_waves", "units": "K s-1", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", - "long_name": "temperature tendency nonorographic gravity wave dissipation", + "cell_measures": "", + "long_name": "Temperature Tendency Due to Non-Orographic Gravity Wave Dissipation", "comment": "Temperature tendency due to dissipation of parameterized nonorographic gravity waves.", "dimensions": "latitude plev39 time", "out_name": "tntnogw", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -236,16 +195,17 @@ "ok_max_mean_abs": "" }, "tntogw": { + "frequency": "mon", "modeling_realm": "atmos", - "standard_name": "temperature_tendency_due_to_dissipation_orographic_gravity_wave_drag", + "standard_name": "tendency_of_air_temperature_due_to_dissipation_of_orographic_gravity_waves", "units": "K s-1", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", - "long_name": "temperature tendency orographic gravity wave dissipation", + "cell_measures": "", + "long_name": "Temperature Tendency Due to Orographic Gravity Wave Dissipation", "comment": "Temperature tendency due to dissipation of parameterized orographic gravity waves.", "dimensions": "latitude plev39 time", "out_name": "tntogw", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -253,16 +213,17 @@ "ok_max_mean_abs": "" }, "tntrl": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "tendency_of_air_temperature_due_to_longwave_heating", "units": "K s-1", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", - "long_name": "Longwave heating rate", + "cell_measures": "", + "long_name": "Tendency of Air Temperature Due to Longwave Radiative Heating", "comment": "Tendency of air temperature due to longwave radiative heating", "dimensions": "latitude plev39 time", "out_name": "tntrl", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -270,16 +231,17 @@ "ok_max_mean_abs": "" }, "tntrlcs": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "tendency_of_air_temperature_due_to_longwave_heating_assuming_clear_sky", "units": "K s-1", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", - "long_name": "Tendency of Air Temperature due to Clear Sky Longwave Radiative Heating", + "cell_measures": "", + "long_name": "Tendency of Air Temperature Due to Clear Sky Longwave Radiative Heating", "comment": "Tendency of Air Temperature due to Clear Sky Longwave Radiative Heating", "dimensions": "latitude plev39 time", "out_name": "tntrlcs", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -287,16 +249,17 @@ "ok_max_mean_abs": "" }, "tntrs": { + "frequency": "mon", "modeling_realm": "aerosol", "standard_name": "tendency_of_air_temperature_due_to_shortwave_heating", "units": "K s-1", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", - "long_name": "Shortwave heating rate", + "cell_measures": "", + "long_name": "Tendency of Air Temperature Due to Shortwave Radiative Heating", "comment": "Tendency of air temperature due to shortwave radiative heating", "dimensions": "latitude plev39 time", "out_name": "tntrs", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -304,16 +267,17 @@ "ok_max_mean_abs": "" }, "tntrscs": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "tendency_of_air_temperature_due_to_shortwave_heating_assuming_clear_sky", "units": "K s-1", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", - "long_name": "Tendency of Air Temperature due to Clear Sky Shortwave Radiative Heating", + "cell_measures": "", + "long_name": "Tendency of Air Temperature Due to Clear Sky Shortwave Radiative Heating", "comment": "Tendency of Air Temperature due to Clear Sky Shortwave Radiative Heating", "dimensions": "latitude plev39 time", "out_name": "tntrscs", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -321,16 +285,17 @@ "ok_max_mean_abs": "" }, "tntscp": { + "frequency": "mon", "modeling_realm": "atmos", - "standard_name": "tendency_of_air_temperature_due_to_stratiform_clouds_and_precipitation", + "standard_name": "tendency_of_air_temperature_due_to_stratiform_cloud_and_precipitation", "units": "K s-1", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", + "cell_measures": "", "long_name": "Tendency of Air Temperature Due to Stratiform Clouds and Precipitation", - "comment": "", + "comment": "The phrase 'tendency_of_X' means derivative of X with respect to time. Air temperature is the bulk temperature of the air, not the surface (skin) temperature. The specification of a physical process by the phrase 'due_to_' process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. A variable with the standard name tendency_of_air_temperature_due_to_stratiform_cloud_and_precipitation should contain net latent heating effects of all processes which convert stratiform clouds and precipitation between water vapour, liquid or ice phases. In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes).", "dimensions": "latitude plev39 time", "out_name": "tntscp", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -338,16 +303,17 @@ "ok_max_mean_abs": "" }, "utendepfd": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "tendency_of_eastward_wind_due_to_eliassen_palm_flux_divergence", "units": "m s-2", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", - "long_name": "Tendency of eastward wind due to Eliassen-Palm Flux divergence", + "cell_measures": "", + "long_name": "Tendency of Eastward Wind Due to Eliassen-Palm Flux Divergence", "comment": "Tendency of the zonal mean zonal wind due to the divergence of the Eliassen-Palm flux.", "dimensions": "latitude plev39 time", "out_name": "utendepfd", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -355,16 +321,17 @@ "ok_max_mean_abs": "" }, "utendnogw": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "tendency_of_eastward_wind_due_to_nonorographic_gravity_wave_drag", "units": "m s-2", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", - "long_name": "u-tendency nonorographic gravity wave drag", + "cell_measures": "", + "long_name": "Eastward Acceleration Due to Non-Orographic Gravity Wave Drag", "comment": "Tendency of the eastward wind by parameterized nonorographic gravity waves.", "dimensions": "latitude plev39 time", "out_name": "utendnogw", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -372,16 +339,17 @@ "ok_max_mean_abs": "" }, "vmrox": { + "frequency": "mon", "modeling_realm": "atmosChem", - "standard_name": "mole_fraction_of_ozone_and_atomic_oxygen_and_1D_oxygen_atom", + "standard_name": "mole_fraction_of_ox_in_air", "units": "mol mol-1", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", - "long_name": "mole fraction of o and o3 and o1d", + "cell_measures": "", + "long_name": "Mole Fraction of Odd Oxygen (O, O3 and O1D)", "comment": "Mole Fraction of Ox", "dimensions": "latitude plev39 time", "out_name": "vmrox", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -389,16 +357,17 @@ "ok_max_mean_abs": "" }, "vtem": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "northward_transformed_eulerian_mean_air_velocity", "units": "m s-1", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", - "long_name": "Transformed Eulerian Mean northward wind", + "cell_measures": "", + "long_name": "Transformed Eulerian Mean Northward Wind", "comment": "Transformed Eulerian Mean Diagnostics v*, meridional component of the residual meridional circulation (v*, w*) derived from 6 hr or higher frequency data fields (use instantaneous daily fields or 12 hr fields if the 6 hr data are not available).", "dimensions": "latitude plev39 time", "out_name": "vtem", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -406,16 +375,17 @@ "ok_max_mean_abs": "" }, "vtendnogw": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "tendency_of_northward_wind_due_to_nonorographic_gravity_wave_drag", "units": "m s-2", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", - "long_name": "v-tendency nonorographic gravity wave drag", + "cell_measures": "", + "long_name": "Northward Acceleration Due to Non-Orographic Gravity Wave Drag", "comment": "Tendency of the northward wind by parameterized nonorographic gravity waves. (Note that CF name tables only have a general northward tendency for all gravity waves, and we need it separated by type.)", "dimensions": "latitude plev39 time", "out_name": "vtendnogw", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -423,16 +393,17 @@ "ok_max_mean_abs": "" }, "wtem": { + "frequency": "mon", "modeling_realm": "atmos", - "standard_name": "unset", + "standard_name": "upward_transformed_eulerian_mean_air_velocity", "units": "m s-1", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", - "long_name": "Transformed Eulerian Mean upward wind", + "cell_measures": "", + "long_name": "Transformed Eulerian Mean Upward Wind", "comment": "Transformed Eulerian Mean Diagnostics w*, meridional component of the residual meridional circulation (v*, w*) derived from 6 hr or higher frequency data fields (use instantaneous daily fields or 12 hr fields if the 6 hr data are not available). Scale height: 6950 m", "dimensions": "latitude plev39 time", "out_name": "wtem", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -440,16 +411,17 @@ "ok_max_mean_abs": "" }, "xgwdparam": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "atmosphere_eastward_stress_due_to_gravity_wave_drag", "units": "Pa", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", - "long_name": "x_gravity_wave_drag_param", + "cell_measures": "", + "long_name": "Eastward Gravity Wave Drag", "comment": "Parameterised x-component of gravity wave drag", "dimensions": "latitude plev39 time", "out_name": "xgwdparam", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -457,16 +429,17 @@ "ok_max_mean_abs": "" }, "ygwdparam": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "atmosphere_northward_stress_due_to_gravity_wave_drag", "units": "Pa", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", - "long_name": "y_gravity_wave_drag_param", + "cell_measures": "", + "long_name": "Northward Gravity Wave Drag", "comment": "Parameterised y- component of gravity wave drag", "dimensions": "latitude plev39 time", "out_name": "ygwdparam", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -474,16 +447,17 @@ "ok_max_mean_abs": "" }, "zmtnt": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "tendency_of_air_temperature_due_to_diabatic_processes", "units": "K s-1", "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", + "cell_measures": "", "long_name": "Zonal Mean Diabatic Heating Rates", "comment": "The diabatic heating rates due to all the processes that may change potential temperature", "dimensions": "latitude plev39 time", "out_name": "zmtnt", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Esubhr.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Esubhr.json index 4f6338ebda..ad826380c4 100644 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Esubhr.json +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Esubhr.json @@ -1,20 +1,23 @@ { "Header": { - "data_specs_version": "01.00.10", + "data_specs_version": "01.00.30", + "cmor_version": "3.4", "table_id": "Table Esubhr", "realm": "atmos", - "frequency": "subhr", - "cmor_version": "3.2", - "table_date": "10 May 2017", + "table_date": "11 March 2019", "missing_value": "1e20", + "int_missing_value": "-999", "product": "model-output", "approx_interval": "0.017361", - "generic_levels": "alevel", + "approx_interval_error": "0.90", + "approx_interval_warning": "0.5", + "generic_levels": "alevel alevhalf", "mip_era": "CMIP6", - "Conventions": "CF-1.7 CMIP-6.0" + "Conventions": "CF-1.7 CMIP-6.2" }, "variable_entry": { "bldep": { + "frequency": "subhrPt", "modeling_realm": "aerosol", "standard_name": "atmosphere_boundary_layer_thickness", "units": "m", @@ -24,7 +27,7 @@ "comment": "Boundary layer depth", "dimensions": "longitude latitude time1", "out_name": "bldep", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -32,13 +35,14 @@ "ok_max_mean_abs": "" }, "hfls": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "surface_upward_latent_heat_flux", "units": "W m-2", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", "long_name": "Surface Upward Latent Heat Flux", - "comment": "", + "comment": "The surface called 'surface' means the lower boundary of the atmosphere. 'Upward' indicates a vector component which is positive when directed upward (negative downward). The surface latent heat flux is the exchange of heat between the surface and the air on account of evaporation (including sublimation). In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions": "longitude latitude time1", "out_name": "hfls", "type": "real", @@ -49,13 +53,14 @@ "ok_max_mean_abs": "" }, "hfss": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "surface_upward_sensible_heat_flux", "units": "W m-2", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", "long_name": "Surface Upward Sensible Heat Flux", - "comment": "", + "comment": "The surface sensible heat flux, also called turbulent heat flux, is the exchange of heat between the surface and the air by motion of air.", "dimensions": "longitude latitude time1", "out_name": "hfss", "type": "real", @@ -66,16 +71,17 @@ "ok_max_mean_abs": "" }, "hus": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "specific_humidity", - "units": "1.0", + "units": "1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", "long_name": "Specific Humidity", - "comment": "", + "comment": "Specific humidity is the mass fraction of water vapor in (moist) air.", "dimensions": "longitude latitude alevel time1", "out_name": "hus", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -83,9 +89,10 @@ "ok_max_mean_abs": "" }, "huss": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "specific_humidity", - "units": "1.0", + "units": "1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", "long_name": "Near-Surface Specific Humidity", @@ -100,6 +107,7 @@ "ok_max_mean_abs": "" }, "mc": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "atmosphere_net_upward_convective_mass_flux", "units": "kg m-2 s-1", @@ -117,6 +125,7 @@ "ok_max_mean_abs": "" }, "pr": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "precipitation_flux", "units": "kg m-2 s-1", @@ -126,7 +135,7 @@ "comment": "includes both liquid and solid phases", "dimensions": "longitude latitude time1", "out_name": "pr", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -134,6 +143,7 @@ "ok_max_mean_abs": "" }, "prc": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "convective_precipitation_flux", "units": "kg m-2 s-1", @@ -151,8 +161,9 @@ "ok_max_mean_abs": "" }, "prw": { + "frequency": "subhrPt", "modeling_realm": "atmos", - "standard_name": "atmosphere_water_vapor_content", + "standard_name": "atmosphere_mass_content_of_water_vapor", "units": "kg m-2", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", @@ -168,16 +179,17 @@ "ok_max_mean_abs": "" }, "ps": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "surface_air_pressure", "units": "Pa", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "Surface Pressure", + "long_name": "Surface Air Pressure", "comment": "surface pressure (not mean sea-level pressure), 2-D field to calculate the 3-D pressure field from hybrid coordinates", "dimensions": "longitude latitude time1", "out_name": "ps", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -185,6 +197,7 @@ "ok_max_mean_abs": "" }, "reffclic": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "effective_radius_of_convective_cloud_ice_particle", "units": "m", @@ -202,6 +215,7 @@ "ok_max_mean_abs": "" }, "reffclis": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "effective_radius_of_stratiform_cloud_ice_particle", "units": "m", @@ -219,12 +233,13 @@ "ok_max_mean_abs": "" }, "reffclwc": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "effective_radius_of_convective_cloud_liquid_water_particle", "units": "m", "cell_methods": "area: point time: point", "cell_measures": "", - "long_name": "Hydrometeor Effective Radius of Convective Cloud Liquid Water", + "long_name": "Convective Cloud Liquid Droplet Effective Radius", "comment": "Droplets are liquid. The effective radius is defined as the ratio of the third moment over the second moment of the particle size distribution and the time-mean should be calculated, weighting the individual samples by the cloudy fraction of the grid cell.", "dimensions": "alevel site time1", "out_name": "reffclwc", @@ -236,12 +251,13 @@ "ok_max_mean_abs": "" }, "reffclws": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "effective_radius_of_stratiform_cloud_liquid_water_particle", "units": "m", "cell_methods": "area: point time: point", "cell_measures": "", - "long_name": "Hydrometeor Effective Radius of Stratiform Cloud Liquid Water", + "long_name": "Stratiform Cloud Liquid Droplet Effective Radius", "comment": "Droplets are liquid. The effective radius is defined as the ratio of the third moment over the second moment of the particle size distribution and the time-mean should be calculated, weighting the individual samples by the cloudy fraction of the grid cell.", "dimensions": "alevel site time1", "out_name": "reffclws", @@ -253,16 +269,17 @@ "ok_max_mean_abs": "" }, "rlut": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "toa_outgoing_longwave_flux", "units": "W m-2", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "TOA Outgoing Longwave Radiatio", + "long_name": "TOA Outgoing Longwave Radiation", "comment": "at the top of the atmosphere (to be compared with satellite measurements)", "dimensions": "longitude latitude time1", "out_name": "rlut", - "type": "", + "type": "real", "positive": "up", "valid_min": "", "valid_max": "", @@ -270,6 +287,7 @@ "ok_max_mean_abs": "" }, "rsdt": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "toa_incoming_shortwave_flux", "units": "W m-2", @@ -287,16 +305,17 @@ "ok_max_mean_abs": "" }, "rsut": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "toa_outgoing_shortwave_flux", "units": "W m-2", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "Top-of-Atmosphere Outgoing Shortwave Radiation", + "long_name": "TOA Outgoing Shortwave Radiation", "comment": "at the top of the atmosphere", "dimensions": "longitude latitude time1", "out_name": "rsut", - "type": "", + "type": "real", "positive": "up", "valid_min": "", "valid_max": "", @@ -304,6 +323,7 @@ "ok_max_mean_abs": "" }, "ta": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "air_temperature", "units": "K", @@ -313,7 +333,7 @@ "comment": "Air Temperature", "dimensions": "longitude latitude alevel time1", "out_name": "ta", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -321,16 +341,17 @@ "ok_max_mean_abs": "" }, "tas": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "air_temperature", "units": "K", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "Surface Air Temperature", + "long_name": "Near-Surface Air Temperature", "comment": "near-surface (usually, 2 meter) air temperature", "dimensions": "longitude latitude time1 height2m", "out_name": "tas", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -338,6 +359,7 @@ "ok_max_mean_abs": "" }, "tnhus": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "tendency_of_specific_humidity", "units": "s-1", @@ -355,6 +377,7 @@ "ok_max_mean_abs": "" }, "tnhuspbl": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "tendency_of_specific_humidity_due_to_boundary_layer_mixing", "units": "s-1", @@ -364,7 +387,7 @@ "comment": "Includes all boundary layer terms including diffusive terms.", "dimensions": "alevel site time1", "out_name": "tnhuspbl", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -372,16 +395,17 @@ "ok_max_mean_abs": "" }, "tnhusscp": { + "frequency": "subhrPt", "modeling_realm": "atmos", - "standard_name": "tendency_of_specific_humidity_due_to_stratiform_clouds_and_precipitation", + "standard_name": "tendency_of_specific_humidity_due_to_stratiform_cloud_and_precipitation", "units": "s-1", "cell_methods": "area: point time: point", "cell_measures": "", "long_name": "Tendency of Specific Humidity Due to Stratiform Clouds and Precipitation", - "comment": "", + "comment": "The phrase 'tendency_of_X' means derivative of X with respect to time. 'Specific' means per unit mass. Specific humidity is the mass fraction of water vapor in (moist) air. The specification of a physical process by the phrase 'due_to_' process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. A variable with the standard name of tendency_of_specific_humidity_due_to_stratiform_cloud_and_precipitation should contain the effects of all processes which convert stratiform clouds and precipitation to or from water vapor. In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes).", "dimensions": "alevel site time1", "out_name": "tnhusscp", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -389,6 +413,7 @@ "ok_max_mean_abs": "" }, "tnt": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "tendency_of_air_temperature", "units": "K s-1", @@ -406,16 +431,17 @@ "ok_max_mean_abs": "" }, "tntd": { + "frequency": "subhrPt", "modeling_realm": "atmos", - "standard_name": "tendency_of_air_temperature_due_to_numerical_diffusion", + "standard_name": "tendency_of_air_temperature_due_to_diffusion", "units": "K s-1", "cell_methods": "area: point time: point", "cell_measures": "", - "long_name": "Tendency of Air Temperature due to Numerical Diffusion", + "long_name": "Tendency of Air Temperature Due to Numerical Diffusion", "comment": "This includes any horizontal or vertical numerical temperature diffusion not associated with the parametrized moist physics or the resolved dynamics. For example, any vertical diffusion which is part of the boundary layer mixing scheme should be excluded, as should any diffusion which is included in the terms from the resolved dynamics. This term is required to check the closure of the temperature budget.", "dimensions": "alevel site time1", "out_name": "tntd", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -423,6 +449,7 @@ "ok_max_mean_abs": "" }, "tntpbl": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "tendency_of_air_temperature_due_to_boundary_layer_mixing", "units": "K s-1", @@ -432,7 +459,7 @@ "comment": "Includes all boundary layer terms including diffusive terms.", "dimensions": "alevel site time1", "out_name": "tntpbl", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -440,16 +467,17 @@ "ok_max_mean_abs": "" }, "tntrl": { + "frequency": "subhrPt", "modeling_realm": "aerosol", "standard_name": "tendency_of_air_temperature_due_to_longwave_heating", "units": "K s-1", "cell_methods": "area: point time: point", "cell_measures": "", - "long_name": "Longwave heating rate", + "long_name": "Tendency of Air Temperature Due to Longwave Radiative Heating", "comment": "Tendency of air temperature due to longwave radiative heating", "dimensions": "alevel site time1", "out_name": "tntrl", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -457,16 +485,17 @@ "ok_max_mean_abs": "" }, "tntrlcs": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "tendency_of_air_temperature_due_to_longwave_heating_assuming_clear_sky", "units": "K s-1", "cell_methods": "area: point time: point", "cell_measures": "", - "long_name": "Tendency of Air Temperature due to Clear Sky Longwave Radiative Heating", + "long_name": "Tendency of Air Temperature Due to Clear Sky Longwave Radiative Heating", "comment": "Tendency of Air Temperature due to Clear Sky Longwave Radiative Heating", "dimensions": "alevel site time1", "out_name": "tntrlcs", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -474,16 +503,17 @@ "ok_max_mean_abs": "" }, "tntrs": { + "frequency": "subhrPt", "modeling_realm": "aerosol", "standard_name": "tendency_of_air_temperature_due_to_shortwave_heating", "units": "K s-1", "cell_methods": "area: point time: point", "cell_measures": "", - "long_name": "Shortwave heating rate", + "long_name": "Tendency of Air Temperature Due to Shortwave Radiative Heating", "comment": "Tendency of air temperature due to shortwave radiative heating", "dimensions": "alevel site time1", "out_name": "tntrs", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -491,16 +521,17 @@ "ok_max_mean_abs": "" }, "tntrscs": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "tendency_of_air_temperature_due_to_shortwave_heating_assuming_clear_sky", "units": "K s-1", "cell_methods": "area: point time: point", "cell_measures": "", - "long_name": "Tendency of Air Temperature due to Clear Sky Shortwave Radiative Heating", + "long_name": "Tendency of Air Temperature Due to Clear Sky Shortwave Radiative Heating", "comment": "Tendency of Air Temperature due to Clear Sky Shortwave Radiative Heating", "dimensions": "alevel site time1", "out_name": "tntrscs", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -508,16 +539,17 @@ "ok_max_mean_abs": "" }, "tntscp": { + "frequency": "subhrPt", "modeling_realm": "atmos", - "standard_name": "tendency_of_air_temperature_due_to_stratiform_clouds_and_precipitation", + "standard_name": "tendency_of_air_temperature_due_to_stratiform_cloud_and_precipitation", "units": "K s-1", "cell_methods": "area: point time: point", "cell_measures": "", "long_name": "Tendency of Air Temperature Due to Stratiform Clouds and Precipitation", - "comment": "", + "comment": "The phrase 'tendency_of_X' means derivative of X with respect to time. Air temperature is the bulk temperature of the air, not the surface (skin) temperature. The specification of a physical process by the phrase 'due_to_' process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. A variable with the standard name tendency_of_air_temperature_due_to_stratiform_cloud_and_precipitation should contain net latent heating effects of all processes which convert stratiform clouds and precipitation between water vapour, liquid or ice phases. In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes).", "dimensions": "alevel site time1", "out_name": "tntscp", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -525,16 +557,17 @@ "ok_max_mean_abs": "" }, "ua": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "eastward_wind", "units": "m s-1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", "long_name": "Eastward Wind", - "comment": "", + "comment": "Zonal wind (positive in a eastward direction).", "dimensions": "longitude latitude alevel time1", "out_name": "ua", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -542,16 +575,17 @@ "ok_max_mean_abs": "" }, "va": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "northward_wind", "units": "m s-1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", "long_name": "Northward Wind", - "comment": "", + "comment": "Meridional wind (positive in a northward direction).", "dimensions": "longitude latitude alevel time1", "out_name": "va", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -559,12 +593,13 @@ "ok_max_mean_abs": "" }, "wap": { + "frequency": "subhrPt", "modeling_realm": "atmos", "standard_name": "lagrangian_tendency_of_air_pressure", "units": "Pa s-1", "cell_methods": "area: mean time: point", "cell_measures": "area: areacella", - "long_name": "omega (=dp/dt)", + "long_name": "Omega (=dp/dt)", "comment": "Omega (vertical velocity in pressure coordinates, positive downwards)", "dimensions": "longitude latitude alevel time1", "out_name": "wap", diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Eyr.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Eyr.json index 26ca84d71a..ee47c42cfb 100644 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Eyr.json +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Eyr.json @@ -1,26 +1,27 @@ { "Header": { - "data_specs_version": "01.00.10", + "data_specs_version": "01.00.30", + "cmor_version": "3.4", "table_id": "Table Eyr", "realm": "land", - "frequency": "yr", - "cmor_version": "3.2", - "table_date": "10 May 2017", + "table_date": "11 March 2019", "missing_value": "1e20", + "int_missing_value": "-999", "product": "model-output", "approx_interval": "365", "generic_levels": "alevel olevel", "mip_era": "CMIP6", - "Conventions": "CF-1.7 CMIP-6.0" + "Conventions": "CF-1.7 CMIP-6.2" }, "variable_entry": { "baresoilFrac": { + "frequency": "yr", "modeling_realm": "land", "standard_name": "area_fraction", "units": "%", "cell_methods": "area: mean where land over all_area_types time: mean", "cell_measures": "area: areacella", - "long_name": "Bare Soil Fraction", + "long_name": "Bare Soil Percentage Area Coverage", "comment": "Percentage of entire grid cell that is covered by bare soil.", "dimensions": "longitude latitude time typebare", "out_name": "baresoilFrac", @@ -32,13 +33,14 @@ "ok_max_mean_abs": "" }, "cLitter": { + "frequency": "yrPt", "modeling_realm": "land", - "standard_name": "litter_carbon_content", + "standard_name": "litter_mass_content_of_carbon", "units": "kg m-2", "cell_methods": "area: mean where land time: point", "cell_measures": "area: areacella", "long_name": "Carbon Mass in Litter Pool", - "comment": "", + "comment": "'Litter' is dead plant material in or above the soil. It is distinct from coarse wood debris. The precise distinction between 'fine' and 'coarse' is model dependent. 'Content' indicates a quantity per unit area. The sum of the quantities with standard names surface_litter_mass_content_of_carbon and subsurface_litter_mass_content_of_carbon has the standard name litter_mass_content_of_carbon.", "dimensions": "longitude latitude time1", "out_name": "cLitter", "type": "real", @@ -49,16 +51,17 @@ "ok_max_mean_abs": "" }, "cLitterLut": { + "frequency": "yrPt", "modeling_realm": "land", - "standard_name": "litter_carbon_content", + "standard_name": "litter_mass_content_of_carbon", "units": "kg m-2", - "cell_methods": "area: mean where landuse time: point", + "cell_methods": "area: mean where sector time: point", "cell_measures": "area: areacella", - "long_name": "carbon in above and belowground litter pools on land use tiles", + "long_name": "Carbon in Above and Below-Ground Litter Pools on Land-Use Tiles", "comment": "end of year values (not annual mean)", "dimensions": "longitude latitude landUse time1", "out_name": "cLitterLut", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -66,13 +69,14 @@ "ok_max_mean_abs": "" }, "cProduct": { + "frequency": "yrPt", "modeling_realm": "land", - "standard_name": "carbon_content_of_products_of_anthropogenic_land_use_change", + "standard_name": "carbon_mass_content_of_forestry_and_agricultural_products", "units": "kg m-2", "cell_methods": "area: mean where land time: point", "cell_measures": "area: areacella", - "long_name": "Carbon Mass in Products of Land Use Change", - "comment": "Carbon mass per unit area in that has been removed from the environment through landuse change.", + "long_name": "Carbon Mass in Products of Land-Use Change", + "comment": "Carbon mass per unit area in that has been removed from the environment through land use change.", "dimensions": "longitude latitude time1", "out_name": "cProduct", "type": "real", @@ -83,16 +87,17 @@ "ok_max_mean_abs": "" }, "cProductLut": { + "frequency": "yrPt", "modeling_realm": "land", - "standard_name": "carbon_content_in_wood_and_agricultural_products", + "standard_name": "carbon_mass_content_of_forestry_and_agricultural_products", "units": "kg m-2", - "cell_methods": "area: mean where landuse time: point", + "cell_methods": "area: mean where sector time: point", "cell_measures": "area: areacella", - "long_name": "wood and agricultural product pool carbon associated with land use tiles; examples of products include paper, cardboard, timber for construction, and crop harvest for food or fuel.", - "comment": "anthropogenic pools associated with land use tiles into which harvests and cleared carbon are deposited before release into atmosphere PLUS any remaining anthropogenic pools that may be associated with lands which were converted into land use tiles during reported period . Does NOT include residue which is deposited into soil or litter; end of year values (not annual mean)", + "long_name": "Wood and Agricultural Product Pool Carbon Associated with Land-Use Tiles", + "comment": "Anthropogenic pools associated with land use tiles into which harvests and cleared carbon are deposited before release into atmosphere PLUS any remaining anthropogenic pools that may be associated with lands which were converted into land use tiles during reported period. Examples of products include paper, cardboard, timber for construction, and crop harvest for food or fuel. Does NOT include residue which is deposited into soil or litter; end of year values (not annual mean).", "dimensions": "longitude latitude landUse time1", "out_name": "cProductLut", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -100,12 +105,13 @@ "ok_max_mean_abs": "" }, "cSoil": { + "frequency": "yrPt", "modeling_realm": "land", - "standard_name": "soil_carbon_content", + "standard_name": "soil_mass_content_of_carbon", "units": "kg m-2", "cell_methods": "area: mean where land time: point", "cell_measures": "area: areacella", - "long_name": "Carbon Mass in Soil Pool", + "long_name": "Carbon Mass in Model Soil Pool", "comment": "Carbon mass in the full depth of the soil model.", "dimensions": "longitude latitude time1", "out_name": "cSoil", @@ -117,16 +123,17 @@ "ok_max_mean_abs": "" }, "cSoilLut": { + "frequency": "yrPt", "modeling_realm": "land", - "standard_name": "soil_carbon_content", + "standard_name": "soil_mass_content_of_carbon", "units": "kg m-2", - "cell_methods": "area: mean where landuse time: point", + "cell_methods": "area: mean where sector time: point", "cell_measures": "area: areacella", - "long_name": "carbon in soil pool on land use tiles", + "long_name": "carbon in soil pool on Land-use tiles", "comment": "end of year values (not annual mean)", "dimensions": "longitude latitude landUse time1", "out_name": "cSoilLut", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -134,6 +141,7 @@ "ok_max_mean_abs": "" }, "cVeg": { + "frequency": "yrPt", "modeling_realm": "land", "standard_name": "vegetation_carbon_content", "units": "kg m-2", @@ -151,16 +159,17 @@ "ok_max_mean_abs": "" }, "cVegLut": { + "frequency": "yrPt", "modeling_realm": "land", "standard_name": "vegetation_carbon_content", "units": "kg m-2", - "cell_methods": "area: mean where landuse time: point", + "cell_methods": "area: mean where sector time: point", "cell_measures": "area: areacella", - "long_name": "carbon in vegetation on land use tiles", + "long_name": "Carbon in Vegetation on Land-Use Tiles", "comment": "end of year values (not annual mean)", "dimensions": "longitude latitude landUse time1", "out_name": "cVegLut", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -168,12 +177,13 @@ "ok_max_mean_abs": "" }, "cropFrac": { + "frequency": "yr", "modeling_realm": "land", "standard_name": "area_fraction", "units": "%", "cell_methods": "area: mean where land over all_area_types time: mean", "cell_measures": "area: areacella", - "long_name": "Crop Fraction", + "long_name": "Percentage Crop Cover", "comment": "Percentage of entire grid cell that is covered by crop.", "dimensions": "longitude latitude time typecrop", "out_name": "cropFrac", @@ -185,16 +195,17 @@ "ok_max_mean_abs": "" }, "fracInLut": { + "frequency": "yr", "modeling_realm": "land", "standard_name": "area_fraction", "units": "%", "cell_methods": "area: mean where land over all_area_types time: sum", "cell_measures": "area: areacella", - "long_name": "annual gross fraction that was transferred into this tile from other land use tiles", - "comment": "cumulative fractional transitions over the year; note that fraction should be reported as fraction of atmospheric grid cell", + "long_name": "Annual Gross Percentage That Was Transferred into This Tile from Other Land-Use Tiles", + "comment": "Cumulative percentage transitions over the year; note that percentage should be reported as a percentage of atmospheric grid cell", "dimensions": "longitude latitude landUse time", "out_name": "fracInLut", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -202,16 +213,17 @@ "ok_max_mean_abs": "" }, "fracLut": { + "frequency": "yrPt", "modeling_realm": "land", "standard_name": "area_fraction", "units": "%", "cell_methods": "area: mean where land over all_area_types time: point", "cell_measures": "area: areacella", - "long_name": "fraction of grid cell for each land use tile", - "comment": "end of year values (not annual mean); note that fraction should be reported as fraction of land grid cell (example: frac_lnd = 0.5, frac_ocn = 0.5, frac_crop_lnd = 0.2 (of land portion of grid cell), then frac_lut(crp) = 0.5*0.2 = 0.1)", + "long_name": "Percentage of Grid Cell for Each Land-Use Tile", + "comment": "End of year values (not annual mean); note that percentage should be reported as percentage of land grid cell (example: frac_lnd = 0.5, frac_ocn = 0.5, frac_crop_lnd = 0.2 (of land portion of grid cell), then frac_lut(crop) = 0.5*0.2 = 0.1)", "dimensions": "longitude latitude landUse time1", "out_name": "fracLut", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -219,16 +231,17 @@ "ok_max_mean_abs": "" }, "fracOutLut": { + "frequency": "yr", "modeling_realm": "land", "standard_name": "area_fraction", "units": "%", "cell_methods": "area: mean where land over all_area_types time: sum", "cell_measures": "area: areacella", - "long_name": "annual gross fraction of land use tile that was transferred into other land use tiles", - "comment": "cumulative fractional transitions over the year; note that fraction should be reported as fraction of atmospheric grid cell", + "long_name": "Annual gross percentage of Land-use tile that was transferred into other Land-use tiles", + "comment": "Cumulative percentage transitions over the year; note that percentage should be reported as percentage of atmospheric grid cell", "dimensions": "longitude latitude landUse time", "out_name": "fracOutLut", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -236,12 +249,13 @@ "ok_max_mean_abs": "" }, "grassFrac": { + "frequency": "yr", "modeling_realm": "land", "standard_name": "area_fraction", "units": "%", "cell_methods": "area: mean where land over all_area_types time: mean", "cell_measures": "area: areacella", - "long_name": "Natural Grass Fraction", + "long_name": "Natural Grass Area Percentage", "comment": "Percentage of entire grid cell that is covered by natural grass.", "dimensions": "longitude latitude time typenatgr", "out_name": "grassFrac", @@ -253,12 +267,13 @@ "ok_max_mean_abs": "" }, "residualFrac": { + "frequency": "yr", "modeling_realm": "land", "standard_name": "area_fraction", "units": "%", "cell_methods": "area: mean where land over all_area_types time: mean", "cell_measures": "area: areacella", - "long_name": "Fraction of Grid Cell that is Land but Neither Vegetation-Covered nor Bare Soil", + "long_name": "Percentage of Grid Cell That Is Land but neither Vegetation Covered nor Bare Soil", "comment": "Percentage of entire grid cell that is land and is covered by neither vegetation nor bare-soil (e.g., urban, ice, lakes, etc.)", "dimensions": "longitude latitude time typeresidual", "out_name": "residualFrac", @@ -270,12 +285,13 @@ "ok_max_mean_abs": "" }, "shrubFrac": { + "frequency": "yr", "modeling_realm": "land", "standard_name": "area_fraction", "units": "%", "cell_methods": "area: mean where land over all_area_types time: mean", "cell_measures": "area: areacella", - "long_name": "Shrub Fraction", + "long_name": "Percentage Cover by Shrub", "comment": "Percentage of entire grid cell that is covered by shrub.", "dimensions": "longitude latitude time typeshrub", "out_name": "shrubFrac", @@ -287,12 +303,13 @@ "ok_max_mean_abs": "" }, "treeFrac": { + "frequency": "yr", "modeling_realm": "land", "standard_name": "area_fraction", "units": "%", "cell_methods": "area: mean where land over all_area_types time: mean", "cell_measures": "area: areacella", - "long_name": "Tree Cover Fraction", + "long_name": "Tree Cover Percentage", "comment": "Percentage of entire grid cell that is covered by trees.", "dimensions": "longitude latitude time typetree", "out_name": "treeFrac", @@ -304,16 +321,17 @@ "ok_max_mean_abs": "" }, "vegFrac": { - "modeling_realm": "", + "frequency": "yr", + "modeling_realm": "land", "standard_name": "area_fraction", "units": "%", "cell_methods": "area: mean where land over all_area_types time: mean", "cell_measures": "area: areacella", - "long_name": "Total vegetated fraction", - "comment": "fraction of grid cell that is covered by vegetation.This SHOULD be the sum of tree, grass, crop and shrub fractions.", + "long_name": "Total Vegetated Percentage Cover", + "comment": "Percentage of grid cell that is covered by vegetation.This SHOULD be the sum of tree, grass, crop and shrub fractions.", "dimensions": "longitude latitude time typeveg", "out_name": "vegFrac", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -321,6 +339,7 @@ "ok_max_mean_abs": "" }, "zfullo": { + "frequency": "yr", "modeling_realm": "ocean", "standard_name": "depth_below_geoid", "units": "m", diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_IfxAnt.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_IfxAnt.json index 2b4c727274..d1ac5ff73c 100644 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_IfxAnt.json +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_IfxAnt.json @@ -1,30 +1,31 @@ { "Header": { - "data_specs_version": "01.00.10", + "data_specs_version": "01.00.30", + "cmor_version": "3.4", "table_id": "Table IfxAnt", "realm": "landIce", - "frequency": "fx", - "cmor_version": "3.2", - "table_date": "10 May 2017", + "table_date": "11 March 2019", "missing_value": "1e20", + "int_missing_value": "-999", "product": "model-output", "approx_interval": "", "generic_levels": "", "mip_era": "CMIP6", - "Conventions": "CF-1.7 CMIP-6.0" + "Conventions": "CF-1.7 CMIP-6.2" }, "variable_entry": { "areacellg": { + "frequency": "fx", "modeling_realm": "land", "standard_name": "cell_area", "units": "m2", - "cell_methods": "area: mean", - "cell_measures": "area: areacellg", - "long_name": "Grid Cell Area for Interpolated Grids", + "cell_methods": "area: sum", + "cell_measures": "", + "long_name": "Grid-Cell Area for Ice Sheet Variables", "comment": "Area of the target grid (not the interpolated area of the source grid).", - "dimensions": "xant yant", + "dimensions": "longitude latitude", "out_name": "areacellg", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -32,16 +33,17 @@ "ok_max_mean_abs": "" }, "hfgeoubed": { + "frequency": "fx", "modeling_realm": "landIce", "standard_name": "upward_geothermal_heat_flux_at_ground_level_in_land_ice", "units": "W m-2", - "cell_methods": "area: mean", + "cell_methods": "area: mean where grounded_ice_sheet", "cell_measures": "area: areacellg", - "long_name": "Geothermal Heat flux beneath land ice", + "long_name": "Geothermal Heat Flux Beneath Land Ice", "comment": "Upward geothermal heat flux per unit area beneath land ice", "dimensions": "xant yant", "out_name": "hfgeoubed", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -49,16 +51,17 @@ "ok_max_mean_abs": "" }, "lithk": { + "frequency": "fx", "modeling_realm": "landIce", "standard_name": "land_ice_thickness", "units": "m", - "cell_methods": "area: mean", + "cell_methods": "area: mean where ice_sheet", "cell_measures": "area: areacellg", "long_name": "Ice Sheet Thickness", "comment": "The thickness of the ice sheet", "dimensions": "xant yant", "out_name": "lithk", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -66,16 +69,17 @@ "ok_max_mean_abs": "" }, "topg": { + "frequency": "fx", "modeling_realm": "landIce", "standard_name": "bedrock_altitude", "units": "m", - "cell_methods": "area: mean", + "cell_methods": "area: mean where grounded_ice_sheet", "cell_measures": "area: areacellg", "long_name": "Bedrock Altitude", "comment": "The bedrock topography beneath the land ice", "dimensions": "xant yant", "out_name": "topg", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_IfxGre.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_IfxGre.json index ba35dba324..dbcd464c89 100644 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_IfxGre.json +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_IfxGre.json @@ -1,30 +1,31 @@ { "Header": { - "data_specs_version": "01.00.10", + "data_specs_version": "01.00.30", + "cmor_version": "3.4", "table_id": "Table IfxGre", "realm": "landIce", - "frequency": "fx", - "cmor_version": "3.2", - "table_date": "10 May 2017", + "table_date": "11 March 2019", "missing_value": "1e20", + "int_missing_value": "-999", "product": "model-output", "approx_interval": "", "generic_levels": "", "mip_era": "CMIP6", - "Conventions": "CF-1.7 CMIP-6.0" + "Conventions": "CF-1.7 CMIP-6.2" }, "variable_entry": { "areacellg": { + "frequency": "fx", "modeling_realm": "land", "standard_name": "cell_area", "units": "m2", - "cell_methods": "area: mean", - "cell_measures": "area: areacellg", - "long_name": "Grid Cell Area for Interpolated Grids", + "cell_methods": "area: sum", + "cell_measures": "", + "long_name": "Grid-Cell Area for Ice Sheet Variables", "comment": "Area of the target grid (not the interpolated area of the source grid).", - "dimensions": "xgre ygre", + "dimensions": "longitude latitude", "out_name": "areacellg", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -32,16 +33,17 @@ "ok_max_mean_abs": "" }, "hfgeoubed": { + "frequency": "fx", "modeling_realm": "landIce", "standard_name": "upward_geothermal_heat_flux_at_ground_level_in_land_ice", "units": "W m-2", - "cell_methods": "area: mean", + "cell_methods": "area: mean where grounded_ice_sheet", "cell_measures": "area: areacellg", - "long_name": "Geothermal Heat flux beneath land ice", + "long_name": "Geothermal Heat Flux Beneath Land Ice", "comment": "Upward geothermal heat flux per unit area beneath land ice", "dimensions": "xgre ygre", "out_name": "hfgeoubed", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -49,16 +51,17 @@ "ok_max_mean_abs": "" }, "lithk": { + "frequency": "fx", "modeling_realm": "landIce", "standard_name": "land_ice_thickness", "units": "m", - "cell_methods": "area: mean", + "cell_methods": "area: mean where ice_sheet", "cell_measures": "area: areacellg", "long_name": "Ice Sheet Thickness", "comment": "The thickness of the ice sheet", "dimensions": "xgre ygre", "out_name": "lithk", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -66,16 +69,17 @@ "ok_max_mean_abs": "" }, "topg": { + "frequency": "fx", "modeling_realm": "landIce", "standard_name": "bedrock_altitude", "units": "m", - "cell_methods": "area: mean", + "cell_methods": "area: mean where grounded_ice_sheet", "cell_measures": "area: areacellg", "long_name": "Bedrock Altitude", "comment": "The bedrock topography beneath the land ice", "dimensions": "xgre ygre", "out_name": "topg", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_ImonAnt.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_ImonAnt.json index e680bc6b96..42d98b39d7 100644 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_ImonAnt.json +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_ImonAnt.json @@ -1,30 +1,31 @@ { "Header": { - "data_specs_version": "01.00.10", + "data_specs_version": "01.00.30", + "cmor_version": "3.4", "table_id": "Table ImonAnt", - "realm": "atmos", - "frequency": "mon", - "cmor_version": "3.2", - "table_date": "10 May 2017", + "realm": "landIce land", + "table_date": "11 March 2019", "missing_value": "1e20", + "int_missing_value": "-999", "product": "model-output", "approx_interval": "30.00", "generic_levels": "", "mip_era": "CMIP6", - "Conventions": "CF-1.7 CMIP-6.0" + "Conventions": "CF-1.7 CMIP-6.2" }, "variable_entry": { "acabf": { + "frequency": "mon", "modeling_realm": "landIce", "standard_name": "land_ice_surface_specific_mass_balance_flux", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", - "long_name": "Surface Mass Balance flux", + "long_name": "Surface Mass Balance Flux", "comment": "Specific mass balance means the net rate at which ice is added per unit area at the land ice surface. Computed as the total surface mass balance on the land ice portion of the grid cell divided by land ice area in the grid cell. A negative value means loss of ice", "dimensions": "xant yant time", "out_name": "acabf", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -32,13 +33,14 @@ "ok_max_mean_abs": "" }, "hfls": { - "modeling_realm": "atmos", + "frequency": "mon", + "modeling_realm": "landIce land", "standard_name": "surface_upward_latent_heat_flux", "units": "W m-2", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", "long_name": "Surface Upward Latent Heat Flux", - "comment": "", + "comment": "The surface called 'surface' means the lower boundary of the atmosphere. 'Upward' indicates a vector component which is positive when directed upward (negative downward). The surface latent heat flux is the exchange of heat between the surface and the air on account of evaporation (including sublimation). In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions": "xant yant time", "out_name": "hfls", "type": "real", @@ -49,13 +51,14 @@ "ok_max_mean_abs": "" }, "hfss": { - "modeling_realm": "atmos", + "frequency": "mon", + "modeling_realm": "landIce land", "standard_name": "surface_upward_sensible_heat_flux", "units": "W m-2", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", "long_name": "Surface Upward Sensible Heat Flux", - "comment": "", + "comment": "The surface sensible heat flux, also called turbulent heat flux, is the exchange of heat between the surface and the air by motion of air.", "dimensions": "xant yant time", "out_name": "hfss", "type": "real", @@ -66,33 +69,17 @@ "ok_max_mean_abs": "" }, "icem": { + "frequency": "mon", "modeling_realm": "landIce", "standard_name": "land_ice_surface_melt_flux", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", - "long_name": "Surface ice melt flux", + "long_name": "Surface Ice Melt Flux", "comment": "Loss of ice mass resulting from surface melting. Computed as the total surface melt water on the land ice portion of the grid cell divided by land ice area in the grid cell.", "dimensions": "xant yant time", "out_name": "icem", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "lialb": { - "modeling_realm": "landIce", - "standard_name": "surface_albedo", - "units": "1.0", - "cell_methods": "area: time: mean where ice_sheet", - "cell_measures": "area: areacellg", - "long_name": "Land ice or snow albedo", - "comment": "Mean surface albedo of entire land ice covered part of the grid cell", - "dimensions": "xant yant time", - "out_name": "lialb", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -100,16 +87,17 @@ "ok_max_mean_abs": "" }, "libmassbffl": { + "frequency": "mon", "modeling_realm": "landIce", "standard_name": "land_ice_basal_specific_mass_balance_flux", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where floating_ice_shelf (comment: mask=sftflf)", "cell_measures": "area: areacellg", - "long_name": "Basal specific mass balance flux of floating ice shelf", + "long_name": "Basal Specific Mass Balance Flux of Floating Ice Shelf", "comment": "Specific mass balance means the net rate at which ice is added per unit area at the land ice base. A negative value means loss of ice. Computed as the total basal mass balance on the floating land ice (floating ice shelf) portion of the grid cell divided by floating land ice (floating ice shelf) area in the grid cell. Cell_methods: area: mean where floating_ice_shelf", "dimensions": "xant yant time", "out_name": "libmassbffl", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -117,16 +105,17 @@ "ok_max_mean_abs": "" }, "libmassbfgr": { + "frequency": "mon", "modeling_realm": "landIce", "standard_name": "land_ice_basal_specific_mass_balance_flux", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where grounded_ice_sheet (comment: mask=sfgrlf)", "cell_measures": "area: areacellg", - "long_name": "Basal specific mass balance flux of grounded ice sheet", + "long_name": "Basal Specific Mass Balance Flux of Grounded Ice Sheet", "comment": "Specific mass balance means the net rate at which ice is added per unit area at the land ice base. A negative value means loss of ice. Computed as the total basal mass balance on the grounded land ice portion of the grid cell divided by grounded land ice area in the grid cell. Cell_methods: area: mean where grounded_ice_sheet", "dimensions": "xant yant time", "out_name": "libmassbfgr", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -134,16 +123,17 @@ "ok_max_mean_abs": "" }, "licalvf": { + "frequency": "mon", "modeling_realm": "landIce", "standard_name": "land_ice_specific_mass_flux_due_to_calving", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", - "long_name": "Land ice calving flux", + "long_name": "Land Ice Calving Flux", "comment": "Loss of ice mass resulting from iceberg calving. Computed as the rate of mass loss by the ice shelf (in kg s-1) divided by the horizontal area of the ice sheet (m2) in the grid box.", "dimensions": "xant yant time", "out_name": "licalvf", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -151,16 +141,17 @@ "ok_max_mean_abs": "" }, "lifmassbf": { + "frequency": "mon", "modeling_realm": "landIce", "standard_name": "land_ice_specific_mass_flux_due_to_calving_and_ice_front_melting", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", - "long_name": "Land ice vertical front mass balance flux", + "long_name": "Land Ice Vertical Front Mass Balance Flux", "comment": "Total mass balance at the ice front (or vertical margin). It includes both iceberg calving and melt on vertical ice front", "dimensions": "xant yant time", "out_name": "lifmassbf", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -168,16 +159,17 @@ "ok_max_mean_abs": "" }, "litempbotfl": { + "frequency": "mon", "modeling_realm": "landIce", "standard_name": "land_ice_basal_temperature", "units": "K", "cell_methods": "area: time: mean where floating_ice_shelf (comment: mask=sftflf)", "cell_measures": "area: areacellg", - "long_name": "Basal temperature of floating ice shelf", + "long_name": "Basal Temperature of Floating Ice Shelf", "comment": "Basal temperature that is used to force the ice sheet models, it is the temperature AT ice shelf-ocean interface. Cell_methods: area: mean where floating_ice_shelf", "dimensions": "xant yant time", "out_name": "litempbotfl", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -185,16 +177,17 @@ "ok_max_mean_abs": "" }, "litempbotgr": { + "frequency": "mon", "modeling_realm": "landIce", "standard_name": "land_ice_basal_temperature", "units": "K", "cell_methods": "area: time: mean where grounded_ice_sheet (comment: mask=sfgrlf)", "cell_measures": "area: areacellg", - "long_name": "Basal temperature of grounded ice sheet", + "long_name": "Basal Temperature of Grounded Ice Sheet", "comment": "Basal temperature that is used to force the ice sheet models, it is the temperature AT ice sheet - bedrock interface. Cell_methods: area: mean where grounded_ice_sheet", "dimensions": "xant yant time", "out_name": "litempbotgr", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -202,16 +195,17 @@ "ok_max_mean_abs": "" }, "litemptop": { + "frequency": "mon", "modeling_realm": "landIce", "standard_name": "temperature_at_top_of_ice_sheet_model", "units": "K", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", - "long_name": "Temperature at top of ice sheet model", + "long_name": "Temperature at Top of Ice Sheet Model", "comment": "Upper boundary temperature that is used to force ice sheet models. It is the temperature at the base of the snowpack models, and does not vary with seasons. Report surface temperature of ice sheet where snow thickness is zero", "dimensions": "xant yant time", "out_name": "litemptop", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -219,7 +213,8 @@ "ok_max_mean_abs": "" }, "mrroLi": { - "modeling_realm": "atmos", + "frequency": "mon", + "modeling_realm": "landIce land", "standard_name": "land_ice_runoff_flux", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where ice_sheet", @@ -228,7 +223,7 @@ "comment": "Runoff flux over land ice is the difference between any available liquid water in the snowpack less any refreezing. Computed as the sum of rainfall and melt of snow or ice less any refreezing or water retained in the snowpack", "dimensions": "xant yant time", "out_name": "mrroLi", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -236,6 +231,7 @@ "ok_max_mean_abs": "" }, "orog": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "surface_altitude", "units": "m", @@ -253,13 +249,14 @@ "ok_max_mean_abs": "" }, "prra": { - "modeling_realm": "atmos", + "frequency": "mon", + "modeling_realm": "landIce land", "standard_name": "rainfall_flux", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", - "long_name": "Rainfall Flux where Ice Free Ocean over Sea over Land Ice", - "comment": "", + "long_name": "Rainfall Flux over Land Ice", + "comment": "In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions": "xant yant time", "out_name": "prra", "type": "real", @@ -270,13 +267,14 @@ "ok_max_mean_abs": "" }, "prsn": { - "modeling_realm": "atmos", + "frequency": "mon", + "modeling_realm": "landIce land", "standard_name": "snowfall_flux", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", "long_name": "Snowfall Flux", - "comment": "at surface; includes precipitation of all forms of water in the solid phase", + "comment": "At surface; includes precipitation of all forms of water in the solid phase", "dimensions": "xant yant time", "out_name": "prsn", "type": "real", @@ -287,13 +285,14 @@ "ok_max_mean_abs": "" }, "rlds": { - "modeling_realm": "atmos", + "frequency": "mon", + "modeling_realm": "landIce land", "standard_name": "surface_downwelling_longwave_flux_in_air", "units": "W m-2", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", "long_name": "Surface Downwelling Longwave Radiation", - "comment": "", + "comment": "The surface called 'surface' means the lower boundary of the atmosphere. 'longwave' means longwave radiation. Downwelling radiation is radiation from above. It does not mean 'net downward'. When thought of as being incident on a surface, a radiative flux is sometimes called 'irradiance'. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called 'vector irradiance'. In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions": "xant yant time", "out_name": "rlds", "type": "real", @@ -304,13 +303,14 @@ "ok_max_mean_abs": "" }, "rlus": { - "modeling_realm": "atmos", + "frequency": "mon", + "modeling_realm": "landIce land", "standard_name": "surface_upwelling_longwave_flux_in_air", "units": "W m-2", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", "long_name": "Surface Upwelling Longwave Radiation", - "comment": "", + "comment": "The surface called 'surface' means the lower boundary of the atmosphere. 'longwave' means longwave radiation. Upwelling radiation is radiation from below. It does not mean 'net upward'. When thought of as being incident on a surface, a radiative flux is sometimes called 'irradiance'. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called 'vector irradiance'. In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions": "xant yant time", "out_name": "rlus", "type": "real", @@ -321,13 +321,14 @@ "ok_max_mean_abs": "" }, "rsds": { - "modeling_realm": "atmos", + "frequency": "mon", + "modeling_realm": "landIce land", "standard_name": "surface_downwelling_shortwave_flux_in_air", "units": "W m-2", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", "long_name": "Surface Downwelling Shortwave Radiation", - "comment": "surface solar irradiance for UV calculations", + "comment": "Surface solar irradiance for UV calculations.", "dimensions": "xant yant time", "out_name": "rsds", "type": "real", @@ -338,13 +339,14 @@ "ok_max_mean_abs": "" }, "rsus": { - "modeling_realm": "atmos", + "frequency": "mon", + "modeling_realm": "landIce land", "standard_name": "surface_upwelling_shortwave_flux_in_air", "units": "W m-2", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", "long_name": "Surface Upwelling Shortwave Radiation", - "comment": "", + "comment": "The surface called 'surface' means the lower boundary of the atmosphere. 'shortwave' means shortwave radiation. Upwelling radiation is radiation from below. It does not mean 'net upward'. When thought of as being incident on a surface, a radiative flux is sometimes called 'irradiance'. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called 'vector irradiance'. In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions": "xant yant time", "out_name": "rsus", "type": "real", @@ -355,8 +357,9 @@ "ok_max_mean_abs": "" }, "sbl": { + "frequency": "mon", "modeling_realm": "landIce", - "standard_name": "surface_snow_and_ice_sublimation_flux", + "standard_name": "tendency_of_atmosphere_mass_content_of_water_vapor_due_to_sublimation_of_surface_snow_and_ice", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", @@ -372,16 +375,17 @@ "ok_max_mean_abs": "" }, "snc": { + "frequency": "mon", "modeling_realm": "landIce land", "standard_name": "surface_snow_area_fraction", "units": "%", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", - "long_name": "snow cover fraction", - "comment": "Fraction of each grid cell that is occupied by snow that rests on land portion of cell.", + "long_name": "Snow Area Percentage", + "comment": "Percentage of each grid cell that is occupied by snow that rests on land portion of cell.", "dimensions": "xant yant time", "out_name": "snc", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -389,16 +393,17 @@ "ok_max_mean_abs": "" }, "snicefreez": { + "frequency": "mon", "modeling_realm": "landIce", "standard_name": "surface_snow_and_ice_refreezing_flux", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", - "long_name": "Surface snow and ice refreeze flux", + "long_name": "Surface Snow and Ice Refreeze Flux", "comment": "Mass flux of surface meltwater which refreezes within the snowpack. Computed as the total refreezing on the land ice portion of the grid cell divided by land ice area in the grid cell.", "dimensions": "xant yant time", "out_name": "snicefreez", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -406,16 +411,17 @@ "ok_max_mean_abs": "" }, "snicem": { + "frequency": "mon", "modeling_realm": "landIce", "standard_name": "surface_snow_and_ice_melt_flux", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", - "long_name": "Surface snow and ice melt flux", + "long_name": "Surface Snow and Ice Melt Flux", "comment": "Loss of snow and ice mass resulting from surface melting. Computed as the total surface melt on the land ice portion of the grid cell divided by land ice area in the grid cell.", "dimensions": "xant yant time", "out_name": "snicem", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -423,6 +429,7 @@ "ok_max_mean_abs": "" }, "snm": { + "frequency": "mon", "modeling_realm": "landIce land", "standard_name": "surface_snow_melt_flux", "units": "kg m-2 s-1", @@ -440,16 +447,17 @@ "ok_max_mean_abs": "" }, "tas": { - "modeling_realm": "atmos", + "frequency": "mon", + "modeling_realm": "landIce land", "standard_name": "air_temperature", "units": "K", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "", - "long_name": "Surface Air Temperature", + "long_name": "Near-Surface Air Temperature", "comment": "near-surface (usually, 2 meter) air temperature", "dimensions": "time height2m", "out_name": "tas", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -457,7 +465,8 @@ "ok_max_mean_abs": "" }, "ts": { - "modeling_realm": "atmos", + "frequency": "mon", + "modeling_realm": "landIce land", "standard_name": "surface_temperature", "units": "K", "cell_methods": "area: time: mean where ice_sheet", @@ -474,6 +483,7 @@ "ok_max_mean_abs": "" }, "tsn": { + "frequency": "mon", "modeling_realm": "landIce land", "standard_name": "temperature_in_surface_snow", "units": "K", diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_ImonGre.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_ImonGre.json index b95e791829..5953ab4a73 100644 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_ImonGre.json +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_ImonGre.json @@ -1,30 +1,31 @@ { "Header": { - "data_specs_version": "01.00.10", + "data_specs_version": "01.00.30", + "cmor_version": "3.4", "table_id": "Table ImonGre", - "realm": "atmos", - "frequency": "mon", - "cmor_version": "3.2", - "table_date": "10 May 2017", + "realm": "landIce land", + "table_date": "11 March 2019", "missing_value": "1e20", + "int_missing_value": "-999", "product": "model-output", "approx_interval": "30.00", "generic_levels": "", "mip_era": "CMIP6", - "Conventions": "CF-1.7 CMIP-6.0" + "Conventions": "CF-1.7 CMIP-6.2" }, "variable_entry": { "acabf": { + "frequency": "mon", "modeling_realm": "landIce", "standard_name": "land_ice_surface_specific_mass_balance_flux", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", - "long_name": "Surface Mass Balance flux", + "long_name": "Surface Mass Balance Flux", "comment": "Specific mass balance means the net rate at which ice is added per unit area at the land ice surface. Computed as the total surface mass balance on the land ice portion of the grid cell divided by land ice area in the grid cell. A negative value means loss of ice", "dimensions": "xgre ygre time", "out_name": "acabf", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -32,13 +33,14 @@ "ok_max_mean_abs": "" }, "hfls": { - "modeling_realm": "atmos", + "frequency": "mon", + "modeling_realm": "landIce land", "standard_name": "surface_upward_latent_heat_flux", "units": "W m-2", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", "long_name": "Surface Upward Latent Heat Flux", - "comment": "", + "comment": "The surface called 'surface' means the lower boundary of the atmosphere. 'Upward' indicates a vector component which is positive when directed upward (negative downward). The surface latent heat flux is the exchange of heat between the surface and the air on account of evaporation (including sublimation). In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions": "xgre ygre time", "out_name": "hfls", "type": "real", @@ -49,13 +51,14 @@ "ok_max_mean_abs": "" }, "hfss": { - "modeling_realm": "atmos", + "frequency": "mon", + "modeling_realm": "landIce land", "standard_name": "surface_upward_sensible_heat_flux", "units": "W m-2", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", "long_name": "Surface Upward Sensible Heat Flux", - "comment": "", + "comment": "The surface sensible heat flux, also called turbulent heat flux, is the exchange of heat between the surface and the air by motion of air.", "dimensions": "xgre ygre time", "out_name": "hfss", "type": "real", @@ -66,33 +69,17 @@ "ok_max_mean_abs": "" }, "icem": { + "frequency": "mon", "modeling_realm": "landIce", "standard_name": "land_ice_surface_melt_flux", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", - "long_name": "Surface ice melt flux", + "long_name": "Surface Ice Melt Flux", "comment": "Loss of ice mass resulting from surface melting. Computed as the total surface melt water on the land ice portion of the grid cell divided by land ice area in the grid cell.", "dimensions": "xgre ygre time", "out_name": "icem", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "lialb": { - "modeling_realm": "landIce", - "standard_name": "surface_albedo", - "units": "1.0", - "cell_methods": "area: time: mean where ice_sheet", - "cell_measures": "area: areacellg", - "long_name": "Land ice or snow albedo", - "comment": "Mean surface albedo of entire land ice covered part of the grid cell", - "dimensions": "xgre ygre time", - "out_name": "lialb", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -100,16 +87,17 @@ "ok_max_mean_abs": "" }, "libmassbffl": { + "frequency": "mon", "modeling_realm": "landIce", "standard_name": "land_ice_basal_specific_mass_balance_flux", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where floating_ice_shelf (comment: mask=sftflf)", "cell_measures": "area: areacellg", - "long_name": "Basal specific mass balance flux of floating ice shelf", + "long_name": "Basal Specific Mass Balance Flux of Floating Ice Shelf", "comment": "Specific mass balance means the net rate at which ice is added per unit area at the land ice base. A negative value means loss of ice. Computed as the total basal mass balance on the floating land ice (floating ice shelf) portion of the grid cell divided by floating land ice (floating ice shelf) area in the grid cell. Cell_methods: area: mean where floating_ice_shelf", "dimensions": "xgre ygre time", "out_name": "libmassbffl", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -117,16 +105,17 @@ "ok_max_mean_abs": "" }, "libmassbfgr": { + "frequency": "mon", "modeling_realm": "landIce", "standard_name": "land_ice_basal_specific_mass_balance_flux", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where grounded_ice_sheet (comment: mask=sfgrlf)", "cell_measures": "area: areacellg", - "long_name": "Basal specific mass balance flux of grounded ice sheet", + "long_name": "Basal Specific Mass Balance Flux of Grounded Ice Sheet", "comment": "Specific mass balance means the net rate at which ice is added per unit area at the land ice base. A negative value means loss of ice. Computed as the total basal mass balance on the grounded land ice portion of the grid cell divided by grounded land ice area in the grid cell. Cell_methods: area: mean where grounded_ice_sheet", "dimensions": "xgre ygre time", "out_name": "libmassbfgr", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -134,16 +123,17 @@ "ok_max_mean_abs": "" }, "licalvf": { + "frequency": "mon", "modeling_realm": "landIce", "standard_name": "land_ice_specific_mass_flux_due_to_calving", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", - "long_name": "Land ice calving flux", + "long_name": "Land Ice Calving Flux", "comment": "Loss of ice mass resulting from iceberg calving. Computed as the rate of mass loss by the ice shelf (in kg s-1) divided by the horizontal area of the ice sheet (m2) in the grid box.", "dimensions": "xgre ygre time", "out_name": "licalvf", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -151,16 +141,17 @@ "ok_max_mean_abs": "" }, "lifmassbf": { + "frequency": "mon", "modeling_realm": "landIce", "standard_name": "land_ice_specific_mass_flux_due_to_calving_and_ice_front_melting", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", - "long_name": "Land ice vertical front mass balance flux", + "long_name": "Land Ice Vertical Front Mass Balance Flux", "comment": "Total mass balance at the ice front (or vertical margin). It includes both iceberg calving and melt on vertical ice front", "dimensions": "xgre ygre time", "out_name": "lifmassbf", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -168,16 +159,17 @@ "ok_max_mean_abs": "" }, "litempbotfl": { + "frequency": "mon", "modeling_realm": "landIce", "standard_name": "land_ice_basal_temperature", "units": "K", "cell_methods": "area: time: mean where floating_ice_shelf (comment: mask=sftflf)", "cell_measures": "area: areacellg", - "long_name": "Basal temperature of floating ice shelf", + "long_name": "Basal Temperature of Floating Ice Shelf", "comment": "Basal temperature that is used to force the ice sheet models, it is the temperature AT ice shelf-ocean interface. Cell_methods: area: mean where floating_ice_shelf", "dimensions": "xgre ygre time", "out_name": "litempbotfl", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -185,16 +177,17 @@ "ok_max_mean_abs": "" }, "litempbotgr": { + "frequency": "mon", "modeling_realm": "landIce", "standard_name": "land_ice_basal_temperature", "units": "K", "cell_methods": "area: time: mean where grounded_ice_sheet (comment: mask=sfgrlf)", "cell_measures": "area: areacellg", - "long_name": "Basal temperature of grounded ice sheet", + "long_name": "Basal Temperature of Grounded Ice Sheet", "comment": "Basal temperature that is used to force the ice sheet models, it is the temperature AT ice sheet - bedrock interface. Cell_methods: area: mean where grounded_ice_sheet", "dimensions": "xgre ygre time", "out_name": "litempbotgr", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -202,16 +195,17 @@ "ok_max_mean_abs": "" }, "litemptop": { + "frequency": "mon", "modeling_realm": "landIce", "standard_name": "temperature_at_top_of_ice_sheet_model", "units": "K", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", - "long_name": "Temperature at top of ice sheet model", + "long_name": "Temperature at Top of Ice Sheet Model", "comment": "Upper boundary temperature that is used to force ice sheet models. It is the temperature at the base of the snowpack models, and does not vary with seasons. Report surface temperature of ice sheet where snow thickness is zero", "dimensions": "xgre ygre time", "out_name": "litemptop", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -219,7 +213,8 @@ "ok_max_mean_abs": "" }, "mrroLi": { - "modeling_realm": "atmos", + "frequency": "mon", + "modeling_realm": "landIce land", "standard_name": "land_ice_runoff_flux", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where ice_sheet", @@ -228,7 +223,7 @@ "comment": "Runoff flux over land ice is the difference between any available liquid water in the snowpack less any refreezing. Computed as the sum of rainfall and melt of snow or ice less any refreezing or water retained in the snowpack", "dimensions": "xgre ygre time", "out_name": "mrroLi", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -236,6 +231,7 @@ "ok_max_mean_abs": "" }, "orog": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "surface_altitude", "units": "m", @@ -253,13 +249,14 @@ "ok_max_mean_abs": "" }, "prra": { - "modeling_realm": "atmos", + "frequency": "mon", + "modeling_realm": "landIce land", "standard_name": "rainfall_flux", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", - "long_name": "Rainfall Flux where Ice Free Ocean over Sea over Land Ice", - "comment": "", + "long_name": "Rainfall Flux over Land Ice", + "comment": "In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions": "xgre ygre time", "out_name": "prra", "type": "real", @@ -270,13 +267,14 @@ "ok_max_mean_abs": "" }, "prsn": { - "modeling_realm": "atmos", + "frequency": "mon", + "modeling_realm": "landIce land", "standard_name": "snowfall_flux", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", "long_name": "Snowfall Flux", - "comment": "at surface; includes precipitation of all forms of water in the solid phase", + "comment": "At surface; includes precipitation of all forms of water in the solid phase", "dimensions": "xgre ygre time", "out_name": "prsn", "type": "real", @@ -287,13 +285,14 @@ "ok_max_mean_abs": "" }, "rlds": { - "modeling_realm": "atmos", + "frequency": "mon", + "modeling_realm": "landIce land", "standard_name": "surface_downwelling_longwave_flux_in_air", "units": "W m-2", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", "long_name": "Surface Downwelling Longwave Radiation", - "comment": "", + "comment": "The surface called 'surface' means the lower boundary of the atmosphere. 'longwave' means longwave radiation. Downwelling radiation is radiation from above. It does not mean 'net downward'. When thought of as being incident on a surface, a radiative flux is sometimes called 'irradiance'. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called 'vector irradiance'. In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions": "xgre ygre time", "out_name": "rlds", "type": "real", @@ -304,13 +303,14 @@ "ok_max_mean_abs": "" }, "rlus": { - "modeling_realm": "atmos", + "frequency": "mon", + "modeling_realm": "landIce land", "standard_name": "surface_upwelling_longwave_flux_in_air", "units": "W m-2", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", "long_name": "Surface Upwelling Longwave Radiation", - "comment": "", + "comment": "The surface called 'surface' means the lower boundary of the atmosphere. 'longwave' means longwave radiation. Upwelling radiation is radiation from below. It does not mean 'net upward'. When thought of as being incident on a surface, a radiative flux is sometimes called 'irradiance'. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called 'vector irradiance'. In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions": "xgre ygre time", "out_name": "rlus", "type": "real", @@ -321,13 +321,14 @@ "ok_max_mean_abs": "" }, "rsds": { - "modeling_realm": "atmos", + "frequency": "mon", + "modeling_realm": "landIce land", "standard_name": "surface_downwelling_shortwave_flux_in_air", "units": "W m-2", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", "long_name": "Surface Downwelling Shortwave Radiation", - "comment": "surface solar irradiance for UV calculations", + "comment": "Surface solar irradiance for UV calculations.", "dimensions": "xgre ygre time", "out_name": "rsds", "type": "real", @@ -338,13 +339,14 @@ "ok_max_mean_abs": "" }, "rsus": { - "modeling_realm": "atmos", + "frequency": "mon", + "modeling_realm": "landIce land", "standard_name": "surface_upwelling_shortwave_flux_in_air", "units": "W m-2", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", "long_name": "Surface Upwelling Shortwave Radiation", - "comment": "", + "comment": "The surface called 'surface' means the lower boundary of the atmosphere. 'shortwave' means shortwave radiation. Upwelling radiation is radiation from below. It does not mean 'net upward'. When thought of as being incident on a surface, a radiative flux is sometimes called 'irradiance'. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called 'vector irradiance'. In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions": "xgre ygre time", "out_name": "rsus", "type": "real", @@ -355,8 +357,9 @@ "ok_max_mean_abs": "" }, "sbl": { + "frequency": "mon", "modeling_realm": "landIce", - "standard_name": "surface_snow_and_ice_sublimation_flux", + "standard_name": "tendency_of_atmosphere_mass_content_of_water_vapor_due_to_sublimation_of_surface_snow_and_ice", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", @@ -372,16 +375,17 @@ "ok_max_mean_abs": "" }, "snc": { + "frequency": "mon", "modeling_realm": "landIce land", "standard_name": "surface_snow_area_fraction", "units": "%", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", - "long_name": "snow cover fraction", - "comment": "Fraction of each grid cell that is occupied by snow that rests on land portion of cell.", + "long_name": "Snow Area Percentage", + "comment": "Percentage of each grid cell that is occupied by snow that rests on land portion of cell.", "dimensions": "xgre ygre time", "out_name": "snc", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -389,16 +393,17 @@ "ok_max_mean_abs": "" }, "snicefreez": { + "frequency": "mon", "modeling_realm": "landIce", "standard_name": "surface_snow_and_ice_refreezing_flux", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", - "long_name": "Surface snow and ice refreeze flux", + "long_name": "Surface Snow and Ice Refreeze Flux", "comment": "Mass flux of surface meltwater which refreezes within the snowpack. Computed as the total refreezing on the land ice portion of the grid cell divided by land ice area in the grid cell.", "dimensions": "xgre ygre time", "out_name": "snicefreez", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -406,16 +411,17 @@ "ok_max_mean_abs": "" }, "snicem": { + "frequency": "mon", "modeling_realm": "landIce", "standard_name": "surface_snow_and_ice_melt_flux", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", - "long_name": "Surface snow and ice melt flux", + "long_name": "Surface Snow and Ice Melt Flux", "comment": "Loss of snow and ice mass resulting from surface melting. Computed as the total surface melt on the land ice portion of the grid cell divided by land ice area in the grid cell.", "dimensions": "xgre ygre time", "out_name": "snicem", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -423,6 +429,7 @@ "ok_max_mean_abs": "" }, "snm": { + "frequency": "mon", "modeling_realm": "landIce land", "standard_name": "surface_snow_melt_flux", "units": "kg m-2 s-1", @@ -440,16 +447,17 @@ "ok_max_mean_abs": "" }, "tas": { - "modeling_realm": "atmos", + "frequency": "mon", + "modeling_realm": "landIce land", "standard_name": "air_temperature", "units": "K", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "", - "long_name": "Surface Air Temperature", + "long_name": "Near-Surface Air Temperature", "comment": "near-surface (usually, 2 meter) air temperature", "dimensions": "time height2m", "out_name": "tas", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -457,7 +465,8 @@ "ok_max_mean_abs": "" }, "ts": { - "modeling_realm": "atmos", + "frequency": "mon", + "modeling_realm": "landIce land", "standard_name": "surface_temperature", "units": "K", "cell_methods": "area: time: mean where ice_sheet", @@ -474,6 +483,7 @@ "ok_max_mean_abs": "" }, "tsn": { + "frequency": "mon", "modeling_realm": "landIce land", "standard_name": "temperature_in_surface_snow", "units": "K", diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_IyrAnt.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_IyrAnt.json index 043ebe2eb9..fe266333b0 100644 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_IyrAnt.json +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_IyrAnt.json @@ -1,47 +1,31 @@ { "Header": { - "data_specs_version": "01.00.10", + "data_specs_version": "01.00.30", + "cmor_version": "3.4", "table_id": "Table IyrAnt", "realm": "landIce", - "frequency": "yr", - "cmor_version": "3.2", - "table_date": "10 May 2017", + "table_date": "11 March 2019", "missing_value": "1e20", + "int_missing_value": "-999", "product": "model-output", "approx_interval": "365.00", "generic_levels": "", "mip_era": "CMIP6", - "Conventions": "CF-1.7 CMIP-6.0" + "Conventions": "CF-1.7 CMIP-6.2" }, "variable_entry": { "acabf": { + "frequency": "yr", "modeling_realm": "landIce", "standard_name": "land_ice_surface_specific_mass_balance_flux", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", - "long_name": "Surface Mass Balance flux", + "long_name": "Surface Mass Balance Flux", "comment": "Specific mass balance means the net rate at which ice is added per unit area at the land ice surface. Computed as the total surface mass balance on the land ice portion of the grid cell divided by land ice area in the grid cell. A negative value means loss of ice", "dimensions": "xant yant time", "out_name": "acabf", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "areacelli": { - "modeling_realm": "landIce", - "standard_name": "cell_area", - "units": "m2", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacellg", - "long_name": "Ice-Sheet Grid Cell Area", - "comment": "Horizontal area of ice-sheet grid cells", - "dimensions": "xant yant time", - "out_name": "areacelli", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -49,16 +33,17 @@ "ok_max_mean_abs": "" }, "hfgeoubed": { + "frequency": "yr", "modeling_realm": "landIce", "standard_name": "upward_geothermal_heat_flux_at_ground_level_in_land_ice", "units": "W m-2", - "cell_methods": "area: time: mean where ice_sheet", + "cell_methods": "area: mean where grounded_ice_sheet", "cell_measures": "area: areacellg", - "long_name": "Geothermal Heat flux beneath land ice", + "long_name": "Geothermal Heat Flux Beneath Land Ice", "comment": "Upward geothermal heat flux per unit area beneath land ice", - "dimensions": "xant yant time", + "dimensions": "xant yant", "out_name": "hfgeoubed", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -66,16 +51,17 @@ "ok_max_mean_abs": "" }, "iareafl": { - "modeling_realm": "atmos", + "frequency": "yr", + "modeling_realm": "landIce", "standard_name": "floating_ice_shelf_area", "units": "m2", "cell_methods": "area: time: mean where floating_ice_shelf (comment: mask=sftflf)", "cell_measures": "", - "long_name": "Area covered by floating ice shelves", + "long_name": "Area Covered by Floating Ice Shelves", "comment": "Total area of the floating ice shelves (the component of ice sheet that flows over ocean)", "dimensions": "time", "out_name": "iareafl", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -83,16 +69,17 @@ "ok_max_mean_abs": "" }, "iareagr": { - "modeling_realm": "atmos", + "frequency": "yr", + "modeling_realm": "landIce", "standard_name": "grounded_ice_sheet_area", "units": "m2", "cell_methods": "area: time: mean where grounded_ice_sheet (comment: mask=sfgrlf)", "cell_measures": "", - "long_name": "Area covered by grounded ice sheet", + "long_name": "Area Covered by Grounded Ice Sheet", "comment": "Total area of the grounded ice sheets (the component of ice sheet resting over bedrock)", "dimensions": "time", "out_name": "iareagr", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -100,16 +87,17 @@ "ok_max_mean_abs": "" }, "libmassbffl": { + "frequency": "yr", "modeling_realm": "landIce", "standard_name": "land_ice_basal_specific_mass_balance_flux", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where floating_ice_shelf (comment: mask=sftflf)", "cell_measures": "area: areacellg", - "long_name": "Basal specific mass balance flux of floating ice shelf", + "long_name": "Basal Specific Mass Balance Flux of Floating Ice Shelf", "comment": "Specific mass balance means the net rate at which ice is added per unit area at the land ice base. A negative value means loss of ice. Computed as the total basal mass balance on the floating land ice (floating ice shelf) portion of the grid cell divided by floating land ice (floating ice shelf) area in the grid cell. Cell_methods: area: mean where floating_ice_shelf", "dimensions": "xant yant time", "out_name": "libmassbffl", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -117,16 +105,17 @@ "ok_max_mean_abs": "" }, "libmassbfgr": { + "frequency": "yr", "modeling_realm": "landIce", "standard_name": "land_ice_basal_specific_mass_balance_flux", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where grounded_ice_sheet (comment: mask=sfgrlf)", "cell_measures": "area: areacellg", - "long_name": "Basal specific mass balance flux of grounded ice sheet", + "long_name": "Basal Specific Mass Balance Flux of Grounded Ice Sheet", "comment": "Specific mass balance means the net rate at which ice is added per unit area at the land ice base. A negative value means loss of ice. Computed as the total basal mass balance on the grounded land ice portion of the grid cell divided by grounded land ice area in the grid cell. Cell_methods: area: mean where grounded_ice_sheet", "dimensions": "xant yant time", "out_name": "libmassbfgr", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -134,16 +123,17 @@ "ok_max_mean_abs": "" }, "licalvf": { + "frequency": "yr", "modeling_realm": "landIce", "standard_name": "land_ice_specific_mass_flux_due_to_calving", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", - "long_name": "Land ice calving flux", + "long_name": "Land Ice Calving Flux", "comment": "Loss of ice mass resulting from iceberg calving. Computed as the rate of mass loss by the ice shelf (in kg s-1) divided by the horizontal area of the ice sheet (m2) in the grid box.", "dimensions": "xant yant time", "out_name": "licalvf", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -151,16 +141,17 @@ "ok_max_mean_abs": "" }, "lifmassbf": { + "frequency": "yr", "modeling_realm": "landIce", "standard_name": "land_ice_specific_mass_flux_due_to_calving_and_ice_front_melting", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", - "long_name": "Land ice vertical front mass balance flux", + "long_name": "Land Ice Vertical Front Mass Balance Flux", "comment": "Total mass balance at the ice front (or vertical margin). It includes both iceberg calving and melt on vertical ice front", "dimensions": "xant yant time", "out_name": "lifmassbf", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -168,16 +159,17 @@ "ok_max_mean_abs": "" }, "lim": { - "modeling_realm": "atmos", + "frequency": "yr", + "modeling_realm": "landIce", "standard_name": "land_ice_mass", "units": "kg", - "cell_methods": "area: time: mean where ice_sheet", + "cell_methods": "area: sum where ice_sheet time: mean", "cell_measures": "", - "long_name": "Ice sheet mass", + "long_name": "Ice Sheet Mass", "comment": "The ice sheet mass is computed as the volume times density", "dimensions": "time", "out_name": "lim", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -185,16 +177,17 @@ "ok_max_mean_abs": "" }, "limnsw": { - "modeling_realm": "atmos", + "frequency": "yr", + "modeling_realm": "landIce", "standard_name": "land_ice_mass_not_displacing_sea_water", "units": "kg", "cell_methods": "area: time: mean where grounded_ice_sheet (comment: mask=sfgrlf)", "cell_measures": "", - "long_name": "Ice sheet mass that does not displace sea water", + "long_name": "Ice Sheet Mass That Does not Displace Sea Water", "comment": "The ice sheet mass is computed as the volume above flotation times density. Changes in land_ice_mass_not_displacing_sea_water will always result in a change in sea level, unlike changes in land_ice_mass which may not result in sea level change (such as melting of the floating ice shelves, or portion of ice that sits on bedrock below sea level)", "dimensions": "time", "out_name": "limnsw", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -202,16 +195,17 @@ "ok_max_mean_abs": "" }, "litempbotfl": { + "frequency": "yr", "modeling_realm": "landIce", "standard_name": "land_ice_basal_temperature", "units": "K", "cell_methods": "area: time: mean where floating_ice_shelf (comment: mask=sftflf)", "cell_measures": "area: areacellg", - "long_name": "Basal temperature of floating ice shelf", + "long_name": "Basal Temperature of Floating Ice Shelf", "comment": "Basal temperature that is used to force the ice sheet models, it is the temperature AT ice shelf-ocean interface. Cell_methods: area: mean where floating_ice_shelf", "dimensions": "xant yant time", "out_name": "litempbotfl", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -219,16 +213,17 @@ "ok_max_mean_abs": "" }, "litempbotgr": { + "frequency": "yr", "modeling_realm": "landIce", "standard_name": "land_ice_basal_temperature", "units": "K", "cell_methods": "area: time: mean where grounded_ice_sheet (comment: mask=sfgrlf)", "cell_measures": "area: areacellg", - "long_name": "Basal temperature of grounded ice sheet", + "long_name": "Basal Temperature of Grounded Ice Sheet", "comment": "Basal temperature that is used to force the ice sheet models, it is the temperature AT ice sheet - bedrock interface. Cell_methods: area: mean where grounded_ice_sheet", "dimensions": "xant yant time", "out_name": "litempbotgr", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -236,16 +231,17 @@ "ok_max_mean_abs": "" }, "litemptop": { + "frequency": "yr", "modeling_realm": "landIce", "standard_name": "temperature_at_top_of_ice_sheet_model", "units": "K", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", - "long_name": "Temperature at top of ice sheet model", + "long_name": "Temperature at Top of Ice Sheet Model", "comment": "Upper boundary temperature that is used to force ice sheet models. It is the temperature at the base of the snowpack models, and does not vary with seasons. Report surface temperature of ice sheet where snow thickness is zero", "dimensions": "xant yant time", "out_name": "litemptop", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -253,16 +249,35 @@ "ok_max_mean_abs": "" }, "lithk": { + "frequency": "yr", "modeling_realm": "landIce", "standard_name": "land_ice_thickness", "units": "m", - "cell_methods": "area: time: mean where ice_sheet", + "cell_methods": "area: mean where grounded_ice_sheet", "cell_measures": "area: areacellg", "long_name": "Ice Sheet Thickness", "comment": "The thickness of the ice sheet", - "dimensions": "xant yant time", + "dimensions": "xant yant", "out_name": "lithk", - "type": "", + "type": "real", + "positive": "", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, + "modelCellAreai": { + "frequency": "yr", + "modeling_realm": "landIce", + "standard_name": "cell_area", + "units": "m2", + "cell_methods": "area: time: mean", + "cell_measures": "area: areacellg", + "long_name": "The Cell Area of the Ice Sheet Model", + "comment": "Horizontal area of ice-sheet grid cells", + "dimensions": "xant yant time", + "out_name": "modelCellAreai", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -270,6 +285,7 @@ "ok_max_mean_abs": "" }, "orog": { + "frequency": "yr", "modeling_realm": "land", "standard_name": "surface_altitude", "units": "m", @@ -287,16 +303,17 @@ "ok_max_mean_abs": "" }, "sftflf": { + "frequency": "yr", "modeling_realm": "landIce", "standard_name": "floating_ice_shelf_area_fraction", "units": "%", "cell_methods": "area: time: mean", "cell_measures": "area: areacellg", - "long_name": "Floating Ice Shelf Area Fraction", - "comment": "Fraction of grid cell covered by floating ice shelf, the component of the ice sheet that is flowing over seawater", - "dimensions": "xant yant time typefis", + "long_name": "Floating Ice Shelf Area Percentage", + "comment": "Percentage of grid cell covered by floating ice shelf, the component of the ice sheet that is flowing over sea water", + "dimensions": "xant yant time", "out_name": "sftflf", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -304,14 +321,15 @@ "ok_max_mean_abs": "" }, "sftgif": { + "frequency": "yr", "modeling_realm": "land", "standard_name": "land_ice_area_fraction", "units": "%", "cell_methods": "area: time: mean", "cell_measures": "area: areacellg", - "long_name": "Fraction of Grid Cell Covered with Glacier", - "comment": "Fraction of grid cell covered by land ice (ice sheet, ice shelf, ice cap, glacier)", - "dimensions": "xant yant time typeli", + "long_name": "Land Ice Area Percentage", + "comment": "Percentage of grid cell covered by land ice (ice sheet, ice shelf, ice cap, glacier)", + "dimensions": "xant yant time", "out_name": "sftgif", "type": "real", "positive": "", @@ -321,16 +339,17 @@ "ok_max_mean_abs": "" }, "sftgrf": { + "frequency": "yr", "modeling_realm": "landIce", "standard_name": "grounded_ice_sheet_area_fraction", "units": "%", "cell_methods": "area: time: mean", "cell_measures": "area: areacellg", - "long_name": "Grounded Ice Sheet Area Fraction", - "comment": "Fraction of grid cell covered by grounded ice sheet", - "dimensions": "xant yant time typegis", + "long_name": "Grounded Ice Sheet Area Percentage", + "comment": "Percentage of grid cell covered by grounded ice sheet", + "dimensions": "xant yant time", "out_name": "sftgrf", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -338,16 +357,17 @@ "ok_max_mean_abs": "" }, "snc": { - "modeling_realm": "landIce land", + "frequency": "yr", + "modeling_realm": "landIce", "standard_name": "surface_snow_area_fraction", "units": "%", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", - "long_name": "snow cover fraction", - "comment": "Fraction of each grid cell that is occupied by snow that rests on land portion of cell.", + "long_name": "Snow Area Percentage", + "comment": "Percentage of each grid cell that is occupied by snow that rests on land portion of cell.", "dimensions": "xant yant time", "out_name": "snc", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -355,8 +375,9 @@ "ok_max_mean_abs": "" }, "strbasemag": { + "frequency": "yr", "modeling_realm": "landIce", - "standard_name": "magnitude_of_basal_drag_at_land_ice_base", + "standard_name": "land_ice_basal_drag", "units": "Pa", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", @@ -364,7 +385,7 @@ "comment": "Magnitude of basal drag at land ice base", "dimensions": "xant yant time", "out_name": "strbasemag", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -372,16 +393,17 @@ "ok_max_mean_abs": "" }, "tendacabf": { - "modeling_realm": "atmos", + "frequency": "yr", + "modeling_realm": "landIce", "standard_name": "tendency_of_land_ice_mass_due_to_surface_mass_balance", "units": "kg s-1", - "cell_methods": "area: time: mean where ice_sheet", + "cell_methods": "area: sum where ice_sheet time: mean", "cell_measures": "", - "long_name": "Total surface mass balance flux", + "long_name": "Total Surface Mass Balance Flux", "comment": "The total surface mass balance flux over land ice is a spatial integration of the surface mass balance flux", "dimensions": "time", "out_name": "tendacabf", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -389,16 +411,17 @@ "ok_max_mean_abs": "" }, "tendlibmassbf": { - "modeling_realm": "atmos", + "frequency": "yr", + "modeling_realm": "landIce", "standard_name": "tendency_of_land_ice_mass_due_to_basal_mass_balance", "units": "kg s-1", - "cell_methods": "area: time: mean where ice_sheet", + "cell_methods": "area: sum where ice_sheet time: mean", "cell_measures": "", - "long_name": "Total basal mass balance flux", + "long_name": "Total Basal Mass Balance Flux", "comment": "The total basal mass balance flux over land ice is a spatial integration of the basal mass balance flux", "dimensions": "time", "out_name": "tendlibmassbf", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -406,16 +429,17 @@ "ok_max_mean_abs": "" }, "tendlicalvf": { - "modeling_realm": "atmos", + "frequency": "yr", + "modeling_realm": "landIce", "standard_name": "tendency_of_land_ice_mass_due_to_calving", "units": "kg s-1", - "cell_methods": "area: time: mean where ice_sheet", + "cell_methods": "area: sum where ice_sheet time: mean", "cell_measures": "", - "long_name": "Total calving flux", + "long_name": "Total Calving Flux", "comment": "The total calving flux over land ice is a spatial integration of the calving flux", "dimensions": "time", "out_name": "tendlicalvf", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -423,6 +447,7 @@ "ok_max_mean_abs": "" }, "topg": { + "frequency": "yr", "modeling_realm": "landIce", "standard_name": "bedrock_altitude", "units": "m", @@ -432,7 +457,7 @@ "comment": "The bedrock topography beneath the land ice", "dimensions": "xant yant time", "out_name": "topg", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -440,16 +465,17 @@ "ok_max_mean_abs": "" }, "xvelbase": { + "frequency": "yr", "modeling_realm": "landIce", "standard_name": "land_ice_basal_x_velocity", "units": "m s-1", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", - "long_name": "X-component of land ice basal velocity", + "long_name": "X-Component of Land Ice Basal Velocity", "comment": "A velocity is a vector quantity. 'x' indicates a vector component along the grid x-axis, positive with increasing x. 'Land ice' means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves. 'basal' means the lower boundary of the land ice.", "dimensions": "xant yant time", "out_name": "xvelbase", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -457,16 +483,17 @@ "ok_max_mean_abs": "" }, "xvelmean": { + "frequency": "yr", "modeling_realm": "landIce", "standard_name": "land_ice_vertical_mean_x_velocity", "units": "m s-1", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", - "long_name": "X-component of land ice vertical mean velocity", + "long_name": "X-Component of Land Ice Vertical Mean Velocity", "comment": "The vertical mean land ice velocity is the average from the bedrock to the surface of the ice", "dimensions": "xant yant time", "out_name": "xvelmean", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -474,16 +501,17 @@ "ok_max_mean_abs": "" }, "xvelsurf": { + "frequency": "yr", "modeling_realm": "landIce", "standard_name": "land_ice_surface_x_velocity", "units": "m s-1", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", - "long_name": "X-component of land ice surface velocity", + "long_name": "X-Component of Land Ice Surface Velocity", "comment": "A velocity is a vector quantity. 'x' indicates a vector component along the grid x-axis, positive with increasing x. 'Land ice' means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves. The surface called 'surface' means the lower boundary of the atmosphere.", "dimensions": "xant yant time", "out_name": "xvelsurf", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -491,16 +519,17 @@ "ok_max_mean_abs": "" }, "yvelbase": { + "frequency": "yr", "modeling_realm": "landIce", "standard_name": "land_ice_basal_y_velocity", "units": "m s-1", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", - "long_name": "Y-component of land ice basal velocity", + "long_name": "Y-Component of Land Ice Basal Velocity", "comment": "A velocity is a vector quantity. 'y' indicates a vector component along the grid y-axis, positive with increasing y. 'Land ice' means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves. 'basal' means the lower boundary of the land ice.", "dimensions": "xant yant time", "out_name": "yvelbase", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -508,16 +537,17 @@ "ok_max_mean_abs": "" }, "yvelmean": { + "frequency": "yr", "modeling_realm": "landIce", "standard_name": "land_ice_vertical_mean_y_velocity", "units": "m s-1", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", - "long_name": "Y-component of land ice vertical mean velocity", + "long_name": "Y-Component of Land Ice Vertical Mean Velocity", "comment": "The vertical mean land ice velocity is the average from the bedrock to the surface of the ice", "dimensions": "xant yant time", "out_name": "yvelmean", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -525,16 +555,17 @@ "ok_max_mean_abs": "" }, "yvelsurf": { + "frequency": "yr", "modeling_realm": "landIce", "standard_name": "land_ice_surface_y_velocity", "units": "m s-1", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", - "long_name": "Y-component of land ice surface velocity", + "long_name": "Y-Component of Land Ice Surface Velocity", "comment": "A velocity is a vector quantity. 'y' indicates a vector component along the grid y-axis, positive with increasing y. 'Land ice' means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves. The surface called 'surface' means the lower boundary of the atmosphere.'", "dimensions": "xant yant time", "out_name": "yvelsurf", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -542,16 +573,17 @@ "ok_max_mean_abs": "" }, "zvelbase": { + "frequency": "yr", "modeling_realm": "landIce", "standard_name": "land_ice_basal_upward_velocity", "units": "m s-1", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", - "long_name": "Upward-component of land ice basal velocity", + "long_name": "Upward Component of Land-Ice Basal Velocity", "comment": "A velocity is a vector quantity. 'Upward' indicates a vector component which is positive when directed upward (negative downward). 'basal' means the lower boundary of the atmosphere", "dimensions": "xant yant time", "out_name": "zvelbase", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -559,16 +591,17 @@ "ok_max_mean_abs": "" }, "zvelsurf": { + "frequency": "yr", "modeling_realm": "landIce", "standard_name": "land_ice_surface_upward_velocity", "units": "m s-1", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", - "long_name": "Upward component of land ice surface velocity", + "long_name": "Upward Component of Land-Ice Surface Velocity", "comment": "A velocity is a vector quantity. 'Upward' indicates a vector component which is positive when directed upward (negative downward). The surface called 'surface' means the lower boundary of the atmosphere", "dimensions": "xant yant time", "out_name": "zvelsurf", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_IyrGre.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_IyrGre.json index c134ae3bc7..bde9abd23c 100644 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_IyrGre.json +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_IyrGre.json @@ -1,47 +1,31 @@ { "Header": { - "data_specs_version": "01.00.10", + "data_specs_version": "01.00.30", + "cmor_version": "3.4", "table_id": "Table IyrGre", "realm": "landIce", - "frequency": "yr", - "cmor_version": "3.2", - "table_date": "10 May 2017", + "table_date": "11 March 2019", "missing_value": "1e20", + "int_missing_value": "-999", "product": "model-output", "approx_interval": "365.00", "generic_levels": "", "mip_era": "CMIP6", - "Conventions": "CF-1.7 CMIP-6.0" + "Conventions": "CF-1.7 CMIP-6.2" }, "variable_entry": { "acabf": { + "frequency": "yr", "modeling_realm": "landIce", "standard_name": "land_ice_surface_specific_mass_balance_flux", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", - "long_name": "Surface Mass Balance flux", + "long_name": "Surface Mass Balance Flux", "comment": "Specific mass balance means the net rate at which ice is added per unit area at the land ice surface. Computed as the total surface mass balance on the land ice portion of the grid cell divided by land ice area in the grid cell. A negative value means loss of ice", "dimensions": "xgre ygre time", "out_name": "acabf", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "areacelli": { - "modeling_realm": "landIce", - "standard_name": "cell_area", - "units": "m2", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacellg", - "long_name": "Ice-Sheet Grid Cell Area", - "comment": "Horizontal area of ice-sheet grid cells", - "dimensions": "xgre ygre time", - "out_name": "areacelli", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -49,16 +33,17 @@ "ok_max_mean_abs": "" }, "hfgeoubed": { + "frequency": "yr", "modeling_realm": "landIce", "standard_name": "upward_geothermal_heat_flux_at_ground_level_in_land_ice", "units": "W m-2", - "cell_methods": "area: time: mean where ice_sheet", + "cell_methods": "area: mean where grounded_ice_sheet", "cell_measures": "area: areacellg", - "long_name": "Geothermal Heat flux beneath land ice", + "long_name": "Geothermal Heat Flux Beneath Land Ice", "comment": "Upward geothermal heat flux per unit area beneath land ice", - "dimensions": "xgre ygre time", + "dimensions": "xgre ygre", "out_name": "hfgeoubed", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -66,16 +51,17 @@ "ok_max_mean_abs": "" }, "iareafl": { - "modeling_realm": "atmos", + "frequency": "yr", + "modeling_realm": "landIce", "standard_name": "floating_ice_shelf_area", "units": "m2", "cell_methods": "area: time: mean where floating_ice_shelf (comment: mask=sftflf)", "cell_measures": "", - "long_name": "Area covered by floating ice shelves", + "long_name": "Area Covered by Floating Ice Shelves", "comment": "Total area of the floating ice shelves (the component of ice sheet that flows over ocean)", "dimensions": "time", "out_name": "iareafl", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -83,16 +69,17 @@ "ok_max_mean_abs": "" }, "iareagr": { - "modeling_realm": "atmos", + "frequency": "yr", + "modeling_realm": "landIce", "standard_name": "grounded_ice_sheet_area", "units": "m2", "cell_methods": "area: time: mean where grounded_ice_sheet (comment: mask=sfgrlf)", "cell_measures": "", - "long_name": "Area covered by grounded ice sheet", + "long_name": "Area Covered by Grounded Ice Sheet", "comment": "Total area of the grounded ice sheets (the component of ice sheet resting over bedrock)", "dimensions": "time", "out_name": "iareagr", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -100,16 +87,17 @@ "ok_max_mean_abs": "" }, "libmassbffl": { + "frequency": "yr", "modeling_realm": "landIce", "standard_name": "land_ice_basal_specific_mass_balance_flux", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where floating_ice_shelf (comment: mask=sftflf)", "cell_measures": "area: areacellg", - "long_name": "Basal specific mass balance flux of floating ice shelf", + "long_name": "Basal Specific Mass Balance Flux of Floating Ice Shelf", "comment": "Specific mass balance means the net rate at which ice is added per unit area at the land ice base. A negative value means loss of ice. Computed as the total basal mass balance on the floating land ice (floating ice shelf) portion of the grid cell divided by floating land ice (floating ice shelf) area in the grid cell. Cell_methods: area: mean where floating_ice_shelf", "dimensions": "xgre ygre time", "out_name": "libmassbffl", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -117,16 +105,17 @@ "ok_max_mean_abs": "" }, "libmassbfgr": { + "frequency": "yr", "modeling_realm": "landIce", "standard_name": "land_ice_basal_specific_mass_balance_flux", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where grounded_ice_sheet (comment: mask=sfgrlf)", "cell_measures": "area: areacellg", - "long_name": "Basal specific mass balance flux of grounded ice sheet", + "long_name": "Basal Specific Mass Balance Flux of Grounded Ice Sheet", "comment": "Specific mass balance means the net rate at which ice is added per unit area at the land ice base. A negative value means loss of ice. Computed as the total basal mass balance on the grounded land ice portion of the grid cell divided by grounded land ice area in the grid cell. Cell_methods: area: mean where grounded_ice_sheet", "dimensions": "xgre ygre time", "out_name": "libmassbfgr", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -134,16 +123,17 @@ "ok_max_mean_abs": "" }, "licalvf": { + "frequency": "yr", "modeling_realm": "landIce", "standard_name": "land_ice_specific_mass_flux_due_to_calving", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", - "long_name": "Land ice calving flux", + "long_name": "Land Ice Calving Flux", "comment": "Loss of ice mass resulting from iceberg calving. Computed as the rate of mass loss by the ice shelf (in kg s-1) divided by the horizontal area of the ice sheet (m2) in the grid box.", "dimensions": "xgre ygre time", "out_name": "licalvf", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -151,16 +141,17 @@ "ok_max_mean_abs": "" }, "lifmassbf": { + "frequency": "yr", "modeling_realm": "landIce", "standard_name": "land_ice_specific_mass_flux_due_to_calving_and_ice_front_melting", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", - "long_name": "Land ice vertical front mass balance flux", + "long_name": "Land Ice Vertical Front Mass Balance Flux", "comment": "Total mass balance at the ice front (or vertical margin). It includes both iceberg calving and melt on vertical ice front", "dimensions": "xgre ygre time", "out_name": "lifmassbf", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -168,16 +159,17 @@ "ok_max_mean_abs": "" }, "lim": { - "modeling_realm": "atmos", + "frequency": "yr", + "modeling_realm": "landIce", "standard_name": "land_ice_mass", "units": "kg", - "cell_methods": "area: time: mean where ice_sheet", + "cell_methods": "area: sum where ice_sheet time: mean", "cell_measures": "", - "long_name": "Ice sheet mass", + "long_name": "Ice Sheet Mass", "comment": "The ice sheet mass is computed as the volume times density", "dimensions": "time", "out_name": "lim", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -185,16 +177,17 @@ "ok_max_mean_abs": "" }, "limnsw": { - "modeling_realm": "atmos", + "frequency": "yr", + "modeling_realm": "landIce", "standard_name": "land_ice_mass_not_displacing_sea_water", "units": "kg", "cell_methods": "area: time: mean where grounded_ice_sheet (comment: mask=sfgrlf)", "cell_measures": "", - "long_name": "Ice sheet mass that does not displace sea water", + "long_name": "Ice Sheet Mass That Does not Displace Sea Water", "comment": "The ice sheet mass is computed as the volume above flotation times density. Changes in land_ice_mass_not_displacing_sea_water will always result in a change in sea level, unlike changes in land_ice_mass which may not result in sea level change (such as melting of the floating ice shelves, or portion of ice that sits on bedrock below sea level)", "dimensions": "time", "out_name": "limnsw", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -202,16 +195,17 @@ "ok_max_mean_abs": "" }, "litempbotfl": { + "frequency": "yr", "modeling_realm": "landIce", "standard_name": "land_ice_basal_temperature", "units": "K", "cell_methods": "area: time: mean where floating_ice_shelf (comment: mask=sftflf)", "cell_measures": "area: areacellg", - "long_name": "Basal temperature of floating ice shelf", + "long_name": "Basal Temperature of Floating Ice Shelf", "comment": "Basal temperature that is used to force the ice sheet models, it is the temperature AT ice shelf-ocean interface. Cell_methods: area: mean where floating_ice_shelf", "dimensions": "xgre ygre time", "out_name": "litempbotfl", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -219,16 +213,17 @@ "ok_max_mean_abs": "" }, "litempbotgr": { + "frequency": "yr", "modeling_realm": "landIce", "standard_name": "land_ice_basal_temperature", "units": "K", "cell_methods": "area: time: mean where grounded_ice_sheet (comment: mask=sfgrlf)", "cell_measures": "area: areacellg", - "long_name": "Basal temperature of grounded ice sheet", + "long_name": "Basal Temperature of Grounded Ice Sheet", "comment": "Basal temperature that is used to force the ice sheet models, it is the temperature AT ice sheet - bedrock interface. Cell_methods: area: mean where grounded_ice_sheet", "dimensions": "xgre ygre time", "out_name": "litempbotgr", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -236,16 +231,17 @@ "ok_max_mean_abs": "" }, "litemptop": { + "frequency": "yr", "modeling_realm": "landIce", "standard_name": "temperature_at_top_of_ice_sheet_model", "units": "K", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", - "long_name": "Temperature at top of ice sheet model", + "long_name": "Temperature at Top of Ice Sheet Model", "comment": "Upper boundary temperature that is used to force ice sheet models. It is the temperature at the base of the snowpack models, and does not vary with seasons. Report surface temperature of ice sheet where snow thickness is zero", "dimensions": "xgre ygre time", "out_name": "litemptop", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -253,16 +249,35 @@ "ok_max_mean_abs": "" }, "lithk": { + "frequency": "yr", "modeling_realm": "landIce", "standard_name": "land_ice_thickness", "units": "m", - "cell_methods": "area: time: mean where ice_sheet", + "cell_methods": "area: mean where grounded_ice_sheet", "cell_measures": "area: areacellg", "long_name": "Ice Sheet Thickness", "comment": "The thickness of the ice sheet", - "dimensions": "xgre ygre time", + "dimensions": "xgre ygre", "out_name": "lithk", - "type": "", + "type": "real", + "positive": "", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, + "modelCellAreai": { + "frequency": "yr", + "modeling_realm": "landIce", + "standard_name": "cell_area", + "units": "m2", + "cell_methods": "area: time: mean", + "cell_measures": "area: areacellg", + "long_name": "The Cell Area of the Ice Sheet Model", + "comment": "Horizontal area of ice-sheet grid cells", + "dimensions": "xgre ygre time", + "out_name": "modelCellAreai", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -270,6 +285,7 @@ "ok_max_mean_abs": "" }, "orog": { + "frequency": "yr", "modeling_realm": "land", "standard_name": "surface_altitude", "units": "m", @@ -287,16 +303,17 @@ "ok_max_mean_abs": "" }, "sftflf": { + "frequency": "yr", "modeling_realm": "landIce", "standard_name": "floating_ice_shelf_area_fraction", "units": "%", "cell_methods": "area: time: mean", "cell_measures": "area: areacellg", - "long_name": "Floating Ice Shelf Area Fraction", - "comment": "Fraction of grid cell covered by floating ice shelf, the component of the ice sheet that is flowing over seawater", - "dimensions": "xgre ygre time typefis", + "long_name": "Floating Ice Shelf Area Percentage", + "comment": "Percentage of grid cell covered by floating ice shelf, the component of the ice sheet that is flowing over sea water", + "dimensions": "xgre ygre time", "out_name": "sftflf", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -304,14 +321,15 @@ "ok_max_mean_abs": "" }, "sftgif": { + "frequency": "yr", "modeling_realm": "land", "standard_name": "land_ice_area_fraction", "units": "%", "cell_methods": "area: time: mean", "cell_measures": "area: areacellg", - "long_name": "Fraction of Grid Cell Covered with Glacier", - "comment": "Fraction of grid cell covered by land ice (ice sheet, ice shelf, ice cap, glacier)", - "dimensions": "xgre ygre time typeli", + "long_name": "Land Ice Area Percentage", + "comment": "Percentage of grid cell covered by land ice (ice sheet, ice shelf, ice cap, glacier)", + "dimensions": "xgre ygre time", "out_name": "sftgif", "type": "real", "positive": "", @@ -321,16 +339,17 @@ "ok_max_mean_abs": "" }, "sftgrf": { + "frequency": "yr", "modeling_realm": "landIce", "standard_name": "grounded_ice_sheet_area_fraction", "units": "%", "cell_methods": "area: time: mean", "cell_measures": "area: areacellg", - "long_name": "Grounded Ice Sheet Area Fraction", - "comment": "Fraction of grid cell covered by grounded ice sheet", - "dimensions": "xgre ygre time typegis", + "long_name": "Grounded Ice Sheet Area Percentage", + "comment": "Percentage of grid cell covered by grounded ice sheet", + "dimensions": "xgre ygre time", "out_name": "sftgrf", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -338,16 +357,17 @@ "ok_max_mean_abs": "" }, "snc": { + "frequency": "yr", "modeling_realm": "landIce land", "standard_name": "surface_snow_area_fraction", "units": "%", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", - "long_name": "snow cover fraction", - "comment": "Fraction of each grid cell that is occupied by snow that rests on land portion of cell.", + "long_name": "Snow Area Percentage", + "comment": "Percentage of each grid cell that is occupied by snow that rests on land portion of cell.", "dimensions": "xgre ygre time", "out_name": "snc", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -355,8 +375,9 @@ "ok_max_mean_abs": "" }, "strbasemag": { + "frequency": "yr", "modeling_realm": "landIce", - "standard_name": "magnitude_of_basal_drag_at_land_ice_base", + "standard_name": "land_ice_basal_drag", "units": "Pa", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", @@ -364,7 +385,7 @@ "comment": "Magnitude of basal drag at land ice base", "dimensions": "xgre ygre time", "out_name": "strbasemag", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -372,16 +393,17 @@ "ok_max_mean_abs": "" }, "tendacabf": { - "modeling_realm": "atmos", + "frequency": "yr", + "modeling_realm": "landIce", "standard_name": "tendency_of_land_ice_mass_due_to_surface_mass_balance", "units": "kg s-1", - "cell_methods": "area: time: mean where ice_sheet", + "cell_methods": "area: sum where ice_sheet time: mean", "cell_measures": "", - "long_name": "Total surface mass balance flux", + "long_name": "Total Surface Mass Balance Flux", "comment": "The total surface mass balance flux over land ice is a spatial integration of the surface mass balance flux", "dimensions": "time", "out_name": "tendacabf", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -389,16 +411,17 @@ "ok_max_mean_abs": "" }, "tendlibmassbf": { - "modeling_realm": "atmos", + "frequency": "yr", + "modeling_realm": "landIce", "standard_name": "tendency_of_land_ice_mass_due_to_basal_mass_balance", "units": "kg s-1", - "cell_methods": "area: time: mean where ice_sheet", + "cell_methods": "area: sum where ice_sheet time: mean", "cell_measures": "", - "long_name": "Total basal mass balance flux", + "long_name": "Total Basal Mass Balance Flux", "comment": "The total basal mass balance flux over land ice is a spatial integration of the basal mass balance flux", "dimensions": "time", "out_name": "tendlibmassbf", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -406,16 +429,17 @@ "ok_max_mean_abs": "" }, "tendlicalvf": { - "modeling_realm": "atmos", + "frequency": "yr", + "modeling_realm": "landIce", "standard_name": "tendency_of_land_ice_mass_due_to_calving", "units": "kg s-1", - "cell_methods": "area: time: mean where ice_sheet", + "cell_methods": "area: sum where ice_sheet time: mean", "cell_measures": "", - "long_name": "Total calving flux", + "long_name": "Total Calving Flux", "comment": "The total calving flux over land ice is a spatial integration of the calving flux", "dimensions": "time", "out_name": "tendlicalvf", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -423,6 +447,7 @@ "ok_max_mean_abs": "" }, "topg": { + "frequency": "yr", "modeling_realm": "landIce", "standard_name": "bedrock_altitude", "units": "m", @@ -432,7 +457,7 @@ "comment": "The bedrock topography beneath the land ice", "dimensions": "xgre ygre time", "out_name": "topg", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -440,16 +465,17 @@ "ok_max_mean_abs": "" }, "xvelbase": { + "frequency": "yr", "modeling_realm": "landIce", "standard_name": "land_ice_basal_x_velocity", "units": "m s-1", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", - "long_name": "X-component of land ice basal velocity", + "long_name": "X-Component of Land Ice Basal Velocity", "comment": "A velocity is a vector quantity. 'x' indicates a vector component along the grid x-axis, positive with increasing x. 'Land ice' means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves. 'basal' means the lower boundary of the land ice.", "dimensions": "xgre ygre time", "out_name": "xvelbase", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -457,16 +483,17 @@ "ok_max_mean_abs": "" }, "xvelmean": { + "frequency": "yr", "modeling_realm": "landIce", "standard_name": "land_ice_vertical_mean_x_velocity", "units": "m s-1", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", - "long_name": "X-component of land ice vertical mean velocity", + "long_name": "X-Component of Land Ice Vertical Mean Velocity", "comment": "The vertical mean land ice velocity is the average from the bedrock to the surface of the ice", "dimensions": "xgre ygre time", "out_name": "xvelmean", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -474,16 +501,17 @@ "ok_max_mean_abs": "" }, "xvelsurf": { + "frequency": "yr", "modeling_realm": "landIce", "standard_name": "land_ice_surface_x_velocity", "units": "m s-1", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", - "long_name": "X-component of land ice surface velocity", + "long_name": "X-Component of Land Ice Surface Velocity", "comment": "A velocity is a vector quantity. 'x' indicates a vector component along the grid x-axis, positive with increasing x. 'Land ice' means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves. The surface called 'surface' means the lower boundary of the atmosphere.", "dimensions": "xgre ygre time", "out_name": "xvelsurf", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -491,16 +519,17 @@ "ok_max_mean_abs": "" }, "yvelbase": { + "frequency": "yr", "modeling_realm": "landIce", "standard_name": "land_ice_basal_y_velocity", "units": "m s-1", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", - "long_name": "Y-component of land ice basal velocity", + "long_name": "Y-Component of Land Ice Basal Velocity", "comment": "A velocity is a vector quantity. 'y' indicates a vector component along the grid y-axis, positive with increasing y. 'Land ice' means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves. 'basal' means the lower boundary of the land ice.", "dimensions": "xgre ygre time", "out_name": "yvelbase", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -508,16 +537,17 @@ "ok_max_mean_abs": "" }, "yvelmean": { + "frequency": "yr", "modeling_realm": "landIce", "standard_name": "land_ice_vertical_mean_y_velocity", "units": "m s-1", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", - "long_name": "Y-component of land ice vertical mean velocity", + "long_name": "Y-Component of Land Ice Vertical Mean Velocity", "comment": "The vertical mean land ice velocity is the average from the bedrock to the surface of the ice", "dimensions": "xgre ygre time", "out_name": "yvelmean", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -525,16 +555,17 @@ "ok_max_mean_abs": "" }, "yvelsurf": { + "frequency": "yr", "modeling_realm": "landIce", "standard_name": "land_ice_surface_y_velocity", "units": "m s-1", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", - "long_name": "Y-component of land ice surface velocity", + "long_name": "Y-Component of Land Ice Surface Velocity", "comment": "A velocity is a vector quantity. 'y' indicates a vector component along the grid y-axis, positive with increasing y. 'Land ice' means glaciers, ice-caps and ice-sheets resting on bedrock and also includes ice-shelves. The surface called 'surface' means the lower boundary of the atmosphere.'", "dimensions": "xgre ygre time", "out_name": "yvelsurf", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -542,16 +573,17 @@ "ok_max_mean_abs": "" }, "zvelbase": { + "frequency": "yr", "modeling_realm": "landIce", "standard_name": "land_ice_basal_upward_velocity", "units": "m s-1", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", - "long_name": "Upward-component of land ice basal velocity", + "long_name": "Upward Component of Land-Ice Basal Velocity", "comment": "A velocity is a vector quantity. 'Upward' indicates a vector component which is positive when directed upward (negative downward). 'basal' means the lower boundary of the atmosphere", "dimensions": "xgre ygre time", "out_name": "zvelbase", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -559,16 +591,17 @@ "ok_max_mean_abs": "" }, "zvelsurf": { + "frequency": "yr", "modeling_realm": "landIce", "standard_name": "land_ice_surface_upward_velocity", "units": "m s-1", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacellg", - "long_name": "Upward component of land ice surface velocity", + "long_name": "Upward Component of Land-Ice Surface Velocity", "comment": "A velocity is a vector quantity. 'Upward' indicates a vector component which is positive when directed upward (negative downward). The surface called 'surface' means the lower boundary of the atmosphere", "dimensions": "xgre ygre time", "out_name": "zvelsurf", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_LImon.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_LImon.json index d2897e68e1..b504dd89f6 100644 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_LImon.json +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_LImon.json @@ -1,30 +1,31 @@ { "Header": { - "data_specs_version": "01.00.10", + "data_specs_version": "01.00.30", + "cmor_version": "3.4", "table_id": "Table LImon", "realm": "landIce land", - "frequency": "mon", - "cmor_version": "3.2", - "table_date": "10 May 2017", + "table_date": "11 March 2019", "missing_value": "1e20", + "int_missing_value": "-999", "product": "model-output", "approx_interval": "30.00000", "generic_levels": "", "mip_era": "CMIP6", - "Conventions": "CF-1.7 CMIP-6.0" + "Conventions": "CF-1.7 CMIP-6.2" }, "variable_entry": { "acabfIs": { + "frequency": "mon", "modeling_realm": "landIce", "standard_name": "land_ice_surface_specific_mass_balance_flux", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacella", - "long_name": "Ice Sheet Surface Mass Balance flux", + "long_name": "Ice Sheet Surface Mass Balance Flux", "comment": "Specific mass balance means the net rate at which ice is added per unit area at the land ice surface. Computed as the total surface mass balance on the land ice portion of the grid cell divided by land ice area in the grid cell. A negative value means loss of ice", "dimensions": "longitude latitude time", "out_name": "acabfIs", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -32,12 +33,13 @@ "ok_max_mean_abs": "" }, "agesno": { + "frequency": "mon", "modeling_realm": "landIce land", "standard_name": "age_of_surface_snow", "units": "day", "cell_methods": "area: mean where land time: mean (with samples weighted by snow mass)", "cell_measures": "area: areacella", - "long_name": "Snow Age", + "long_name": "Mean Age of Snow", "comment": "Age of Snow (when computing the time-mean here, the time samples, weighted by the mass of snow on the land portion of the grid cell, are accumulated and then divided by the sum of the weights. Reported as missing data in regions free of snow on land.", "dimensions": "longitude latitude time", "out_name": "agesno", @@ -49,6 +51,7 @@ "ok_max_mean_abs": "" }, "hfdsn": { + "frequency": "mon", "modeling_realm": "landIce land", "standard_name": "surface_downward_heat_flux_in_snow", "units": "W m-2", @@ -66,6 +69,7 @@ "ok_max_mean_abs": "" }, "hflsIs": { + "frequency": "mon", "modeling_realm": "landIce", "standard_name": "surface_upward_latent_heat_flux", "units": "W m-2", @@ -75,31 +79,33 @@ "comment": "Upward latent heat flux from the ice sheet surface", "dimensions": "longitude latitude time", "out_name": "hflsIs", - "type": "", - "positive": "", + "type": "real", + "positive": "up", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "hfssIs": { + "frequency": "mon", "modeling_realm": "landIce", "standard_name": "surface_upward_sensible_heat_flux", "units": "W m-2", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacella", "long_name": "Ice Sheet Surface Upward Sensible Heat Flux", - "comment": "Upward sensible heat flux from the ice sheet surface", + "comment": "Upward sensible heat flux from the ice sheet surface. The surface sensible heat flux, also called turbulent heat flux, is the exchange of heat between the surface and the air by motion of air.", "dimensions": "longitude latitude time", "out_name": "hfssIs", - "type": "", - "positive": "", + "type": "real", + "positive": "up", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "icemIs": { + "frequency": "mon", "modeling_realm": "landIce", "standard_name": "land_ice_surface_melt_flux", "units": "kg m-2 s-1", @@ -109,24 +115,7 @@ "comment": "Loss of ice mass resulting from surface melting. Computed as the total surface melt water on the land ice portion of the grid cell divided by land ice area in the grid cell.", "dimensions": "longitude latitude time", "out_name": "icemIs", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "lialbIs": { - "modeling_realm": "landIce", - "standard_name": "surface_albedo", - "units": "1.0", - "cell_methods": "area: time: mean where ice_sheet", - "cell_measures": "area: areacella", - "long_name": "Ice Sheet Ice or Snow Albedo", - "comment": "Mean surface albedo of entire land ice covered part of the grid cell", - "dimensions": "longitude latitude time", - "out_name": "lialbIs", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -134,16 +123,17 @@ "ok_max_mean_abs": "" }, "litemptopIs": { + "frequency": "mon", "modeling_realm": "landIce", "standard_name": "temperature_at_top_of_ice_sheet_model", "units": "K", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacella", - "long_name": "Ice Sheet Temperature at top of ice sheet model", + "long_name": "Ice Sheet Temperature at Top of Ice Sheet Model", "comment": "Upper boundary temperature that is used to force ice sheet models. It is the temperature at the base of the snowpack models, and does not vary with seasons. Report surface temperature of ice sheet where snow thickness is zero", "dimensions": "longitude latitude time", "out_name": "litemptopIs", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -151,8 +141,9 @@ "ok_max_mean_abs": "" }, "lwsnl": { + "frequency": "mon", "modeling_realm": "landIce land", - "standard_name": "liquid_water_content_of_snow_layer", + "standard_name": "liquid_water_content_of_surface_snow", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", @@ -168,16 +159,17 @@ "ok_max_mean_abs": "" }, "mrroIs": { + "frequency": "mon", "modeling_realm": "landIce", "standard_name": "runoff_flux", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacella", - "long_name": "Ice Sheet Total Run-off", + "long_name": "Ice Sheet Total Runoff", "comment": "The total run-off (including drainage through the base of the soil model) per unit area leaving the land portion of the grid cell.", "dimensions": "longitude latitude time", "out_name": "mrroIs", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -185,6 +177,7 @@ "ok_max_mean_abs": "" }, "orogIs": { + "frequency": "mon", "modeling_realm": "landIce", "standard_name": "surface_altitude", "units": "m", @@ -194,7 +187,7 @@ "comment": "The surface called 'surface' means the lower boundary of the atmosphere. Altitude is the (geometric) height above the geoid, which is the reference geopotential surface. The geoid is similar to mean sea level.", "dimensions": "longitude latitude time", "out_name": "orogIs", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -202,6 +195,7 @@ "ok_max_mean_abs": "" }, "pflw": { + "frequency": "mon", "modeling_realm": "landIce land", "standard_name": "liquid_water_content_of_permafrost_layer", "units": "kg m-2", @@ -219,16 +213,17 @@ "ok_max_mean_abs": "" }, "prraIs": { + "frequency": "mon", "modeling_realm": "landIce", "standard_name": "rainfall_flux", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacella", - "long_name": "Ice Sheet Rainfall rate", + "long_name": "Ice Sheet Rainfall Rate", "comment": "Rainfall rate over the ice sheet", "dimensions": "longitude latitude time", "out_name": "prraIs", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -236,6 +231,7 @@ "ok_max_mean_abs": "" }, "prsnIs": { + "frequency": "mon", "modeling_realm": "landIce", "standard_name": "snowfall_flux", "units": "kg m-2 s-1", @@ -245,7 +241,7 @@ "comment": "at surface; includes precipitation of all forms of water in the solid phase", "dimensions": "longitude latitude time", "out_name": "prsnIs", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -253,40 +249,43 @@ "ok_max_mean_abs": "" }, "rldsIs": { + "frequency": "mon", "modeling_realm": "landIce", "standard_name": "surface_downwelling_longwave_flux_in_air", "units": "W m-2", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacella", "long_name": "Ice Sheet Surface Downwelling Longwave Radiation", - "comment": "", + "comment": "The surface called 'surface' means the lower boundary of the atmosphere. 'longwave' means longwave radiation. Downwelling radiation is radiation from above. It does not mean 'net downward'. When thought of as being incident on a surface, a radiative flux is sometimes called 'irradiance'. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called 'vector irradiance'. In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions": "longitude latitude time", "out_name": "rldsIs", - "type": "", - "positive": "", + "type": "real", + "positive": "down", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "rlusIs": { + "frequency": "mon", "modeling_realm": "landIce", "standard_name": "surface_upwelling_longwave_flux_in_air", "units": "W m-2", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacella", "long_name": "Ice Sheet Surface Upwelling Longwave Radiation", - "comment": "", + "comment": "The surface called 'surface' means the lower boundary of the atmosphere. 'longwave' means longwave radiation. Upwelling radiation is radiation from below. It does not mean 'net upward'. When thought of as being incident on a surface, a radiative flux is sometimes called 'irradiance'. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called 'vector irradiance'. In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions": "longitude latitude time", "out_name": "rlusIs", - "type": "", - "positive": "", + "type": "real", + "positive": "up", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "rsdsIs": { + "frequency": "mon", "modeling_realm": "landIce", "standard_name": "surface_downwelling_shortwave_flux_in_air", "units": "W m-2", @@ -296,33 +295,35 @@ "comment": "Surface solar irradiance for UV calculations", "dimensions": "longitude latitude time", "out_name": "rsdsIs", - "type": "", - "positive": "", + "type": "real", + "positive": "down", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "rsusIs": { + "frequency": "mon", "modeling_realm": "landIce", "standard_name": "surface_upwelling_shortwave_flux_in_air", "units": "W m-2", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacella", "long_name": "Ice Sheet Surface Upwelling Shortwave Radiation", - "comment": "", + "comment": "The surface called 'surface' means the lower boundary of the atmosphere. 'shortwave' means shortwave radiation. Upwelling radiation is radiation from below. It does not mean 'net upward'. When thought of as being incident on a surface, a radiative flux is sometimes called 'irradiance'. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called 'vector irradiance'. In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions": "longitude latitude time", "out_name": "rsusIs", - "type": "", - "positive": "", + "type": "real", + "positive": "up", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "sbl": { + "frequency": "mon", "modeling_realm": "landIce", - "standard_name": "surface_snow_and_ice_sublimation_flux", + "standard_name": "tendency_of_atmosphere_mass_content_of_water_vapor_due_to_sublimation_of_surface_snow_and_ice", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", @@ -338,8 +339,9 @@ "ok_max_mean_abs": "" }, "sblIs": { + "frequency": "mon", "modeling_realm": "landIce", - "standard_name": "surface_snow_and_ice_sublimation_flux", + "standard_name": "tendency_of_atmosphere_mass_content_of_water_vapor_due_to_sublimation_of_surface_snow_and_ice", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where ice_sheet", "cell_measures": "area: areacella", @@ -347,7 +349,7 @@ "comment": "The snow and ice sublimation flux is the loss of snow and ice mass per unit area from the surface resulting from their direct conversion to water vapor that enters the atmosphere.", "dimensions": "longitude latitude time", "out_name": "sblIs", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -355,16 +357,17 @@ "ok_max_mean_abs": "" }, "sftflf": { + "frequency": "mon", "modeling_realm": "landIce", "standard_name": "floating_ice_shelf_area_fraction", "units": "%", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Floating Ice Shelf Area Fraction", - "comment": "Fraction of grid cell covered by floating ice shelf, the component of the ice sheet that is flowing over seawater", - "dimensions": "longitude latitude time typefis", + "long_name": "Floating Ice Shelf Area Percentage", + "comment": "Percentage of grid cell covered by floating ice shelf, the component of the ice sheet that is flowing over sea water", + "dimensions": "longitude latitude time", "out_name": "sftflf", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -372,14 +375,15 @@ "ok_max_mean_abs": "" }, "sftgif": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "land_ice_area_fraction", "units": "%", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Fraction of Grid Cell Covered with Glacier", - "comment": "Fraction of grid cell covered by land ice (ice sheet, ice shelf, ice cap, glacier)", - "dimensions": "longitude latitude time typeli", + "long_name": "Land Ice Area Percentage", + "comment": "Percentage of grid cell covered by land ice (ice sheet, ice shelf, ice cap, glacier)", + "dimensions": "longitude latitude time", "out_name": "sftgif", "type": "real", "positive": "", @@ -389,16 +393,17 @@ "ok_max_mean_abs": "" }, "sftgrf": { + "frequency": "mon", "modeling_realm": "landIce", "standard_name": "grounded_ice_sheet_area_fraction", "units": "%", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Grounded Ice Sheet Area Fraction", - "comment": "Fraction of grid cell covered by grounded ice sheet", - "dimensions": "longitude latitude time typegis", + "long_name": "Grounded Ice Sheet Area Percentage", + "comment": "Percentage of grid cell covered by grounded ice sheet", + "dimensions": "longitude latitude time", "out_name": "sftgrf", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -406,13 +411,14 @@ "ok_max_mean_abs": "" }, "snc": { + "frequency": "mon", "modeling_realm": "landIce land", "standard_name": "surface_snow_area_fraction", "units": "%", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Snow Area Fraction", - "comment": "Fraction of each grid cell that is occupied by snow that rests on land portion of cell.", + "long_name": "Snow Area Percentage", + "comment": "Percentage of each grid cell that is occupied by snow that rests on land portion of cell.", "dimensions": "longitude latitude time", "out_name": "snc", "type": "real", @@ -423,6 +429,7 @@ "ok_max_mean_abs": "" }, "sncIs": { + "frequency": "mon", "modeling_realm": "landIce", "standard_name": "surface_snow_area_fraction", "units": "%", @@ -432,7 +439,7 @@ "comment": "Percentage of each grid cell that is occupied by snow that rests on land portion of cell.", "dimensions": "longitude latitude time", "out_name": "sncIs", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -440,6 +447,7 @@ "ok_max_mean_abs": "" }, "snd": { + "frequency": "mon", "modeling_realm": "landIce land", "standard_name": "surface_snow_thickness", "units": "m", @@ -457,6 +465,7 @@ "ok_max_mean_abs": "" }, "snicefreezIs": { + "frequency": "mon", "modeling_realm": "landIce", "standard_name": "surface_snow_and_ice_refreezing_flux", "units": "kg m-2 s-1", @@ -466,7 +475,7 @@ "comment": "Mass flux of surface meltwater which refreezes within the snowpack. Computed as the total refreezing on the land ice portion of the grid cell divided by land ice area in the grid cell.", "dimensions": "longitude latitude time", "out_name": "snicefreezIs", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -474,6 +483,7 @@ "ok_max_mean_abs": "" }, "snicemIs": { + "frequency": "mon", "modeling_realm": "landIce", "standard_name": "surface_snow_and_ice_melt_flux", "units": "kg m-2 s-1", @@ -483,7 +493,7 @@ "comment": "Loss of snow and ice mass resulting from surface melting. Computed as the total surface melt on the land ice portion of the grid cell divided by land ice area in the grid cell.", "dimensions": "longitude latitude time", "out_name": "snicemIs", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -491,6 +501,7 @@ "ok_max_mean_abs": "" }, "snm": { + "frequency": "mon", "modeling_realm": "landIce land", "standard_name": "surface_snow_melt_flux", "units": "kg m-2 s-1", @@ -508,6 +519,7 @@ "ok_max_mean_abs": "" }, "snmIs": { + "frequency": "mon", "modeling_realm": "landIce", "standard_name": "surface_snow_melt_flux", "units": "kg m-2 s-1", @@ -517,7 +529,7 @@ "comment": "The total surface snow melt rate on the land portion of the grid cell divided by the land area in the grid cell; report as zero for snow-free land regions and missing where there is no land.", "dimensions": "longitude latitude time", "out_name": "snmIs", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -525,6 +537,7 @@ "ok_max_mean_abs": "" }, "snw": { + "frequency": "mon", "modeling_realm": "landIce land", "standard_name": "surface_snow_amount", "units": "kg m-2", @@ -542,6 +555,7 @@ "ok_max_mean_abs": "" }, "sootsn": { + "frequency": "mon", "modeling_realm": "landIce land", "standard_name": "soot_content_of_surface_snow", "units": "kg m-2", @@ -559,6 +573,7 @@ "ok_max_mean_abs": "" }, "tasIs": { + "frequency": "mon", "modeling_realm": "landIce", "standard_name": "air_temperature", "units": "K", @@ -568,7 +583,7 @@ "comment": "near-surface (usually, 2 meter) air temperature", "dimensions": "longitude latitude time", "out_name": "tasIs", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -576,6 +591,7 @@ "ok_max_mean_abs": "" }, "tpf": { + "frequency": "mon", "modeling_realm": "landIce land", "standard_name": "permafrost_layer_thickness", "units": "m", @@ -593,6 +609,7 @@ "ok_max_mean_abs": "" }, "tsIs": { + "frequency": "mon", "modeling_realm": "landIce", "standard_name": "surface_temperature", "units": "K", @@ -602,7 +619,7 @@ "comment": "Temperature of the lower boundary of the atmosphere", "dimensions": "longitude latitude time", "out_name": "tsIs", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -610,6 +627,7 @@ "ok_max_mean_abs": "" }, "tsn": { + "frequency": "mon", "modeling_realm": "landIce land", "standard_name": "temperature_in_surface_snow", "units": "K", @@ -627,6 +645,7 @@ "ok_max_mean_abs": "" }, "tsnIs": { + "frequency": "mon", "modeling_realm": "landIce", "standard_name": "temperature_in_surface_snow", "units": "K", @@ -636,7 +655,7 @@ "comment": "This temperature is averaged over all the snow in the grid cell that rests on land or land ice. When computing the time-mean here, the time samples, weighted by the mass of snow on the land portion of the grid cell, are accumulated and then divided by the sum of the weights. Reported as missing in regions free of snow on land.", "dimensions": "longitude latitude time", "out_name": "tsnIs", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Lmon.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Lmon.json index db286de97a..68bfec6390 100644 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Lmon.json +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Lmon.json @@ -1,26 +1,27 @@ { "Header": { - "data_specs_version": "01.00.10", + "data_specs_version": "01.00.30", + "cmor_version": "3.4", "table_id": "Table Lmon", "realm": "land", - "frequency": "mon", - "cmor_version": "3.2", - "table_date": "10 May 2017", + "table_date": "11 March 2019", "missing_value": "1e20", + "int_missing_value": "-999", "product": "model-output", "approx_interval": "30.00000", "generic_levels": "", "mip_era": "CMIP6", - "Conventions": "CF-1.7 CMIP-6.0" + "Conventions": "CF-1.7 CMIP-6.2" }, "variable_entry": { "baresoilFrac": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "area_fraction", "units": "%", "cell_methods": "area: mean where land over all_area_types time: mean", "cell_measures": "area: areacella", - "long_name": "Bare Soil Fraction", + "long_name": "Bare Soil Percentage Area Coverage", "comment": "Percentage of entire grid cell that is covered by bare soil.", "dimensions": "longitude latitude time typebare", "out_name": "baresoilFrac", @@ -32,13 +33,14 @@ "ok_max_mean_abs": "" }, "burntFractionAll": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "area_fraction", "units": "%", "cell_methods": "area: mean where land over all_area_types time: mean", "cell_measures": "area: areacella", "long_name": "Percentage of Entire Grid cell that is Covered by Burnt Vegetation (All Classes)", - "comment": "Percentage of grid cell burned due to all fires including natural and anthropogenic fires and those associated with anthropogenic land use change", + "comment": "Percentage of grid cell burned due to all fires including natural and anthropogenic fires and those associated with anthropogenic Land-use change", "dimensions": "longitude latitude time typeburnt", "out_name": "burntFractionAll", "type": "real", @@ -49,12 +51,13 @@ "ok_max_mean_abs": "" }, "c3PftFrac": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "area_fraction", "units": "%", "cell_methods": "area: mean where land over all_area_types time: mean", "cell_measures": "area: areacella", - "long_name": "Total C3 PFT Cover Fraction", + "long_name": "Percentage Cover by C3 Plant Functional Type", "comment": "Percentage of entire grid cell that is covered by C3 PFTs (including grass, crops, and trees).", "dimensions": "longitude latitude time typec3pft", "out_name": "c3PftFrac", @@ -66,12 +69,13 @@ "ok_max_mean_abs": "" }, "c4PftFrac": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "area_fraction", "units": "%", "cell_methods": "area: mean where land over all_area_types time: mean", "cell_measures": "area: areacella", - "long_name": "Total C4 PFT Cover Fraction", + "long_name": "Percentage Cover by C4 Plant Functional Type", "comment": "Percentage of entire grid cell that is covered by C4 PFTs (including grass and crops).", "dimensions": "longitude latitude time typec4pft", "out_name": "c4PftFrac", @@ -83,8 +87,9 @@ "ok_max_mean_abs": "" }, "cCwd": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "wood_debris_carbon_content", + "standard_name": "wood_debris_mass_content_of_carbon", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", @@ -100,8 +105,9 @@ "ok_max_mean_abs": "" }, "cLeaf": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "leaf_carbon_content", + "standard_name": "leaf_mass_content_of_carbon", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", @@ -117,13 +123,14 @@ "ok_max_mean_abs": "" }, "cLitter": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "litter_carbon_content", + "standard_name": "litter_mass_content_of_carbon", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", "long_name": "Carbon Mass in Litter Pool", - "comment": "", + "comment": "'Litter' is dead plant material in or above the soil. It is distinct from coarse wood debris. The precise distinction between 'fine' and 'coarse' is model dependent. 'Content' indicates a quantity per unit area. The sum of the quantities with standard names surface_litter_mass_content_of_carbon and subsurface_litter_mass_content_of_carbon has the standard name litter_mass_content_of_carbon.", "dimensions": "longitude latitude time", "out_name": "cLitter", "type": "real", @@ -134,13 +141,14 @@ "ok_max_mean_abs": "" }, "cLitterAbove": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "surface_litter_carbon_content", + "standard_name": "surface_litter_mass_content_of_carbon", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", "long_name": "Carbon Mass in Above-Ground Litter", - "comment": "", + "comment": "'Litter' is dead plant material in or above the soil. It is distinct from coarse wood debris. The precise distinction between 'fine' and 'coarse' is model dependent. 'Surface litter' means the part of the litter resting above the soil surface. 'Content' indicates a quantity per unit area. The sum of the quantities with standard names surface_litter_mass_content_of_carbon and subsurface_litter_mass_content_of_carbon has the standard name litter_mass_content_of_carbon.", "dimensions": "longitude latitude time", "out_name": "cLitterAbove", "type": "real", @@ -151,13 +159,14 @@ "ok_max_mean_abs": "" }, "cLitterBelow": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "subsurface_litter_carbon_content", + "standard_name": "subsurface_litter_mass_content_of_carbon", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", "long_name": "Carbon Mass in Below-Ground Litter", - "comment": "", + "comment": "'Litter' is dead plant material in or above the soil. It is distinct from coarse wood debris. The precise distinction between 'fine' and 'coarse' is model dependent. 'subsurface litter' means the part of the litter mixed within the soil below the surface. 'Content' indicates a quantity per unit area. The sum of the quantities with standard names surface_litter_mass_content_of_carbon and subsurface_litter_mass_content_of_carbon has the standard name litter_mass_content_of_carbon.", "dimensions": "longitude latitude time", "out_name": "cLitterBelow", "type": "real", @@ -168,13 +177,14 @@ "ok_max_mean_abs": "" }, "cProduct": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "carbon_content_of_products_of_anthropogenic_land_use_change", + "standard_name": "carbon_mass_content_of_forestry_and_agricultural_products", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Carbon Mass in Products of Land Use Change", - "comment": "Carbon mass per unit area in that has been removed from the environment through landuse change.", + "long_name": "Carbon Mass in Products of Land-Use Change", + "comment": "Carbon mass per unit area in that has been removed from the environment through land use change.", "dimensions": "longitude latitude time", "out_name": "cProduct", "type": "real", @@ -185,8 +195,9 @@ "ok_max_mean_abs": "" }, "cRoot": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "root_carbon_content", + "standard_name": "root_mass_content_of_carbon", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", @@ -202,8 +213,9 @@ "ok_max_mean_abs": "" }, "cSoilFast": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "fast_soil_pool_carbon_content", + "standard_name": "fast_soil_pool_mass_content_of_carbon", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", @@ -219,8 +231,9 @@ "ok_max_mean_abs": "" }, "cSoilMedium": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "medium_soil_pool_carbon_content", + "standard_name": "medium_soil_pool_mass_content_of_carbon", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", @@ -236,8 +249,9 @@ "ok_max_mean_abs": "" }, "cSoilSlow": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "slow_soil_pool_carbon_content", + "standard_name": "slow_soil_pool_mass_content_of_carbon", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", @@ -253,6 +267,7 @@ "ok_max_mean_abs": "" }, "cVeg": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "vegetation_carbon_content", "units": "kg m-2", @@ -270,12 +285,13 @@ "ok_max_mean_abs": "" }, "cropFrac": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "area_fraction", "units": "%", "cell_methods": "area: mean where land over all_area_types time: mean", "cell_measures": "area: areacella", - "long_name": "Crop Fraction", + "long_name": "Percentage Crop Cover", "comment": "Percentage of entire grid cell that is covered by crop.", "dimensions": "longitude latitude time typecrop", "out_name": "cropFrac", @@ -287,6 +303,7 @@ "ok_max_mean_abs": "" }, "evspsblsoi": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "water_evaporation_flux_from_soil", "units": "kg m-2 s-1", @@ -297,13 +314,14 @@ "dimensions": "longitude latitude time", "out_name": "evspsblsoi", "type": "real", - "positive": "up", + "positive": "", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "evspsblveg": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "water_evaporation_flux_from_canopy", "units": "kg m-2 s-1", @@ -314,19 +332,20 @@ "dimensions": "longitude latitude time", "out_name": "evspsblveg", "type": "real", - "positive": "up", + "positive": "", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "fFire": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_fires_excluding_anthropogenic_land_use_change", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Carbon Mass Flux into Atmosphere due to CO2 Emission from Fire", + "long_name": "Carbon Mass Flux into Atmosphere Due to CO2 Emission from Fire Excluding Land-Use Change", "comment": "CO2 emissions (expressed as a carbon mass flux per unit area) from natural fires and human ignition fires as calculated by the fire module of the dynamic vegetation model, but excluding any CO2 flux from fire included in fLuc (CO2 Flux to Atmosphere from Land Use Change).", "dimensions": "longitude latitude time", "out_name": "fFire", @@ -338,12 +357,13 @@ "ok_max_mean_abs": "" }, "fGrazing": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_grazing", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Carbon Mass Flux into Atmosphere due to Grazing on Land", + "long_name": "Carbon Mass Flux into Atmosphere Due to Grazing on Land", "comment": "Carbon mass flux per unit area due to grazing on land", "dimensions": "longitude latitude time", "out_name": "fGrazing", @@ -355,12 +375,13 @@ "ok_max_mean_abs": "" }, "fHarvest": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_emission_from_crop_harvesting", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Carbon Mass Flux into Atmosphere due to Crop Harvesting", + "long_name": "Carbon Mass Flux into Atmosphere Due to Crop Harvesting", "comment": "Carbon mass flux per unit area due to crop harvesting", "dimensions": "longitude latitude time", "out_name": "fHarvest", @@ -372,6 +393,7 @@ "ok_max_mean_abs": "" }, "fLitterSoil": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "carbon_mass_flux_into_soil_from_litter", "units": "kg m-2 s-1", @@ -389,13 +411,14 @@ "ok_max_mean_abs": "" }, "fVegLitter": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "litter_carbon_flux", + "standard_name": "mass_flux_of_carbon_into_litter_from_vegetation", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", "long_name": "Total Carbon Mass Flux from Vegetation to Litter", - "comment": "", + "comment": "In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. 'Vegetation' means any living plants e.g. trees, shrubs, grass. 'Litter' is dead plant material in or above the soil. It is distinct from coarse wood debris. The precise distinction between 'fine' and 'coarse' is model dependent. The sum of the quantities with standard names mass_flux_of_carbon_into_litter_from_vegetation_due_to_mortality and mass_flux_of_carbon_into_litter_from_vegetation_due_to_senescence is mass_flux_of_carbon_into_litter_from_vegetation.", "dimensions": "longitude latitude time", "out_name": "fVegLitter", "type": "real", @@ -406,6 +429,7 @@ "ok_max_mean_abs": "" }, "fVegSoil": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "carbon_mass_flux_into_soil_from_vegetation_excluding_litter", "units": "kg m-2 s-1", @@ -423,29 +447,31 @@ "ok_max_mean_abs": "" }, "gpp": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "gross_primary_productivity_of_biomass_expressed_as_carbon", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Carbon Mass Flux out of Atmosphere due to Gross Primary Production on Land", - "comment": "", + "long_name": "Carbon Mass Flux out of Atmosphere Due to Gross Primary Production on Land", + "comment": "The rate of synthesis of biomass from inorganic precursors by autotrophs ('producers') expressed as the mass of carbon which it contains. For example, photosynthesis in plants or phytoplankton. The producers also respire some of this biomass and the difference is referred to as the net primary production. ", "dimensions": "longitude latitude time", "out_name": "gpp", "type": "real", - "positive": "down", + "positive": "", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "grassFrac": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "area_fraction", "units": "%", "cell_methods": "area: mean where land over all_area_types time: mean", "cell_measures": "area: areacella", - "long_name": "Natural Grass Fraction", + "long_name": "Natural Grass Area Percentage", "comment": "Percentage of entire grid cell that is covered by natural grass.", "dimensions": "longitude latitude time typenatgr", "out_name": "grassFrac", @@ -457,13 +483,14 @@ "ok_max_mean_abs": "" }, "lai": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "leaf_area_index", - "units": "1.0", + "units": "1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", "long_name": "Leaf Area Index", - "comment": "", + "comment": "A ratio obtained by dividing the total upper leaf surface area of vegetation by the (horizontal) surface area of the land on which it grows.", "dimensions": "longitude latitude time", "out_name": "lai", "type": "real", @@ -474,13 +501,14 @@ "ok_max_mean_abs": "" }, "landCoverFrac": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "area_fraction", "units": "%", "cell_methods": "area: mean where land over all_area_types time: mean", "cell_measures": "area: areacella", - "long_name": "Plant Functional Type Grid Fraction", - "comment": "Percentage of grid cell area occupied by different model vegetation/land cover categories. The categories may differ from model to model, depending on each model's subgrid land cover category definitions. Categories may include natural vegetation, anthropogenic vegetation, bare soil, lakes, urban areas, glaciers, etc. Sum of all should equal the fraction of the grid-cell that is land.", + "long_name": "Percentage of Area by Vegetation or Land-Cover Category", + "comment": "Percentage of grid cell area occupied by different model vegetation/land cover categories. The categories may differ from model to model, depending on each model's subgrid land cover category definitions. Categories may include natural vegetation, anthropogenic vegetation, bare soil, lakes, urban areas, glaciers, etc. Sum of all should equal the percentage of the grid cell that is land.", "dimensions": "longitude latitude vegtype time", "out_name": "landCoverFrac", "type": "real", @@ -491,6 +519,7 @@ "ok_max_mean_abs": "" }, "mrfso": { + "frequency": "mon", "modeling_realm": "land landIce", "standard_name": "soil_frozen_water_content", "units": "kg m-2", @@ -507,24 +536,8 @@ "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, - "mrlsl": { - "modeling_realm": "land", - "standard_name": "moisture_content_of_soil_layer", - "units": "kg m-2", - "cell_methods": "area: mean where land time: mean", - "cell_measures": "area: areacella", - "long_name": "Water Content of Soil Layer", - "comment": "The mass of water in all phases, including ice, in soil layers. Report as missing for grid cells with no land.", - "dimensions": "longitude latitude sdepth time", - "out_name": "mrlsl", - "type": "real", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, "mrro": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "runoff_flux", "units": "kg m-2 s-1", @@ -542,6 +555,7 @@ "ok_max_mean_abs": "" }, "mrros": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "surface_runoff_flux", "units": "kg m-2 s-1", @@ -559,8 +573,9 @@ "ok_max_mean_abs": "" }, "mrso": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "soil_moisture_content", + "standard_name": "mass_content_of_water_in_soil", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", @@ -576,8 +591,9 @@ "ok_max_mean_abs": "" }, "mrsos": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "moisture_content_of_soil_layer", + "standard_name": "mass_content_of_water_in_soil_layer", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", @@ -593,12 +609,13 @@ "ok_max_mean_abs": "" }, "nbp": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "surface_net_downward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_all_land_processes", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Carbon Mass Flux out of Atmosphere due to Net Biospheric Production on Land", + "long_name": "Carbon Mass Flux out of Atmosphere Due to Net Biospheric Production on Land", "comment": "This is the net mass flux of carbon from atmosphere into land, calculated as photosynthesis MINUS the sum of plant and soil respiration, carbon fluxes from fire, harvest, grazing and land use change. Positive flux is into the land.", "dimensions": "longitude latitude time", "out_name": "nbp", @@ -610,13 +627,14 @@ "ok_max_mean_abs": "" }, "npp": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "net_primary_productivity_of_biomass_expressed_as_carbon", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Carbon Mass Flux out of Atmosphere due to Net Primary Production on Land", - "comment": "", + "long_name": "Carbon Mass Flux out of Atmosphere Due to Net Primary Production on Land", + "comment": "'Production of carbon' means the production of biomass expressed as the mass of carbon which it contains. Net primary production is the excess of gross primary production (rate of synthesis of biomass from inorganic precursors) by autotrophs ('producers'), for example, photosynthesis in plants or phytoplankton, over the rate at which the autotrophs themselves respire some of this biomass. 'Productivity' means production per unit area. The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", "dimensions": "longitude latitude time", "out_name": "npp", "type": "real", @@ -627,12 +645,13 @@ "ok_max_mean_abs": "" }, "nppLeaf": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "net_primary_productivity_of_carbon_accumulated_in_leaves", + "standard_name": "net_primary_productivity_of_biomass_expressed_as_carbon_accumulated_in_leaves", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Carbon Mass Flux due to NPP Allocation to Leaf", + "long_name": "Carbon Mass Flux Due to NPP Allocation to Leaf", "comment": "This is the rate of carbon uptake by leaves due to NPP", "dimensions": "longitude latitude time", "out_name": "nppLeaf", @@ -644,12 +663,13 @@ "ok_max_mean_abs": "" }, "nppRoot": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "net_primary_productivity_of_carbon_accumulated_in_roots", + "standard_name": "net_primary_productivity_of_biomass_expressed_as_carbon_accumulated_in_roots", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Carbon Mass Flux due to NPP Allocation to Roots", + "long_name": "Carbon Mass Flux Due to NPP Allocation to Roots", "comment": "This is the rate of carbon uptake by roots due to NPP", "dimensions": "longitude latitude time", "out_name": "nppRoot", @@ -661,12 +681,13 @@ "ok_max_mean_abs": "" }, "nppWood": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "net_primary_productivity_of_carbon_accumulated_in_wood", + "standard_name": "net_primary_productivity_of_biomass_expressed_as_carbon_accumulated_in_wood", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Carbon Mass Flux due to NPP Allocation to Wood", + "long_name": "Carbon Mass Flux Due to NPP Allocation to Wood", "comment": "This is the rate of carbon uptake by wood due to NPP", "dimensions": "longitude latitude time", "out_name": "nppWood", @@ -678,12 +699,13 @@ "ok_max_mean_abs": "" }, "pastureFrac": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "area_fraction", "units": "%", "cell_methods": "area: mean where land over all_area_types time: mean", "cell_measures": "area: areacella", - "long_name": "Anthropogenic Pasture Fraction", + "long_name": "Percentage of Land Which Is Anthropogenic Pasture", "comment": "Percentage of entire grid cell that is covered by anthropogenic pasture.", "dimensions": "longitude latitude time typepasture", "out_name": "pastureFrac", @@ -695,6 +717,7 @@ "ok_max_mean_abs": "" }, "prveg": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "precipitation_flux_onto_canopy", "units": "kg m-2 s-1", @@ -712,13 +735,14 @@ "ok_max_mean_abs": "" }, "rGrowth": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "surface_upward_carbon_mass_flux_due_to_plant_respiration_for_biomass_growth", + "standard_name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_for_biomass_growth", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Carbon Mass Flux into Atmosphere due to Growth Autotrophic Respiration on Land", - "comment": "", + "long_name": "Carbon Mass Flux into Atmosphere Due to Growth Autotrophic Respiration on Land", + "comment": "Growth respiration is defined as the additional carbon cost for the synthesis of new growth.", "dimensions": "longitude latitude time", "out_name": "rGrowth", "type": "real", @@ -729,13 +753,14 @@ "ok_max_mean_abs": "" }, "rMaint": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "surface_upward_carbon_mass_flux_due_to_plant_respiration_for_biomass_maintenance", + "standard_name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_for_biomass_maintenance", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Carbon Mass Flux into Atmosphere due to Maintenance Autotrophic Respiration on Land", - "comment": "", + "long_name": "Carbon Mass Flux into Atmosphere Due to Maintenance Autotrophic Respiration on Land", + "comment": "Maintenance respiration is defined as the carbon cost to support the metabolic activity of existing live tissue.", "dimensions": "longitude latitude time", "out_name": "rMaint", "type": "real", @@ -746,12 +771,13 @@ "ok_max_mean_abs": "" }, "ra": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "plant_respiration_carbon_flux", + "standard_name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Carbon Mass Flux into Atmosphere due to Autotrophic (Plant) Respiration on Land", + "long_name": "Carbon Mass Flux into Atmosphere Due to Autotrophic (Plant) Respiration on Land", "comment": "Carbon mass flux per unit area into atmosphere due to autotrophic respiration on land (respiration by producers) [see rh for heterotrophic production]", "dimensions": "longitude latitude time", "out_name": "ra", @@ -763,12 +789,13 @@ "ok_max_mean_abs": "" }, "residualFrac": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "area_fraction", "units": "%", "cell_methods": "area: mean where land over all_area_types time: mean", "cell_measures": "area: areacella", - "long_name": "Fraction of Grid Cell that is Land but Neither Vegetation-Covered nor Bare Soil", + "long_name": "Percentage of Grid Cell That Is Land but neither Vegetation Covered nor Bare Soil", "comment": "Percentage of entire grid cell that is land and is covered by neither vegetation nor bare-soil (e.g., urban, ice, lakes, etc.)", "dimensions": "longitude latitude time typeresidual", "out_name": "residualFrac", @@ -780,12 +807,13 @@ "ok_max_mean_abs": "" }, "rh": { + "frequency": "mon", "modeling_realm": "land", - "standard_name": "heterotrophic_respiration_carbon_flux", + "standard_name": "surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_heterotrophic_respiration", "units": "kg m-2 s-1", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", - "long_name": "Carbon Mass Flux into Atmosphere due to Heterotrophic Respiration on Land", + "long_name": "Carbon Mass Flux into Atmosphere Due to Heterotrophic Respiration on Land", "comment": "Carbon mass flux per unit area into atmosphere due to heterotrophic respiration on land (respiration by consumers)", "dimensions": "longitude latitude time", "out_name": "rh", @@ -797,12 +825,13 @@ "ok_max_mean_abs": "" }, "shrubFrac": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "area_fraction", "units": "%", "cell_methods": "area: mean where land over all_area_types time: mean", "cell_measures": "area: areacella", - "long_name": "Shrub Fraction", + "long_name": "Percentage Cover by Shrub", "comment": "Percentage of entire grid cell that is covered by shrub.", "dimensions": "longitude latitude time typeshrub", "out_name": "shrubFrac", @@ -814,6 +843,7 @@ "ok_max_mean_abs": "" }, "tran": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "transpiration_flux", "units": "kg m-2 s-1", @@ -831,12 +861,13 @@ "ok_max_mean_abs": "" }, "treeFrac": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "area_fraction", "units": "%", "cell_methods": "area: mean where land over all_area_types time: mean", "cell_measures": "area: areacella", - "long_name": "Tree Cover Fraction", + "long_name": "Tree Cover Percentage", "comment": "Percentage of entire grid cell that is covered by trees.", "dimensions": "longitude latitude time typetree", "out_name": "treeFrac", @@ -848,12 +879,13 @@ "ok_max_mean_abs": "" }, "treeFracPrimDec": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "area_fraction", "units": "%", "cell_methods": "area: mean where land over all_area_types time: mean", "cell_measures": "area: areacella", - "long_name": "Total Primary Deciduous Tree Fraction", + "long_name": "Percentage Cover by Primary Deciduous Tree", "comment": "Percentage of the entire grid cell that is covered by total primary deciduous trees.", "dimensions": "longitude latitude time typepdec", "out_name": "treeFracPrimDec", @@ -865,12 +897,13 @@ "ok_max_mean_abs": "" }, "treeFracPrimEver": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "area_fraction", "units": "%", "cell_methods": "area: mean where land over all_area_types time: mean", "cell_measures": "area: areacella", - "long_name": "Total Primary Evergreen Tree Cover Fraction", + "long_name": "Percentage Cover by Primary Evergreen Trees", "comment": "Percentage of entire grid cell that is covered by primary evergreen trees.", "dimensions": "longitude latitude time typepever", "out_name": "treeFracPrimEver", @@ -882,12 +915,13 @@ "ok_max_mean_abs": "" }, "treeFracSecDec": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "area_fraction", "units": "%", "cell_methods": "area: mean where land over all_area_types time: mean", "cell_measures": "area: areacella", - "long_name": "Total Secondary Deciduous Tree Cover Fraction", + "long_name": "Percentage Cover by Secondary Deciduous Trees", "comment": "Percentage of entire grid cell that is covered by secondary deciduous trees.", "dimensions": "longitude latitude time typesdec", "out_name": "treeFracSecDec", @@ -899,12 +933,13 @@ "ok_max_mean_abs": "" }, "treeFracSecEver": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "area_fraction", "units": "%", "cell_methods": "area: mean where land over all_area_types time: mean", "cell_measures": "area: areacella", - "long_name": "Total Secondary Evergreen Tree Cover Fraction", + "long_name": "Percentage Cover by Secondary Evergreen Trees", "comment": "Percentage of entire grid cell that is covered by secondary evergreen trees.", "dimensions": "longitude latitude time typesever", "out_name": "treeFracSecEver", @@ -916,13 +951,14 @@ "ok_max_mean_abs": "" }, "tsl": { + "frequency": "mon", "modeling_realm": "land", "standard_name": "soil_temperature", "units": "K", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", "long_name": "Temperature of Soil", - "comment": "Temperature of each soil layer. Reported as missing for grid cells with no land.", + "comment": "Temperature of soil. Reported as missing for grid cells with no land.", "dimensions": "longitude latitude sdepth time", "out_name": "tsl", "type": "real", diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Oclim.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Oclim.json index d5d5f2cd69..46c93500cc 100644 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Oclim.json +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Oclim.json @@ -1,27 +1,28 @@ { "Header": { - "data_specs_version": "01.00.10", + "data_specs_version": "01.00.30", + "cmor_version": "3.4", "table_id": "Table Oclim", "realm": "ocean", - "frequency": "monClim", - "cmor_version": "3.2", - "table_date": "10 May 2017", + "table_date": "11 March 2019", "missing_value": "1e20", + "int_missing_value": "-999", "product": "model-output", "approx_interval": "30.00000", "generic_levels": "olevel", "mip_era": "CMIP6", - "Conventions": "CF-1.7 CMIP-6.0" + "Conventions": "CF-1.7 CMIP-6.2" }, "variable_entry": { "difmxybo": { + "frequency": "monC", "modeling_realm": "ocean", "standard_name": "ocean_momentum_xy_biharmonic_diffusivity", "units": "m4 s-1", "cell_methods": "area: mean time: mean within years time: mean over years", "cell_measures": "area: areacello volume: volcello", "long_name": "Ocean Momentum XY Biharmonic Diffusivity", - "comment": "Lateral biharmonic viscosity applied to the momentum equitions.", + "comment": "Lateral biharmonic viscosity applied to the momentum equations.", "dimensions": "longitude latitude olevel time2", "out_name": "difmxybo", "type": "real", @@ -32,13 +33,14 @@ "ok_max_mean_abs": "" }, "difmxybo2d": { + "frequency": "monC", "modeling_realm": "ocean", "standard_name": "ocean_momentum_xy_biharmonic_diffusivity", "units": "m4 s-1", "cell_methods": "area: mean time: mean within years time: mean over years", "cell_measures": "area: areacello", "long_name": "Ocean Momentum XY Biharmonic Diffusivity", - "comment": "Lateral biharmonic viscosity applied to the momentum equitions.", + "comment": "Lateral biharmonic viscosity applied to the momentum equations.", "dimensions": "longitude latitude time2", "out_name": "difmxybo", "type": "real", @@ -49,13 +51,14 @@ "ok_max_mean_abs": "" }, "difmxylo": { + "frequency": "monC", "modeling_realm": "ocean", "standard_name": "ocean_momentum_xy_laplacian_diffusivity", "units": "m2 s-1", "cell_methods": "area: mean time: mean within years time: mean over years", "cell_measures": "area: areacello volume: volcello", "long_name": "Ocean Momentum XY Laplacian Diffusivity", - "comment": "Lateral Laplacian viscosity applied to the momentum equitions.", + "comment": "Lateral Laplacian viscosity applied to the momentum equations.", "dimensions": "longitude latitude olevel time2", "out_name": "difmxylo", "type": "real", @@ -66,13 +69,14 @@ "ok_max_mean_abs": "" }, "difmxylo2d": { + "frequency": "monC", "modeling_realm": "ocean", "standard_name": "ocean_momentum_xy_laplacian_diffusivity", "units": "m2 s-1", "cell_methods": "area: mean time: mean within years time: mean over years", "cell_measures": "area: areacello", "long_name": "Ocean Momentum XY Laplacian Diffusivity", - "comment": "Lateral Laplacian viscosity applied to the momentum equitions.", + "comment": "Lateral Laplacian viscosity applied to the momentum equations.", "dimensions": "longitude latitude time2", "out_name": "difmxylo", "type": "real", @@ -83,13 +87,14 @@ "ok_max_mean_abs": "" }, "diftrbbo": { + "frequency": "monC", "modeling_realm": "ocean", - "standard_name": "ocean_tracer_bolus_biharmonic_diffusivity", + "standard_name": "ocean_tracer_biharmonic_diffusivity_due_to_parameterized_mesoscale_eddy_advection", "units": "m4 s-1", "cell_methods": "area: mean time: mean within years time: mean over years", "cell_measures": "area: areacello volume: volcello", "long_name": "Ocean Tracer Bolus Biharmonic Diffusivity", - "comment": "", + "comment": "Parameterized mesoscale eddy advection occurs on a spatial scale of many tens of kilometres and an evolutionary time of weeks(sometimes called bolus advection). Reference: James C. McWilliams 2016, Submesoscale currents in the ocean, Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences, volume 472, issue 2189. DOI: 10.1098/rspa.2016.0117. ", "dimensions": "longitude latitude olevel time2", "out_name": "diftrbbo", "type": "real", @@ -100,13 +105,14 @@ "ok_max_mean_abs": "" }, "diftrbbo2d": { + "frequency": "monC", "modeling_realm": "ocean", - "standard_name": "ocean_tracer_bolus_biharmonic_diffusivity", + "standard_name": "ocean_tracer_biharmonic_diffusivity_due_to_parameterized_mesoscale_eddy_advection", "units": "m4 s-1", "cell_methods": "area: mean time: mean within years time: mean over years", "cell_measures": "area: areacello", "long_name": "Ocean Tracer Bolus Biharmonic Diffusivity", - "comment": "", + "comment": "Parameterized mesoscale eddy advection occurs on a spatial scale of many tens of kilometres and an evolutionary time of weeks(sometimes called bolus advection). Reference: James C. McWilliams 2016, Submesoscale currents in the ocean, Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences, volume 472, issue 2189. DOI: 10.1098/rspa.2016.0117. ", "dimensions": "longitude latitude time2", "out_name": "diftrbbo", "type": "real", @@ -117,12 +123,13 @@ "ok_max_mean_abs": "" }, "diftrblo": { + "frequency": "monC", "modeling_realm": "ocean", - "standard_name": "ocean_tracer_bolus_laplacian_diffusivity", + "standard_name": "ocean_tracer_laplacian_diffusivity_due_to_parameterized_mesoscale_eddy_advection", "units": "m2 s-1", "cell_methods": "area: mean time: mean within years time: mean over years", "cell_measures": "area: areacello volume: volcello", - "long_name": "Ocean Tracer Bolus Laplacian Diffusivity", + "long_name": "Ocean Tracer Diffusivity Due to Parameterized Mesoscale Advection", "comment": "Ocean tracer diffusivity associated with parameterized eddy-induced advective transport. Sometimes this diffusivity is called the 'thickness' diffusivity. For CMIP5, this diagnostic was called 'ocean tracer bolus laplacian diffusivity'. The CMIP6 name is physically more relevant.", "dimensions": "longitude latitude olevel time2", "out_name": "diftrblo", @@ -134,12 +141,13 @@ "ok_max_mean_abs": "" }, "diftrblo2d": { + "frequency": "monC", "modeling_realm": "ocean", - "standard_name": "ocean_tracer_bolus_laplacian_diffusivity", + "standard_name": "ocean_tracer_laplacian_diffusivity_due_to_parameterized_mesoscale_eddy_advection", "units": "m2 s-1", "cell_methods": "area: mean time: mean within years time: mean over years", "cell_measures": "area: areacello", - "long_name": "Ocean Tracer Bolus Laplacian Diffusivity", + "long_name": "Ocean Tracer Diffusivity Due to Parameterized Mesoscale Advection", "comment": "Ocean tracer diffusivity associated with parameterized eddy-induced advective transport. Sometimes this diffusivity is called the 'thickness' diffusivity. For CMIP5, this diagnostic was called 'ocean tracer bolus laplacian diffusivity'. The CMIP6 name is physically more relevant.", "dimensions": "longitude latitude time2", "out_name": "diftrblo", @@ -151,13 +159,14 @@ "ok_max_mean_abs": "" }, "diftrebo": { + "frequency": "monC", "modeling_realm": "ocean", "standard_name": "ocean_tracer_epineutral_biharmonic_diffusivity", "units": "m4 s-1", "cell_methods": "area: mean time: mean within years time: mean over years", "cell_measures": "area: areacello volume: volcello", "long_name": "Ocean Tracer Epineutral Biharmonic Diffusivity", - "comment": "", + "comment": "Epineutral diffusivity means a lateral diffusivity along a either a neutral or isopycnal density surface due to motion which is not resolved on the grid scale of an ocean model. The type of density surface is dependent on the model formulation. ", "dimensions": "longitude latitude olevel time2", "out_name": "diftrebo", "type": "real", @@ -168,13 +177,14 @@ "ok_max_mean_abs": "" }, "diftrebo2d": { + "frequency": "monC", "modeling_realm": "ocean", "standard_name": "ocean_tracer_epineutral_biharmonic_diffusivity", "units": "m4 s-1", "cell_methods": "area: mean time: mean within years time: mean over years", "cell_measures": "area: areacello", "long_name": "Ocean Tracer Epineutral Biharmonic Diffusivity", - "comment": "", + "comment": "Epineutral diffusivity means a lateral diffusivity along a either a neutral or isopycnal density surface due to motion which is not resolved on the grid scale of an ocean model. The type of density surface is dependent on the model formulation. ", "dimensions": "longitude latitude time2", "out_name": "diftrebo", "type": "real", @@ -185,6 +195,7 @@ "ok_max_mean_abs": "" }, "diftrelo": { + "frequency": "monC", "modeling_realm": "ocean", "standard_name": "ocean_tracer_epineutral_laplacian_diffusivity", "units": "m2 s-1", @@ -202,6 +213,7 @@ "ok_max_mean_abs": "" }, "diftrelo2d": { + "frequency": "monC", "modeling_realm": "ocean", "standard_name": "ocean_tracer_epineutral_laplacian_diffusivity", "units": "m2 s-1", @@ -219,13 +231,14 @@ "ok_max_mean_abs": "" }, "diftrxybo": { + "frequency": "monC", "modeling_realm": "ocean", "standard_name": "ocean_tracer_xy_biharmonic_diffusivity", "units": "m4 s-1", "cell_methods": "area: mean time: mean within years time: mean over years", "cell_measures": "area: areacello volume: volcello", "long_name": "Ocean Tracer XY Biharmonic Diffusivity", - "comment": "", + "comment": "Diffusivity is also sometimes known as the coefficient of diffusion. Diffusion occurs as a result of a gradient in the spatial distribution of mass concentration, temperature or momentum. The diffusivity may be very different in the vertical and horizontal directions. 'xy diffusivity' means the lateral along_coordinate component of diffusivity due to motion which is not resolved on the grid scale of the model. xy diffusivities are used in some ocean models to counteract the numerical instabilities inherent in certain implementations of rotated neutral diffusion. 'biharmonic diffusivity' means diffusivity for use with a biharmonic diffusion operator.", "dimensions": "longitude latitude olevel time2", "out_name": "diftrxybo", "type": "real", @@ -236,13 +249,14 @@ "ok_max_mean_abs": "" }, "diftrxybo2d": { + "frequency": "monC", "modeling_realm": "ocean", "standard_name": "ocean_tracer_xy_biharmonic_diffusivity", "units": "m4 s-1", "cell_methods": "area: mean time: mean within years time: mean over years", "cell_measures": "area: areacello", "long_name": "Ocean Tracer XY Biharmonic Diffusivity", - "comment": "", + "comment": "Diffusivity is also sometimes known as the coefficient of diffusion. Diffusion occurs as a result of a gradient in the spatial distribution of mass concentration, temperature or momentum. The diffusivity may be very different in the vertical and horizontal directions. 'xy diffusivity' means the lateral along_coordinate component of diffusivity due to motion which is not resolved on the grid scale of the model. xy diffusivities are used in some ocean models to counteract the numerical instabilities inherent in certain implementations of rotated neutral diffusion. 'biharmonic diffusivity' means diffusivity for use with a biharmonic diffusion operator.", "dimensions": "longitude latitude time2", "out_name": "diftrxybo", "type": "real", @@ -253,13 +267,14 @@ "ok_max_mean_abs": "" }, "diftrxylo": { + "frequency": "monC", "modeling_realm": "ocean", "standard_name": "ocean_tracer_xy_laplacian_diffusivity", "units": "m2 s-1", "cell_methods": "area: mean time: mean within years time: mean over years", "cell_measures": "area: areacello volume: volcello", "long_name": "Ocean Tracer XY Laplacian Diffusivity", - "comment": "", + "comment": "Diffusivity is also sometimes known as the coefficient of diffusion. Diffusion occurs as a result of a gradient in the spatial distribution of mass concentration, temperature or momentum. The diffusivity may be very different in the vertical and horizontal directions. 'xy diffusivity' means the lateral along_coordinate component of diffusivity due to motion which is not resolved on the grid scale of the model. xy diffusivities are used in some ocean models to counteract the numerical instabilities inherent in certain implementations of rotated neutral diffusion. 'laplacian diffusivity' means diffusivity for use with a Laplacian diffusion operator.", "dimensions": "longitude latitude olevel time2", "out_name": "diftrxylo", "type": "real", @@ -270,13 +285,14 @@ "ok_max_mean_abs": "" }, "diftrxylo2d": { + "frequency": "monC", "modeling_realm": "ocean", "standard_name": "ocean_tracer_xy_laplacian_diffusivity", "units": "m2 s-1", "cell_methods": "area: mean time: mean within years time: mean over years", "cell_measures": "area: areacello", "long_name": "Ocean Tracer XY Laplacian Diffusivity", - "comment": "", + "comment": "Diffusivity is also sometimes known as the coefficient of diffusion. Diffusion occurs as a result of a gradient in the spatial distribution of mass concentration, temperature or momentum. The diffusivity may be very different in the vertical and horizontal directions. 'xy diffusivity' means the lateral along_coordinate component of diffusivity due to motion which is not resolved on the grid scale of the model. xy diffusivities are used in some ocean models to counteract the numerical instabilities inherent in certain implementations of rotated neutral diffusion. 'laplacian diffusivity' means diffusivity for use with a Laplacian diffusion operator.", "dimensions": "longitude latitude time2", "out_name": "diftrxylo", "type": "real", @@ -287,6 +303,7 @@ "ok_max_mean_abs": "" }, "difvho": { + "frequency": "monC", "modeling_realm": "ocean", "standard_name": "ocean_vertical_heat_diffusivity", "units": "m2 s-1", @@ -304,13 +321,14 @@ "ok_max_mean_abs": "" }, "difvmbo": { + "frequency": "monC", "modeling_realm": "ocean", "standard_name": "ocean_vertical_momentum_diffusivity_due_to_background", "units": "m2 s-1", "cell_methods": "area: mean time: mean within years time: mean over years", "cell_measures": "area: areacello volume: volcello", - "long_name": "Ocean Vertical Momentum Diffusivity due to Background", - "comment": "", + "long_name": "Ocean Vertical Momentum Diffusivity Due to Background", + "comment": "Vertical/dianeutral diffusivity applied to momentum due to the background (i.e. caused by a time invariant imposed field which may be either constant over the globe or spatially varying, depending on the ocean model used).", "dimensions": "longitude latitude olevel time2", "out_name": "difvmbo", "type": "real", @@ -321,13 +339,14 @@ "ok_max_mean_abs": "" }, "difvmfdo": { + "frequency": "monC", "modeling_realm": "ocean", "standard_name": "ocean_vertical_momentum_diffusivity_due_to_form_drag", "units": "m2 s-1", "cell_methods": "area: mean time: mean within years time: mean over years", "cell_measures": "area: areacello volume: volcello", - "long_name": "Ocean Vertical Momentum Diffusivity due to Form Drag", - "comment": "", + "long_name": "Ocean Vertical Momentum Diffusivity Due to Form Drag", + "comment": "Vertical/dianeutral diffusivity applied to momentum due to form drag (i.e. resulting from a model scheme representing mesoscale eddy-induced form drag).", "dimensions": "longitude latitude olevel time2", "out_name": "difvmfdo", "type": "real", @@ -338,13 +357,14 @@ "ok_max_mean_abs": "" }, "difvmo": { + "frequency": "monC", "modeling_realm": "ocean", "standard_name": "ocean_vertical_momentum_diffusivity", "units": "m2 s-1", "cell_methods": "area: mean time: mean within years time: mean over years", "cell_measures": "area: areacello volume: volcello", "long_name": "Ocean Vertical Momentum Diffusivity", - "comment": "", + "comment": "Vertical/dianeutral diffusivity applied to momentum.", "dimensions": "longitude latitude olevel time2", "out_name": "difvmo", "type": "real", @@ -355,13 +375,14 @@ "ok_max_mean_abs": "" }, "difvmto": { + "frequency": "monC", "modeling_realm": "ocean", "standard_name": "ocean_vertical_momentum_diffusivity_due_to_tides", "units": "m2 s-1", "cell_methods": "area: mean time: mean within years time: mean over years", "cell_measures": "area: areacello volume: volcello", - "long_name": "Ocean Vertical Momentum Diffusivity due to Tides", - "comment": "", + "long_name": "Ocean Vertical Momentum Diffusivity Due to Tides", + "comment": "Diffusivity is also sometimes known as the coefficient of diffusion. Diffusion occurs as a result of a gradient in the spatial distribution of mass concentration, temperature or momentum. The diffusivity may be very different in the vertical and horizontal directions. The construction vertical_X_diffusivity means the vertical component of the diffusivity of X due to motion which is not resolved on the grid scale of the model. 'Due to tides' means due to all astronomical gravity changes which manifest as tides. No distinction is made between different tidal components. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", "dimensions": "longitude latitude olevel time2", "out_name": "difvmto", "type": "real", @@ -372,6 +393,7 @@ "ok_max_mean_abs": "" }, "difvso": { + "frequency": "monC", "modeling_realm": "ocean", "standard_name": "ocean_vertical_salt_diffusivity", "units": "m2 s-1", @@ -389,13 +411,14 @@ "ok_max_mean_abs": "" }, "difvtrbo": { + "frequency": "monC", "modeling_realm": "ocean", "standard_name": "ocean_vertical_tracer_diffusivity_due_to_background", "units": "m2 s-1", "cell_methods": "area: mean time: mean within years time: mean over years", "cell_measures": "area: areacello volume: volcello", - "long_name": "Ocean Vertical Tracer Diffusivity due to Background", - "comment": "", + "long_name": "Ocean Vertical Tracer Diffusivity Due to Background", + "comment": "Vertical/dianeutral diffusivity applied to tracers due to the background (i.e. caused by a time invariant imposed field which may be either constant over the globe or spatially varying, depending on the ocean model used).", "dimensions": "longitude latitude olevel time2", "out_name": "difvtrbo", "type": "real", @@ -406,13 +429,14 @@ "ok_max_mean_abs": "" }, "difvtrto": { + "frequency": "monC", "modeling_realm": "ocean", "standard_name": "ocean_vertical_tracer_diffusivity_due_to_tides", "units": "m2 s-1", "cell_methods": "area: mean time: mean within years time: mean over years", "cell_measures": "area: areacello volume: volcello", - "long_name": "Ocean Vertical Tracer Diffusivity due to Tides", - "comment": "", + "long_name": "Ocean Vertical Tracer Diffusivity Due to Tides", + "comment": "Vertical/dianeutral diffusivity applied to tracers due to tides (i.e. caused by astronomical gravity changes which manifest as tides).", "dimensions": "longitude latitude olevel time2", "out_name": "difvtrto", "type": "real", @@ -423,13 +447,14 @@ "ok_max_mean_abs": "" }, "dispkevfo": { + "frequency": "monC", "modeling_realm": "ocean", "standard_name": "ocean_kinetic_energy_dissipation_per_unit_area_due_to_vertical_friction", "units": "W m-2", "cell_methods": "area: mean time: mean within years time: mean over years", "cell_measures": "area: areacello volume: volcello", - "long_name": "Ocean Kinetic Energy Dissipation Per Unit Area due to Vertical Friction", - "comment": "", + "long_name": "Ocean Kinetic Energy Dissipation per Unit Area Due to Vertical Friction", + "comment": "Friction, leading to the dissipation of kinetic energy, arises in ocean models as a result of the viscosity of sea water. Generally, the lateral (xy) viscosity is given a large value to maintain the numerical stability of the model. In contrast, the vertical viscosity is usually much smaller. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase.", "dimensions": "longitude latitude olevel time2", "out_name": "dispkevfo", "type": "real", @@ -440,12 +465,13 @@ "ok_max_mean_abs": "" }, "dispkexyfo": { + "frequency": "monC", "modeling_realm": "ocean", "standard_name": "ocean_kinetic_energy_dissipation_per_unit_area_due_to_xy_friction", "units": "W m-2", "cell_methods": "area: mean time: mean within years time: mean over years", "cell_measures": "area: areacello volume: volcello", - "long_name": "Ocean Kinetic Energy Dissipation Per Unit Area due to XY Friction", + "long_name": "Ocean Kinetic Energy Dissipation per Unit Area Due to XY Friction", "comment": "Depth integrated impacts on kinetic energy arising from lateral frictional dissipation associated with Laplacian and/or biharmonic viscosity. For CMIP5, this diagnostic was 3d, whereas the CMIP6 depth integrated diagnostic is sufficient for many purposes and reduces archive requirements.", "dimensions": "longitude latitude olevel time2", "out_name": "dispkexyfo", @@ -457,12 +483,13 @@ "ok_max_mean_abs": "" }, "dispkexyfo2d": { + "frequency": "monC", "modeling_realm": "ocean", "standard_name": "ocean_kinetic_energy_dissipation_per_unit_area_due_to_xy_friction", "units": "W m-2", "cell_methods": "area: mean time: mean within years time: mean over years", "cell_measures": "area: areacello", - "long_name": "Ocean Kinetic Energy Dissipation Per Unit Area due to XY Friction", + "long_name": "Ocean Kinetic Energy Dissipation per Unit Area Due to XY Friction", "comment": "Depth integrated impacts on kinetic energy arising from lateral frictional dissipation associated with Laplacian and/or biharmonic viscosity. For CMIP5, this diagnostic was 3d, whereas the CMIP6 depth integrated diagnostic is sufficient for many purposes and reduces archive requirements.", "dimensions": "longitude latitude time2", "out_name": "dispkexyfo", @@ -474,12 +501,13 @@ "ok_max_mean_abs": "" }, "tnkebto": { + "frequency": "monC", "modeling_realm": "ocean", - "standard_name": "tendency_of_ocean_eddy_kinetic_energy_content_due_to_bolus_transport", + "standard_name": "tendency_of_ocean_eddy_kinetic_energy_content_due_to_parameterized_eddy_advection", "units": "W m-2", "cell_methods": "area: mean time: mean within years time: mean over years", "cell_measures": "area: areacello volume: volcello", - "long_name": "Tendency of Ocean Eddy Kinetic Energy Content due to Bolus Transport", + "long_name": "Tendency of Ocean Eddy Kinetic Energy Content Due to Parameterized Eddy Advection", "comment": "Depth integrated impacts on kinetic energy arising from parameterized eddy-induced advection. For CMIP5, this diagnostic was 3d, whereas the CMIP6 depth integrated diagnostic is sufficient for many purposes and reduces archive requirements.", "dimensions": "longitude latitude olevel time2", "out_name": "tnkebto", @@ -491,12 +519,13 @@ "ok_max_mean_abs": "" }, "tnkebto2d": { + "frequency": "monC", "modeling_realm": "ocean", - "standard_name": "tendency_of_ocean_eddy_kinetic_energy_content_due_to_bolus_transport", + "standard_name": "tendency_of_ocean_eddy_kinetic_energy_content_due_to_parameterized_eddy_advection", "units": "W m-2", "cell_methods": "area: mean time: mean within years time: mean over years", "cell_measures": "area: areacello", - "long_name": "Tendency of Ocean Eddy Kinetic Energy Content due to Bolus Transport", + "long_name": "Tendency of Ocean Eddy Kinetic Energy Content Due to Parameterized Eddy Advection", "comment": "Depth integrated impacts on kinetic energy arising from parameterized eddy-induced advection. For CMIP5, this diagnostic was 3d, whereas the CMIP6 depth integrated diagnostic is sufficient for many purposes and reduces archive requirements.", "dimensions": "longitude latitude time2", "out_name": "tnkebto", @@ -508,6 +537,7 @@ "ok_max_mean_abs": "" }, "tnpeo": { + "frequency": "monC", "modeling_realm": "ocean", "standard_name": "tendency_of_ocean_potential_energy_content", "units": "W m-2", @@ -525,13 +555,14 @@ "ok_max_mean_abs": "" }, "tnpeot": { + "frequency": "monC", "modeling_realm": "ocean", "standard_name": "tendency_of_ocean_potential_energy_content_due_to_tides", "units": "W m-2", "cell_methods": "area: mean time: mean within years time: mean over years", "cell_measures": "area: areacello volume: volcello", - "long_name": "Tendency of Ocean Potential Energy Content due to Tides", - "comment": "", + "long_name": "Tendency of Ocean Potential Energy Content Due to Tides", + "comment": "'Content' indicates a quantity per unit area. Potential energy is the sum of the gravitational potential energy relative to the geoid and the centripetal potential energy. (The geopotential is the specific potential energy.) 'Due to tides' means due to all astronomical gravity changes which manifest as tides. No distinction is made between different tidal components. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. 'tendency_of_X' means derivative of X with respect to time.", "dimensions": "longitude latitude olevel time2", "out_name": "tnpeot", "type": "real", @@ -542,13 +573,14 @@ "ok_max_mean_abs": "" }, "tnpeotb": { + "frequency": "monC", "modeling_realm": "ocean", "standard_name": "tendency_of_ocean_potential_energy_content_due_to_background", "units": "W m-2", "cell_methods": "area: mean time: mean within years time: mean over years", "cell_measures": "area: areacello volume: volcello", - "long_name": "Tendency of Ocean Potential Energy Content due to Background", - "comment": "", + "long_name": "Tendency of Ocean Potential Energy Content Due to Background", + "comment": "'Content' indicates a quantity per unit area. Potential energy is the sum of the gravitational potential energy relative to the geoid and the centripetal potential energy. (The geopotential is the specific potential energy.) 'Due to background' means caused by a time invariant imposed field which may be either constant over the globe or spatially varying, depending on the ocean model used. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. 'tendency_of_X' means derivative of X with respect to time.", "dimensions": "longitude latitude olevel time2", "out_name": "tnpeotb", "type": "real", @@ -559,6 +591,7 @@ "ok_max_mean_abs": "" }, "zfullo": { + "frequency": "monC", "modeling_realm": "ocean", "standard_name": "depth_below_geoid", "units": "m", @@ -576,14 +609,15 @@ "ok_max_mean_abs": "" }, "zhalfo": { + "frequency": "monC", "modeling_realm": "ocean", "standard_name": "depth_below_geoid", "units": "m", "cell_methods": "area: mean time: mean within years time: mean over years", - "cell_measures": "area: areacello volume: volcello", + "cell_measures": "area: areacello", "long_name": "Depth Below Geoid of Interfaces Between Ocean Layers", "comment": "Depth below geoid", - "dimensions": "longitude latitude olevel time2", + "dimensions": "longitude latitude olevhalf time2", "out_name": "zhalfo", "type": "real", "positive": "", diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Oday.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Oday.json index 761e264812..1523a37457 100644 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Oday.json +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Oday.json @@ -1,26 +1,27 @@ { "Header": { - "data_specs_version": "01.00.10", + "data_specs_version": "01.00.30", + "cmor_version": "3.4", "table_id": "Table Oday", - "realm": "ocnBgChem", - "frequency": "day", - "cmor_version": "3.2", - "table_date": "10 May 2017", + "realm": "ocnBgchem", + "table_date": "11 March 2019", "missing_value": "1e20", + "int_missing_value": "-999", "product": "model-output", "approx_interval": "1.00000", - "generic_levels": "", + "generic_levels": "olevel", "mip_era": "CMIP6", - "Conventions": "CF-1.7 CMIP-6.0" + "Conventions": "CF-1.7 CMIP-6.2" }, "variable_entry": { "chlos": { - "modeling_realm": "ocnBgChem", + "frequency": "day", + "modeling_realm": "ocnBgchem", "standard_name": "mass_concentration_of_phytoplankton_expressed_as_chlorophyll_in_sea_water", "units": "kg m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Sea Surface Total Chlorophyll Mass Concentration", + "long_name": "Surface Mass Concentration of Total Phytoplankton Expressed as Chlorophyll in Sea Water", "comment": "Sum of chlorophyll from all phytoplankton group concentrations at the sea surface. In most models this is equal to chldiat+chlmisc, that is the sum of 'Diatom Chlorophyll Mass Concentration' plus 'Other Phytoplankton Chlorophyll Mass Concentration'", "dimensions": "longitude latitude time", "out_name": "chlos", @@ -32,13 +33,14 @@ "ok_max_mean_abs": "" }, "omldamax": { + "frequency": "day", "modeling_realm": "ocean", "standard_name": "ocean_mixed_layer_thickness_defined_by_mixing_scheme", "units": "m", "cell_methods": "area: mean time: maximum", "cell_measures": "area: areacello", - "long_name": "Daily Maximum Ocean Mixed Layer Thickness Defined by Mixing Scheme", - "comment": "", + "long_name": "Mean Daily Maximum Ocean Mixed Layer Thickness Defined by Mixing Scheme", + "comment": "The ocean mixed layer is the upper part of the ocean, regarded as being well-mixed. The base of the mixed layer defined by the mixing scheme is a diagnostic of ocean models. 'Thickness' means the vertical extent of a layer.", "dimensions": "longitude latitude time", "out_name": "omldamax", "type": "real", @@ -49,7 +51,8 @@ "ok_max_mean_abs": "" }, "phycos": { - "modeling_realm": "ocnBgChem", + "frequency": "day", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_phytoplankton_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", @@ -66,13 +69,14 @@ "ok_max_mean_abs": "" }, "sos": { + "frequency": "day", "modeling_realm": "ocean", "standard_name": "sea_surface_salinity", "units": "0.001", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", "long_name": "Sea Surface Salinity", - "comment": "", + "comment": "Sea water salinity is the salt content of sea water, often on the Practical Salinity Scale of 1978. However, the unqualified term 'salinity' is generic and does not necessarily imply any particular method of calculation. The units of salinity are dimensionless and the units attribute should normally be given as 1e-3 or 0.001 i.e. parts per thousand. ", "dimensions": "longitude latitude time", "out_name": "sos", "type": "real", @@ -83,13 +87,14 @@ "ok_max_mean_abs": "" }, "sossq": { + "frequency": "day", "modeling_realm": "ocean", "standard_name": "square_of_sea_surface_salinity", "units": "1e-06", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", "long_name": "Square of Sea Surface Salinity", - "comment": "", + "comment": "Sea water salinity is the salt content of sea water, often on the Practical Salinity Scale of 1978. However, the unqualified term 'salinity' is generic and does not necessarily imply any particular method of calculation. The units of salinity are dimensionless and the units attribute should normally be given as 1e-3 or 0.001 i.e. parts per thousand. ", "dimensions": "longitude latitude time", "out_name": "sossq", "type": "real", @@ -100,13 +105,14 @@ "ok_max_mean_abs": "" }, "tos": { + "frequency": "day", "modeling_realm": "ocean", "standard_name": "sea_surface_temperature", - "units": "K", + "units": "degC", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", "long_name": "Sea Surface Temperature", - "comment": "temperature of liquid ocean. Note that the correct standard_name for this variable is 'sea_surface_temperature', not 'surface_temperature', but this was discovered too late to correct. To maintain consistency across CMIP5 models, the wrong standard_name will continue to be used.", + "comment": "Temperature of upper boundary of the liquid ocean, including temperatures below sea-ice and floating ice shelves.", "dimensions": "longitude latitude time", "out_name": "tos", "type": "real", @@ -117,13 +123,14 @@ "ok_max_mean_abs": "" }, "tossq": { + "frequency": "day", "modeling_realm": "ocean", "standard_name": "square_of_sea_surface_temperature", "units": "degC2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", "long_name": "Square of Sea Surface Temperature", - "comment": "square of temperature of liquid ocean, averaged over the day.", + "comment": "Square of temperature of liquid ocean.", "dimensions": "longitude latitude time", "out_name": "tossq", "type": "real", diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Odec.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Odec.json index 40438fe53b..b892357bb1 100644 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Odec.json +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Odec.json @@ -1,20 +1,21 @@ { "Header": { - "data_specs_version": "01.00.10", + "data_specs_version": "01.00.30", + "cmor_version": "3.4", "table_id": "Table Odec", "realm": "ocean", - "frequency": "dec", - "cmor_version": "3.2", - "table_date": "10 May 2017", + "table_date": "11 March 2019", "missing_value": "1e20", + "int_missing_value": "-999", "product": "model-output", - "approx_interval": "", - "generic_levels": "olevel", + "approx_interval": "3650.00000", + "generic_levels": "olevel", "mip_era": "CMIP6", - "Conventions": "CF-1.7 CMIP-6.0" + "Conventions": "CF-1.7 CMIP-6.2" }, "variable_entry": { "agessc": { + "frequency": "dec", "modeling_realm": "ocean", "standard_name": "sea_water_age_since_surface_contact", "units": "yr", @@ -31,7 +32,26 @@ "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, + "bigthetao": { + "frequency": "dec", + "modeling_realm": "ocean", + "standard_name": "sea_water_conservative_temperature", + "units": "degC", + "cell_methods": "area: mean where sea time: mean", + "cell_measures": "area: areacello volume: volcello", + "long_name": "Sea Water Conservative Temperature", + "comment": "Sea water conservative temperature (this should be contributed only for models using conservative temperature as prognostic field)", + "dimensions": "longitude latitude olevel time", + "out_name": "bigthetao", + "type": "real", + "positive": "", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, "bigthetaoga": { + "frequency": "dec", "modeling_realm": "ocean", "standard_name": "sea_water_conservative_temperature", "units": "degC", @@ -49,11 +69,12 @@ "ok_max_mean_abs": "" }, "hfbasin": { + "frequency": "dec", "modeling_realm": "ocean", "standard_name": "northward_ocean_heat_transport", "units": "W", - "cell_methods": "longitude: mean (basin) time: mean", - "cell_measures": "area: areacella", + "cell_methods": "longitude: sum (comment: basin sum [along zig-zag grid path]) depth: sum time: mean", + "cell_measures": "", "long_name": "Northward Ocean Heat Transport", "comment": "Contains contributions from all physical processes affecting the northward heat transport, including resolved advection, parameterized advection, lateral diffusion, etc. Diagnosed here as a function of latitude and basin. Use Celsius for temperature scale.", "dimensions": "latitude basin time", @@ -66,6 +87,7 @@ "ok_max_mean_abs": "" }, "hfds": { + "frequency": "dec", "modeling_realm": "ocean", "standard_name": "surface_downward_heat_flux_in_sea_water", "units": "W m-2", @@ -82,14 +104,33 @@ "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, + "masscello": { + "frequency": "dec", + "modeling_realm": "ocean", + "standard_name": "sea_water_mass_per_unit_area", + "units": "kg m-2", + "cell_methods": "area: mean where sea time: mean", + "cell_measures": "area: areacello volume: volcello", + "long_name": "Ocean Grid-Cell Mass per Area", + "comment": "Tracer grid-cell mass per unit area used for computing tracer budgets. For Boussinesq models with static ocean grid cell thickness, masscello = rhozero*thickcello, where thickcello is static cell thickness and rhozero is constant Boussinesq reference density. More generally, masscello is time dependent and reported as part of Omon.", + "dimensions": "longitude latitude olevel time", + "out_name": "masscello", + "type": "real", + "positive": "", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, "masso": { + "frequency": "dec", "modeling_realm": "ocean", "standard_name": "sea_water_mass", "units": "kg", "cell_methods": "area: sum where sea time: mean", "cell_measures": "", "long_name": "Sea Water Mass", - "comment": "Total mass of liquid seawater. For Boussinesq models, report this diagnostic as Boussinesq reference density times total volume.", + "comment": "Total mass of liquid sea water. For Boussinesq models, report this diagnostic as Boussinesq reference density times total volume.", "dimensions": "time", "out_name": "masso", "type": "real", @@ -99,16 +140,71 @@ "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, - "msftmyz": { + "msftmrho": { + "frequency": "dec", "modeling_realm": "ocean", "standard_name": "ocean_meridional_overturning_mass_streamfunction", "units": "kg s-1", - "cell_methods": "longitude: mean (comment: basin mean[ along zig-zag grid path]) time: mean", - "cell_measures": "area: areacella", + "cell_methods": "longitude: sum (comment: basin sum [along zig-zag grid path]) depth: sum time: mean", + "cell_measures": "", + "long_name": "Ocean Meridional Overturning Mass Streamfunction", + "comment": "Overturning mass streamfunction arising from all advective mass transport processes, resolved and parameterized.", + "dimensions": "latitude rho basin time", + "out_name": "msftmrho", + "type": "real", + "positive": "", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, + "msftmz": { + "frequency": "dec", + "modeling_realm": "ocean", + "standard_name": "ocean_meridional_overturning_mass_streamfunction", + "units": "kg s-1", + "cell_methods": "longitude: sum (comment: basin sum [along zig-zag grid path]) depth: sum time: mean", + "cell_measures": "", "long_name": "Ocean Meridional Overturning Mass Streamfunction", "comment": "Overturning mass streamfunction arising from all advective mass transport processes, resolved and parameterized.", "dimensions": "latitude olevel basin time", - "out_name": "msftmyz", + "out_name": "msftmz", + "type": "real", + "positive": "", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, + "msftyrho": { + "frequency": "dec", + "modeling_realm": "ocean", + "standard_name": "ocean_y_overturning_mass_streamfunction", + "units": "kg s-1", + "cell_methods": "time: mean grid_longitude: mean", + "cell_measures": "", + "long_name": "Ocean Y Overturning Mass Streamfunction", + "comment": "Overturning mass streamfunction arising from all advective mass transport processes, resolved and parameterized.", + "dimensions": "gridlatitude rho basin time", + "out_name": "msftyrho", + "type": "real", + "positive": "", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, + "msftyz": { + "frequency": "dec", + "modeling_realm": "ocean", + "standard_name": "ocean_y_overturning_mass_streamfunction", + "units": "kg s-1", + "cell_methods": "time: mean grid_longitude: mean", + "cell_measures": "", + "long_name": "Ocean Y Overturning Mass Streamfunction", + "comment": "Overturning mass streamfunction arising from all advective mass transport processes, resolved and parameterized.", + "dimensions": "gridlatitude olevel basin time", + "out_name": "msftyz", "type": "real", "positive": "", "valid_min": "", @@ -117,6 +213,7 @@ "ok_max_mean_abs": "" }, "sfdsi": { + "frequency": "dec", "modeling_realm": "ocean seaIce", "standard_name": "downward_sea_ice_basal_salt_flux", "units": "kg m-2 s-1", @@ -127,13 +224,14 @@ "dimensions": "longitude latitude time", "out_name": "sfdsi", "type": "real", - "positive": "", + "positive": "down", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "sfriver": { + "frequency": "dec", "modeling_realm": "ocean", "standard_name": "salt_flux_into_sea_water_from_rivers", "units": "kg m-2 s-1", @@ -151,13 +249,14 @@ "ok_max_mean_abs": "" }, "so": { + "frequency": "dec", "modeling_realm": "ocean", "standard_name": "sea_water_salinity", "units": "0.001", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", "long_name": "Sea Water Salinity", - "comment": "", + "comment": "Sea water salinity is the salt content of sea water, often on the Practical Salinity Scale of 1978. However, the unqualified term 'salinity' is generic and does not necessarily imply any particular method of calculation. The units of salinity are dimensionless and the units attribute should normally be given as 1e-3 or 0.001 i.e. parts per thousand. ", "dimensions": "longitude latitude olevel time", "out_name": "so", "type": "real", @@ -168,13 +267,14 @@ "ok_max_mean_abs": "" }, "soga": { + "frequency": "dec", "modeling_realm": "ocean", "standard_name": "sea_water_salinity", "units": "0.001", "cell_methods": "area: mean where sea time: mean", "cell_measures": "", "long_name": "Global Mean Sea Water Salinity", - "comment": "", + "comment": "Sea water salinity is the salt content of sea water, often on the Practical Salinity Scale of 1978. However, the unqualified term 'salinity' is generic and does not necessarily imply any particular method of calculation. The units of salinity are dimensionless and the units attribute should normally be given as 1e-3 or 0.001 i.e. parts per thousand. ", "dimensions": "time", "out_name": "soga", "type": "real", @@ -185,13 +285,14 @@ "ok_max_mean_abs": "" }, "sos": { + "frequency": "dec", "modeling_realm": "ocean", "standard_name": "sea_surface_salinity", "units": "0.001", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", "long_name": "Sea Surface Salinity", - "comment": "", + "comment": "Sea water salinity is the salt content of sea water, often on the Practical Salinity Scale of 1978. However, the unqualified term 'salinity' is generic and does not necessarily imply any particular method of calculation. The units of salinity are dimensionless and the units attribute should normally be given as 1e-3 or 0.001 i.e. parts per thousand. ", "dimensions": "longitude latitude time", "out_name": "sos", "type": "real", @@ -202,13 +303,14 @@ "ok_max_mean_abs": "" }, "sosga": { + "frequency": "dec", "modeling_realm": "ocean", "standard_name": "sea_surface_salinity", "units": "0.001", "cell_methods": "area: mean where sea time: mean", "cell_measures": "", "long_name": "Global Average Sea Surface Salinity", - "comment": "", + "comment": "Sea water salinity is the salt content of sea water, often on the Practical Salinity Scale of 1978. However, the unqualified term 'salinity' is generic and does not necessarily imply any particular method of calculation. The units of salinity are dimensionless and the units attribute should normally be given as 1e-3 or 0.001 i.e. parts per thousand. ", "dimensions": "time", "out_name": "sosga", "type": "real", @@ -219,6 +321,7 @@ "ok_max_mean_abs": "" }, "tauuo": { + "frequency": "dec", "modeling_realm": "ocean", "standard_name": "surface_downward_x_stress", "units": "N m-2", @@ -236,6 +339,7 @@ "ok_max_mean_abs": "" }, "tauvo": { + "frequency": "dec", "modeling_realm": "ocean", "standard_name": "surface_downward_y_stress", "units": "N m-2", @@ -253,6 +357,7 @@ "ok_max_mean_abs": "" }, "thetao": { + "frequency": "dec", "modeling_realm": "ocean", "standard_name": "sea_water_potential_temperature", "units": "degC", @@ -270,6 +375,7 @@ "ok_max_mean_abs": "" }, "thetaoga": { + "frequency": "dec", "modeling_realm": "ocean", "standard_name": "sea_water_potential_temperature", "units": "degC", @@ -287,13 +393,14 @@ "ok_max_mean_abs": "" }, "thkcello": { + "frequency": "dec", "modeling_realm": "ocean", "standard_name": "cell_thickness", "units": "m", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", "long_name": "Ocean Model Cell Thickness", - "comment": "", + "comment": "'Thickness' means the vertical extent of a layer. 'Cell' refers to a model grid-cell.", "dimensions": "longitude latitude olevel time", "out_name": "thkcello", "type": "real", @@ -304,13 +411,14 @@ "ok_max_mean_abs": "" }, "tos": { + "frequency": "dec", "modeling_realm": "ocean", "standard_name": "sea_surface_temperature", - "units": "K", + "units": "degC", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", "long_name": "Sea Surface Temperature", - "comment": "temperature of liquid ocean. Note that the correct standard_name for this variable is 'sea_surface_temperature', not 'surface_temperature', but this was discovered too late to correct. To maintain consistency across CMIP5 models, the wrong standard_name will continue to be used.", + "comment": "Temperature of upper boundary of the liquid ocean, including temperatures below sea-ice and floating ice shelves.", "dimensions": "longitude latitude time", "out_name": "tos", "type": "real", @@ -321,13 +429,14 @@ "ok_max_mean_abs": "" }, "tosga": { + "frequency": "dec", "modeling_realm": "ocean", "standard_name": "sea_surface_temperature", "units": "degC", "cell_methods": "area: mean where sea time: mean", "cell_measures": "", "long_name": "Global Average Sea Surface Temperature", - "comment": "This may differ from 'surface temperature' in regions of sea ice.This may differ from 'surface temperature' in regions of sea ice.For models using conservative temperature as prognostic field, they should report the SST as surface potent", + "comment": "Temperature of upper boundary of the liquid ocean, including temperatures below sea-ice and floating ice shelves.", "dimensions": "time", "out_name": "tosga", "type": "real", @@ -338,6 +447,7 @@ "ok_max_mean_abs": "" }, "uo": { + "frequency": "dec", "modeling_realm": "ocean", "standard_name": "sea_water_x_velocity", "units": "m s-1", @@ -355,13 +465,14 @@ "ok_max_mean_abs": "" }, "vo": { + "frequency": "dec", "modeling_realm": "ocean", "standard_name": "sea_water_y_velocity", "units": "m s-1", "cell_methods": "time: mean", "cell_measures": "--OPT", "long_name": "Sea Water Y Velocity", - "comment": "Prognostic x-ward velocity component resolved by the model.", + "comment": "Prognostic y-ward velocity component resolved by the model.", "dimensions": "longitude latitude olevel time", "out_name": "vo", "type": "real", @@ -371,14 +482,33 @@ "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, + "volcello": { + "frequency": "dec", + "modeling_realm": "ocean", + "standard_name": "ocean_volume", + "units": "m3", + "cell_methods": "area: mean where sea time: mean", + "cell_measures": "area: areacello volume: volcello", + "long_name": "Ocean Grid-Cell Volume", + "comment": "grid-cell volume ca. 2000.", + "dimensions": "longitude latitude olevel time", + "out_name": "volcello", + "type": "real", + "positive": "", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, "volo": { + "frequency": "dec", "modeling_realm": "ocean", "standard_name": "sea_water_volume", "units": "m3", "cell_methods": "area: sum where sea time: mean", "cell_measures": "", "long_name": "Sea Water Volume", - "comment": "Total volume of liquid seawater.", + "comment": "Total volume of liquid sea water.", "dimensions": "time", "out_name": "volo", "type": "real", @@ -389,6 +519,7 @@ "ok_max_mean_abs": "" }, "wfo": { + "frequency": "dec", "modeling_realm": "ocean", "standard_name": "water_flux_into_sea_water", "units": "kg m-2 s-1", @@ -406,13 +537,14 @@ "ok_max_mean_abs": "" }, "wo": { + "frequency": "dec", "modeling_realm": "ocean", "standard_name": "upward_sea_water_velocity", "units": "m s-1", "cell_methods": "time: mean", "cell_measures": "--OPT", - "long_name": "Sea Water Z Velocity", - "comment": "", + "long_name": "Sea Water Vertical Velocity", + "comment": "A velocity is a vector quantity. 'Upward' indicates a vector component which is positive when directed upward (negative downward).", "dimensions": "longitude latitude olevel time", "out_name": "wo", "type": "real", diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Ofx.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Ofx.json index f3ba8bd78e..d63312c474 100644 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Ofx.json +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Ofx.json @@ -1,26 +1,27 @@ { "Header": { - "data_specs_version": "01.00.10", + "data_specs_version": "01.00.30", + "cmor_version": "3.4", "table_id": "Table Ofx", "realm": "ocean", - "frequency": "fx", - "cmor_version": "3.2", - "table_date": "10 May 2017", + "table_date": "11 March 2019", "missing_value": "1e20", + "int_missing_value": "-999", "product": "model-output", - "approx_interval": "", - "generic_levels": "olevel", + "approx_interval": "0.00000", + "generic_levels": "olevel", "mip_era": "CMIP6", - "Conventions": "CF-1.7 CMIP-6.0" + "Conventions": "CF-1.7 CMIP-6.2" }, "variable_entry": { "areacello": { + "frequency": "fx", "modeling_realm": "ocean", "standard_name": "cell_area", "units": "m2", - "cell_methods": "area: mean", - "cell_measures": "area: areacello", - "long_name": "Ocean Grid-Cell Area", + "cell_methods": "area: sum", + "cell_measures": "", + "long_name": "Grid-Cell Area for Ocean Variables", "comment": "Horizontal area of ocean grid cells", "dimensions": "longitude latitude", "out_name": "areacello", @@ -32,13 +33,14 @@ "ok_max_mean_abs": "" }, "basin": { + "frequency": "fx", "modeling_realm": "ocean", "standard_name": "region", - "units": "1.0", + "units": "1", "cell_methods": "area: mean", "cell_measures": "area: areacello", "long_name": "Region Selection Index", - "comment": "", + "comment": "A variable with the standard name of region contains strings which indicate geographical regions. These strings must be chosen from the standard region list.", "dimensions": "longitude latitude", "out_name": "basin", "type": "integer", @@ -51,10 +53,11 @@ "ok_max_mean_abs": "" }, "deptho": { + "frequency": "fx", "modeling_realm": "ocean", "standard_name": "sea_floor_depth_below_geoid", "units": "m", - "cell_methods": "area: mean", + "cell_methods": "area: mean where sea", "cell_measures": "area: areacello", "long_name": "Sea Floor Depth Below Geoid", "comment": "Ocean bathymetry. Reported here is the sea floor depth for present day relative to z=0 geoid. Reported as missing for land grid cells.", @@ -68,13 +71,14 @@ "ok_max_mean_abs": "" }, "hfgeou": { + "frequency": "fx", "modeling_realm": "ocean", "standard_name": "upward_geothermal_heat_flux_at_sea_floor", "units": "W m-2", - "cell_methods": "area: mean", + "cell_methods": "area: mean where sea", "cell_measures": "area: areacello", "long_name": "Upward Geothermal Heat Flux at Sea Floor", - "comment": "", + "comment": "Upward geothermal heat flux per unit area on the sea floor", "dimensions": "longitude latitude", "out_name": "hfgeou", "type": "real", @@ -85,12 +89,13 @@ "ok_max_mean_abs": "" }, "masscello": { + "frequency": "fx", "modeling_realm": "ocean", "standard_name": "sea_water_mass_per_unit_area", "units": "kg m-2", "cell_methods": "area: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Ocean Grid-Cell Mass per area", + "long_name": "Ocean Grid-Cell Mass per Area", "comment": "Tracer grid-cell mass per unit area used for computing tracer budgets. For Boussinesq models with static ocean grid cell thickness, masscello = rhozero*thickcello, where thickcello is static cell thickness and rhozero is constant Boussinesq reference density. More generally, masscello is time dependent and reported as part of Omon.", "dimensions": "longitude latitude olevel", "out_name": "masscello", @@ -102,14 +107,15 @@ "ok_max_mean_abs": "" }, "sftof": { + "frequency": "fx", "modeling_realm": "ocean", "standard_name": "sea_area_fraction", "units": "%", "cell_methods": "area: mean", "cell_measures": "area: areacello", - "long_name": "Sea Area Fraction", - "comment": "This is the area fraction at the ocean surface.", - "dimensions": "longitude latitude typesea", + "long_name": "Sea Area Percentage", + "comment": "Percentage of horizontal area occupied by ocean.", + "dimensions": "longitude latitude", "out_name": "sftof", "type": "real", "positive": "", @@ -119,13 +125,14 @@ "ok_max_mean_abs": "" }, "thkcello": { + "frequency": "fx", "modeling_realm": "ocean", "standard_name": "cell_thickness", "units": "m", "cell_methods": "area: mean", "cell_measures": "area: areacello volume: volcello", "long_name": "Ocean Model Cell Thickness", - "comment": "", + "comment": "'Thickness' means the vertical extent of a layer. 'Cell' refers to a model grid-cell.", "dimensions": "longitude latitude olevel", "out_name": "thkcello", "type": "real", @@ -135,17 +142,18 @@ "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, - "ugrid": { + "ugrido": { + "frequency": "fx", "modeling_realm": "ocean", - "standard_name": "missing", + "standard_name": "longitude", "units": "", "cell_methods": "", "cell_measures": "--UGRID", - "long_name": "UGRID Grid Information", - "comment": "", + "long_name": "UGRID Grid Specification", + "comment": "Ony required for models with unstructured grids: this label should be used for a file containing information about the grid structure, following the UGRID convention.", "dimensions": "longitude latitude", "out_name": "ugrido", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -153,6 +161,7 @@ "ok_max_mean_abs": "" }, "volcello": { + "frequency": "fx", "modeling_realm": "ocean", "standard_name": "ocean_volume", "units": "m3", diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Omon.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Omon.json index 0935e8ec9e..6cd5161f88 100644 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Omon.json +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Omon.json @@ -1,20 +1,21 @@ { "Header": { - "data_specs_version": "01.00.10", + "data_specs_version": "01.00.30", + "cmor_version": "3.4", "table_id": "Table Omon", - "realm": "ocnBgChem", - "frequency": "mon", - "cmor_version": "3.2", - "table_date": "10 May 2017", + "realm": "ocnBgchem", + "table_date": "11 March 2019", "missing_value": "1e20", + "int_missing_value": "-999", "product": "model-output", "approx_interval": "30.00000", "generic_levels": "olevel", "mip_era": "CMIP6", - "Conventions": "CF-1.7 CMIP-6.0" + "Conventions": "CF-1.7 CMIP-6.2" }, "variable_entry": { "agessc": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "sea_water_age_since_surface_contact", "units": "yr", @@ -32,14 +33,15 @@ "ok_max_mean_abs": "" }, "arag": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_aragonite_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", + "cell_measures": "area: areacello volume: volcello", "long_name": "Aragonite Concentration", "comment": "Sum of particulate aragonite components (e.g. Phytoplankton, Detrital, etc.)", - "dimensions": "longitude latitude time depth0m", + "dimensions": "longitude latitude olevel time", "out_name": "arag", "type": "real", "positive": "", @@ -49,8 +51,9 @@ "ok_max_mean_abs": "" }, "aragos": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_mole_concentration_of_aragonite_epressed_as_carbon_in_sea_water", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_aragonite_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", @@ -66,14 +69,15 @@ "ok_max_mean_abs": "" }, "bacc": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_bacteria_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", + "cell_measures": "area: areacello volume: volcello", "long_name": "Bacterial Carbon Concentration", "comment": "Sum of bacterial carbon component concentrations", - "dimensions": "longitude latitude time depth0m", + "dimensions": "longitude latitude olevel time", "out_name": "bacc", "type": "real", "positive": "", @@ -83,13 +87,14 @@ "ok_max_mean_abs": "" }, "baccos": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_mole_concentration_of_bacteria_expressed_as_carbon_in_sea_water", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_bacteria_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", "long_name": "Surface Bacterial Carbon Concentration", - "comment": "sum of bacterial carbon component concentrations", + "comment": "Sum of bacterial carbon component concentrations", "dimensions": "longitude latitude time", "out_name": "baccos", "type": "real", @@ -100,14 +105,15 @@ "ok_max_mean_abs": "" }, "bfe": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_particulate_organic_matter_expressed_as_iron_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", - "long_name": "Mole Concentration of Particulate Organic Matter expressed as Iron in sea water", + "cell_measures": "area: areacello volume: volcello", + "long_name": "Mole Concentration of Particulate Organic Matter Expressed as Iron in Sea Water", "comment": "Sum of particulate organic iron component concentrations", - "dimensions": "longitude latitude time depth0m", + "dimensions": "longitude latitude olevel time", "out_name": "bfe", "type": "real", "positive": "", @@ -117,12 +123,13 @@ "ok_max_mean_abs": "" }, "bfeos": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_mole_concentration_of_particulate_organic_matter_expressed_as_iron_in_sea_water", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_particulate_organic_matter_expressed_as_iron_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Surface Mole Concentration of Particulate Organic Matter expressed as Iron in sea water", + "long_name": "Surface Mole Concentration of Particulate Organic Matter Expressed as Iron in Sea Water", "comment": "sum of particulate organic iron component concentrations", "dimensions": "longitude latitude time", "out_name": "bfeos", @@ -134,12 +141,13 @@ "ok_max_mean_abs": "" }, "bigthetao": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "sea_water_conservative_temperature", "units": "degC", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Sea Water Convervative Temperature", + "long_name": "Sea Water Conservative Temperature", "comment": "Sea water conservative temperature (this should be contributed only for models using conservative temperature as prognostic field)", "dimensions": "longitude latitude olevel time", "out_name": "bigthetao", @@ -151,6 +159,7 @@ "ok_max_mean_abs": "" }, "bigthetaoga": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "sea_water_conservative_temperature", "units": "degC", @@ -168,14 +177,15 @@ "ok_max_mean_abs": "" }, "bsi": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_particulate_matter_expressed_as_silicon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", - "long_name": "Mole Concentration of Particulate Organic Matter expressed as silicon in sea water", + "cell_measures": "area: areacello volume: volcello", + "long_name": "Mole Concentration of Particulate Organic Matter Expressed as Silicon in Sea Water", "comment": "Sum of particulate silica component concentrations", - "dimensions": "longitude latitude time depth0m", + "dimensions": "longitude latitude olevel time", "out_name": "bsi", "type": "real", "positive": "", @@ -185,12 +195,13 @@ "ok_max_mean_abs": "" }, "bsios": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_mole_concentration_of_particulate_matter_expressed_as_silicon_in_sea_water", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_particulate_organic_matter_expressed_as_silicon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Surface Mole Concentration of Particulate Organic Matter expressed as Silicon in sea water", + "long_name": "Surface Mole Concentration of Particulate Organic Matter Expressed as Silicon in Sea Water", "comment": "sum of particulate silica component concentrations", "dimensions": "longitude latitude time", "out_name": "bsios", @@ -202,14 +213,15 @@ "ok_max_mean_abs": "" }, "calc": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_calcite_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", + "cell_measures": "area: areacello volume: volcello", "long_name": "Calcite Concentration", "comment": "Sum of particulate calcite component concentrations (e.g. Phytoplankton, Detrital, etc.)", - "dimensions": "longitude latitude time depth0m", + "dimensions": "longitude latitude olevel time", "out_name": "calc", "type": "real", "positive": "", @@ -219,8 +231,9 @@ "ok_max_mean_abs": "" }, "calcos": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_mole_concentration_of_calcite_epressed_as_carbon_in_sea_water", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_calcite_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", @@ -236,13 +249,14 @@ "ok_max_mean_abs": "" }, "cfc11": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "mole_concentration_of_cfc11_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Moles Per Unit Mass of CFC-11 in sea water", - "comment": "", + "long_name": "Mole Concentration of CFC11 in Sea Water", + "comment": "Mole concentration means number of moles per unit volume, also called 'molarity', and is used in the construction 'mole_concentration_of_X_in_Y', where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula of CFC11 is CFCl3. The IUPAC name for CFC11 is trichloro-fluoro-methane.", "dimensions": "longitude latitude olevel time", "out_name": "cfc11", "type": "real", @@ -253,13 +267,14 @@ "ok_max_mean_abs": "" }, "cfc12": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "mole_concentration_of_cfc12_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Moles Per Unit Mass of CFC-12 in sea water", - "comment": "", + "long_name": "Mole Concentration of CFC12 in Sea Water", + "comment": "Mole concentration means number of moles per unit volume, also called 'molarity', and is used in the construction 'mole_concentration_of_X_in_Y', where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for CFC12 is CF2Cl2. The IUPAC name for CFC12 is dichloro-difluoro-methane.", "dimensions": "longitude latitude olevel time", "out_name": "cfc12", "type": "real", @@ -270,14 +285,15 @@ "ok_max_mean_abs": "" }, "chl": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "mass_concentration_of_phytoplankton_expressed_as_chlorophyll_in_sea_water", "units": "kg m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", - "long_name": "Mass Concentration of Total Chlorophyll in sea water", + "cell_measures": "area: areacello volume: volcello", + "long_name": "Mass Concentration of Total Phytoplankton Expressed as Chlorophyll in Sea Water", "comment": "Sum of chlorophyll from all phytoplankton group concentrations. In most models this is equal to chldiat+chlmisc, that is the sum of Diatom Chlorophyll Mass Concentration and Other Phytoplankton Chlorophyll Mass Concentration", - "dimensions": "longitude latitude time depth0m", + "dimensions": "longitude latitude olevel time", "out_name": "chl", "type": "real", "positive": "", @@ -287,14 +303,15 @@ "ok_max_mean_abs": "" }, "chlcalc": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "mass_concentration_of_calcareous_phytoplankton_expressed_as_chlorophyll_in_sea_water", "units": "kg m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", - "long_name": "Mass Concentration of Calcareous Phytoplankton expressed as Chlorophyll in sea water", + "cell_measures": "area: areacello volume: volcello", + "long_name": "Mass Concentration of Calcareous Phytoplankton Expressed as Chlorophyll in Sea Water", "comment": "chlorophyll concentration from the calcite-producing phytoplankton component alone", - "dimensions": "longitude latitude time depth0m", + "dimensions": "longitude latitude olevel time", "out_name": "chlcalc", "type": "real", "positive": "", @@ -304,12 +321,13 @@ "ok_max_mean_abs": "" }, "chlcalcos": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "mass_concentration_of_calcareous_phytoplankton_expressed_as_chlorophyll_in_sea_water", "units": "kg m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Surface Mass Concentration of Calcareous Phytoplankton expressed as Chlorophyll in sea water", + "long_name": "Surface Mass Concentration of Calcareous Phytoplankton Expressed as Chlorophyll in Sea Water", "comment": "chlorophyll concentration from the calcite-producing phytoplankton component alone", "dimensions": "longitude latitude time", "out_name": "chlcalcos", @@ -321,14 +339,15 @@ "ok_max_mean_abs": "" }, "chldiat": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "mass_concentration_of_diatoms_expressed_as_chlorophyll_in_sea_water", "units": "kg m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", - "long_name": "Mass Concentration of Diatom expressed as Chlorophyll in sea water", + "cell_measures": "area: areacello volume: volcello", + "long_name": "Mass Concentration of Diatoms Expressed as Chlorophyll in Sea Water", "comment": "Chlorophyll from diatom phytoplankton component concentration alone", - "dimensions": "longitude latitude time depth0m", + "dimensions": "longitude latitude olevel time", "out_name": "chldiat", "type": "real", "positive": "", @@ -338,12 +357,13 @@ "ok_max_mean_abs": "" }, "chldiatos": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "mass_concentration_of_diatoms_expressed_as_chlorophyll_in_sea_water", "units": "kg m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Surface Mass Concentration of Diatoms expressed as Chlorophyll in sea water", + "long_name": "Surface Mass Concentration of Diatoms Expressed as Chlorophyll in Sea Water", "comment": "chlorophyll from diatom phytoplankton component concentration alone", "dimensions": "longitude latitude time", "out_name": "chldiatos", @@ -355,14 +375,15 @@ "ok_max_mean_abs": "" }, "chldiaz": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "mass_concentration_of_diazotrophs_expressed_as_chlorophyll_in_sea_water", "units": "kg m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", - "long_name": "Mass Concentration of Diazotrophs expressed as Chlorophyll in sea water", + "cell_measures": "area: areacello volume: volcello", + "long_name": "Mass Concentration of Diazotrophs Expressed as Chlorophyll in Sea Water", "comment": "Chlorophyll concentration from the diazotrophic phytoplankton component alone", - "dimensions": "longitude latitude time depth0m", + "dimensions": "longitude latitude olevel time", "out_name": "chldiaz", "type": "real", "positive": "", @@ -372,12 +393,13 @@ "ok_max_mean_abs": "" }, "chldiazos": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "mass_concentration_of_diazotrophs_expressed_as_chlorophyll_in_sea_water", "units": "kg m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Surface Mass Concentration of Diazotrophs expressed as Chlorophyll in sea water", + "long_name": "Surface Mass Concentration of Diazotrophs Expressed as Chlorophyll in Sea Water", "comment": "chlorophyll concentration from the diazotrophic phytoplankton component alone", "dimensions": "longitude latitude time", "out_name": "chldiazos", @@ -389,14 +411,15 @@ "ok_max_mean_abs": "" }, "chlmisc": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "mass_concentration_of_miscellaneous_phytoplankton_expressed_as_chlorophyll_in_sea_water", "units": "kg m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", - "long_name": "Mass Concentration of Other Phytoplankton expressed as Chlorophyll in sea water", + "cell_measures": "area: areacello volume: volcello", + "long_name": "Mass Concentration of Other Phytoplankton Expressed as Chlorophyll in Sea Water", "comment": "Chlorophyll from additional phytoplankton component concentrations alone", - "dimensions": "longitude latitude time depth0m", + "dimensions": "longitude latitude olevel time", "out_name": "chlmisc", "type": "real", "positive": "", @@ -406,12 +429,13 @@ "ok_max_mean_abs": "" }, "chlmiscos": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "mass_concentration_of_miscellaneous_phytoplankton_expressed_as_chlorophyll_in_sea_water", "units": "kg m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Surface Mass Concentration of Other Phytoplankton expressed as Chlorophyll in sea water", + "long_name": "Surface Mass Concentration of Other Phytoplankton Expressed as Chlorophyll in Sea Water", "comment": "chlorophyll from additional phytoplankton component concentrations alone", "dimensions": "longitude latitude time", "out_name": "chlmiscos", @@ -423,12 +447,13 @@ "ok_max_mean_abs": "" }, "chlos": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "mass_concentration_of_phytoplankton_expressed_as_chlorophyll_in_sea_water", "units": "kg m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Surface Mass Concentration of Total Phytoplankton expressed as Chlorophyll in sea water", + "long_name": "Surface Mass Concentration of Total Phytoplankton Expressed as Chlorophyll in Sea Water", "comment": "Sum of chlorophyll from all phytoplankton group concentrations at the sea surface. In most models this is equal to chldiat+chlmisc, that is the sum of 'Diatom Chlorophyll Mass Concentration' plus 'Other Phytoplankton Chlorophyll Mass Concentration'", "dimensions": "longitude latitude time", "out_name": "chlos", @@ -440,14 +465,15 @@ "ok_max_mean_abs": "" }, "chlpico": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "mass_concentration_of_picophytoplankton_expressed_as_chlorophyll_in_sea_water", "units": "kg m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", - "long_name": "Mass Concentration of Picophytoplankton expressed as Chlorophyll in sea water", + "cell_measures": "area: areacello volume: volcello", + "long_name": "Mass Concentration of Picophytoplankton Expressed as Chlorophyll in Sea Water", "comment": "chlorophyll concentration from the picophytoplankton (<2 um) component alone", - "dimensions": "longitude latitude time depth0m", + "dimensions": "longitude latitude olevel time", "out_name": "chlpico", "type": "real", "positive": "", @@ -457,12 +483,13 @@ "ok_max_mean_abs": "" }, "chlpicoos": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "mass_concentration_of_picophytoplankton_expressed_as_chlorophyll_in_sea_water", "units": "kg m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Surface Mass Concentration of Picophytoplankton expressed as Chlorophyll in sea water", + "long_name": "Surface Mass Concentration of Picophytoplankton Expressed as Chlorophyll in Sea Water", "comment": "chlorophyll concentration from the picophytoplankton (<2 um) component alone", "dimensions": "longitude latitude time", "out_name": "chlpicoos", @@ -474,14 +501,15 @@ "ok_max_mean_abs": "" }, "co3": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_carbonate_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", - "long_name": "Carbonate ion Concentration", - "comment": "", - "dimensions": "longitude latitude time depth0m", + "cell_measures": "area: areacello volume: volcello", + "long_name": "Carbonate Ion Concentration", + "comment": "Mole concentration (number of moles per unit volume: molarity) of the carbonate anion (CO3).", + "dimensions": "longitude latitude olevel time", "out_name": "co3", "type": "real", "positive": "", @@ -491,14 +519,15 @@ "ok_max_mean_abs": "" }, "co3abio": { - "modeling_realm": "ocnBgChem", - "standard_name": "mole_concentration_of_carbonate_expressed_as_carbon_in_sea_water_due_to_abiotic_component", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_carbonate_abiotic_analogue_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", - "long_name": "Abiotic Carbonate ion Concentration", - "comment": "", - "dimensions": "longitude latitude time depth0m", + "cell_measures": "area: areacello volume: volcello", + "long_name": "Abiotic Carbonate Ion Concentration", + "comment": "Mole concentration (number of moles per unit volume: molarity) of the abiotic-analogue carbonate anion (CO3). An abiotic analogue is used to simulate the effect on a modelled variable when biological effects on ocean carbon concentration and alkalinity are ignored. ", + "dimensions": "longitude latitude olevel time", "out_name": "co3abio", "type": "real", "positive": "", @@ -508,13 +537,14 @@ "ok_max_mean_abs": "" }, "co3abioos": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_mole_concentration_of_carbonate_expressed_as_carbon_in_sea_water_due_to_abiotic_component", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_carbonate_abiotic_analogue_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Surface Abiotic Carbonate ion Concentration", - "comment": "", + "long_name": "Surface Abiotic Carbonate Ion Concentration", + "comment": "Near surface mole concentration (number of moles per unit volume: molarity) of the abiotic-analogue carbonate anion (CO3). An abiotic analogue is used to simulate the effect on a modelled variable when biological effects on ocean carbon concentration and alkalinity are ignored. ", "dimensions": "longitude latitude time", "out_name": "co3abioos", "type": "real", @@ -525,14 +555,15 @@ "ok_max_mean_abs": "" }, "co3nat": { - "modeling_realm": "ocnBgChem", - "standard_name": "mole_concentration_of_carbonate_expressed_as_carbon_in_sea_water_due_to_natural_component", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_carbonate_natural_analogue_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", - "long_name": "Natural Carbonate ion Concentration", - "comment": "", - "dimensions": "longitude latitude time depth0m", + "cell_measures": "area: areacello volume: volcello", + "long_name": "Natural Carbonate Ion Concentration", + "comment": "Surface mole concentration (number of moles per unit volume: molarity) of the natural-analogue carbonate anion (CO3). A natural analogue is used to simulate the effect on a modelled variable of imposing preindustrial atmospheric carbon dioxide concentrations, even when the model as a whole may be subjected to varying forcings. ", + "dimensions": "longitude latitude olevel time", "out_name": "co3nat", "type": "real", "positive": "", @@ -542,13 +573,14 @@ "ok_max_mean_abs": "" }, "co3natos": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_mole_concentration_of_carbonate_expressed_as_carbon_in_sea_water_due_to_natural_component", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_carbonate_natural_analogue_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Surface Natural Carbonate ion Concentration", - "comment": "", + "long_name": "Surface Natural Carbonate Ion Concentration", + "comment": "Near surface mole concentration (number of moles per unit volume: molarity) of the natural-analogue carbonate anion (CO3). A natural analogue is used to simulate the effect on a modelled variable of imposing preindustrial atmospheric carbon dioxide concentrations, even when the model as a whole may be subjected to varying forcings. ", "dimensions": "longitude latitude time", "out_name": "co3natos", "type": "real", @@ -559,13 +591,14 @@ "ok_max_mean_abs": "" }, "co3os": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_mole_concentration_of_carbonate_expressed_as_carbon_in_sea_water", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_carbonate_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Surface Carbonate ion Concentration", - "comment": "", + "long_name": "Surface Carbonate Ion Concentration", + "comment": "Near surface mole concentration (number of moles per unit volume: molarity) of the carbonate anion (CO3).", "dimensions": "longitude latitude time", "out_name": "co3os", "type": "real", @@ -576,14 +609,15 @@ "ok_max_mean_abs": "" }, "co3satarag": { - "modeling_realm": "ocnBgChem", - "standard_name": "mole_concentration_of_aragonite_expressed_as_carbon_in_sea_water_at_saturation", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_carbonate_expressed_as_carbon_at_equilibrium_with_pure_aragonite_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", - "long_name": "Carbonate ion Concentration for sea water in equilibrium with pure Aragonite", - "comment": "", - "dimensions": "longitude latitude time depth0m", + "cell_measures": "area: areacello volume: volcello", + "long_name": "Mole Concentration of Carbonate Ion in Equilibrium with Pure Aragonite in Sea Water", + "comment": "Mole concentration (number of moles per unit volume: molarity) of the carbonate anion (CO3) for sea water in equilibrium with pure Aragonite. Aragonite (CaCO3) is a mineral that is a polymorph of calcium carbonate.", + "dimensions": "longitude latitude olevel time", "out_name": "co3satarag", "type": "real", "positive": "", @@ -593,13 +627,14 @@ "ok_max_mean_abs": "" }, "co3sataragos": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_mole_concentration_of_carbonate_expressed_as_carbon_for_sea_water_in_equilibrium_with_pure_aragonite", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_carbonate_expressed_as_carbon_at_equilibrium_with_pure_aragonite_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Surface Mole Concentration of Carbonate Ion in Equilibrium with Pure Aragonite in sea water", - "comment": "", + "long_name": "Surface Mole Concentration of Carbonate Ion in Equilibrium with Pure Aragonite in Sea Water", + "comment": "Near surface mole concentration (number of moles per unit volume: molarity) of the carbonate anion (CO3) for sea water in equilibrium with pure Aragonite. Aragonite (CaCO3) is a mineral that is a polymorph of calcium carbonate.", "dimensions": "longitude latitude time", "out_name": "co3sataragos", "type": "real", @@ -610,14 +645,15 @@ "ok_max_mean_abs": "" }, "co3satcalc": { - "modeling_realm": "ocnBgChem", - "standard_name": "mole_concentration_of_calcite_expressed_as_carbon_in_sea_water_at_saturation", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_carbonate_expressed_as_carbon_at_equilibrium_with_pure_calcite_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", - "long_name": "Carbonate ion Concentration for sea water in equilibrium with pure Calcite", - "comment": "", - "dimensions": "longitude latitude time depth0m", + "cell_measures": "area: areacello volume: volcello", + "long_name": "Mole Concentration of Carbonate Ion in Equilibrium with Pure Calcite in Sea Water", + "comment": "Mole concentration (number of moles per unit volume: molarity) of the carbonate anion (CO3) for sea water in equilibrium with pure calcite. Aragonite (CaCO3) is a mineral that is a polymorph of calcium carbonate.", + "dimensions": "longitude latitude olevel time", "out_name": "co3satcalc", "type": "real", "positive": "", @@ -627,13 +663,14 @@ "ok_max_mean_abs": "" }, "co3satcalcos": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_mole_concentration_of_carbonate_expressed_as_carbon_for_sea_water_in_equilibrium_with_pure_calcite", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_carbonate_expressed_as_carbon_at_equilibrium_with_pure_calcite_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Surface Mole Concentration of Carbonate Ion in Equilibrium with Pure Calcite in sea water", - "comment": "", + "long_name": "Surface Mole Concentration of Carbonate Ion in Equilibrium with Pure Calcite in Sea Water", + "comment": "Near surface mole concentration (number of moles per unit volume: molarity) of the carbonate anion (CO3) for sea water in equilibrium with pure calcite. Aragonite (CaCO3) is a mineral that is a polymorph of calcium carbonate.", "dimensions": "longitude latitude time", "out_name": "co3satcalcos", "type": "real", @@ -644,14 +681,15 @@ "ok_max_mean_abs": "" }, "detoc": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_organic_detritus_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", + "cell_measures": "area: areacello volume: volcello", "long_name": "Detrital Organic Carbon Concentration", "comment": "Sum of detrital organic carbon component concentrations", - "dimensions": "longitude latitude time depth0m", + "dimensions": "longitude latitude olevel time", "out_name": "detoc", "type": "real", "positive": "", @@ -661,8 +699,9 @@ "ok_max_mean_abs": "" }, "detocos": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_mole_concentration_of_organic_detritus_expressed_as_carbon_in_sea_water", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_organic_detritus_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", @@ -678,14 +717,15 @@ "ok_max_mean_abs": "" }, "dfe": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_dissolved_iron_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", - "long_name": "Mole Concentration of Dissolved Iron in sea water", + "cell_measures": "area: areacello volume: volcello", + "long_name": "Dissolved Iron Concentration", "comment": "Dissolved iron in sea water, including both Fe2+ and Fe3+ ions (but not particulate detrital iron)", - "dimensions": "longitude latitude time depth0m", + "dimensions": "longitude latitude olevel time", "out_name": "dfe", "type": "real", "positive": "", @@ -695,8 +735,9 @@ "ok_max_mean_abs": "" }, "dfeos": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_mole_concentration_of_dissolved_iron_in_sea_water", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_dissolved_iron_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", @@ -712,14 +753,15 @@ "ok_max_mean_abs": "" }, "dissi13c": { - "modeling_realm": "ocnBgChem", - "standard_name": "mole_concentration_of_dissolved_inorganic_carbon13_in_sea_water", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_dissolved_inorganic_13C_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", - "long_name": "Dissolved Inorganic 13Carbon Concentration", - "comment": "Dissolved inorganic 14carbon (CO3+HCO3+H2CO3) concentration", - "dimensions": "longitude latitude time depth0m", + "cell_measures": "area: areacello volume: volcello", + "long_name": "Dissolved Inorganic Carbon-13 Concentration", + "comment": "Dissolved inorganic carbon-13 (CO3+HCO3+H2CO3) concentration", + "dimensions": "longitude latitude olevel time", "out_name": "dissi13c", "type": "real", "positive": "", @@ -729,13 +771,14 @@ "ok_max_mean_abs": "" }, "dissi13cos": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_mole_concentration_of_dissolved_inorganic_carbon13_in_sea_water", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_dissolved_inorganic_13C_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Surface Dissolved Inorganic 13Carbon Concentration", - "comment": "Dissolved inorganic 14carbon (CO3+HCO3+H2CO3) concentration", + "long_name": "Surface Dissolved Inorganic Carbon-13 Concentration", + "comment": "Near surface dissolved inorganic carbon-13 (CO3+HCO3+H2CO3) concentration", "dimensions": "longitude latitude time", "out_name": "dissi13cos", "type": "real", @@ -746,14 +789,15 @@ "ok_max_mean_abs": "" }, "dissi14cabio": { - "modeling_realm": "ocnBgChem", - "standard_name": "mole_concentration_of_dissolved_inorganic_carbon14_in_sea_water", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_dissolved_inorganic_14C_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", - "long_name": "Abiotic Dissolved Inorganic 14Carbon Concentration", - "comment": "Abiotic Dissolved inorganic 14carbon (CO3+HCO3+H2CO3) concentration", - "dimensions": "longitude latitude time depth0m", + "cell_measures": "area: areacello volume: volcello", + "long_name": "Abiotic Dissolved Inorganic Carbon-14 Concentration", + "comment": "Abiotic Dissolved inorganic carbon-14 (CO3+HCO3+H2CO3) concentration", + "dimensions": "longitude latitude olevel time", "out_name": "dissi14cabio", "type": "real", "positive": "", @@ -763,13 +807,14 @@ "ok_max_mean_abs": "" }, "dissi14cabioos": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_mole_concentration_of_dissolved_inorganic_carbon14_in_sea_water", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_dissolved_inorganic_14C_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Surface Abiotic Dissolved Inorganic 14Carbon Concentration", - "comment": "Abiotic Dissolved inorganic 14carbon (CO3+HCO3+H2CO3) concentration", + "long_name": "Surface Abiotic Dissolved Inorganic Carbon-14 Concentration", + "comment": "Abiotic Dissolved inorganic carbon-14 (CO3+HCO3+H2CO3) concentration", "dimensions": "longitude latitude time", "out_name": "dissi14cabioos", "type": "real", @@ -780,14 +825,15 @@ "ok_max_mean_abs": "" }, "dissic": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_dissolved_inorganic_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", + "cell_measures": "area: areacello volume: volcello", "long_name": "Dissolved Inorganic Carbon Concentration", "comment": "Dissolved inorganic carbon (CO3+HCO3+H2CO3) concentration", - "dimensions": "longitude latitude time depth0m", + "dimensions": "longitude latitude olevel time", "out_name": "dissic", "type": "real", "positive": "", @@ -797,14 +843,15 @@ "ok_max_mean_abs": "" }, "dissicabio": { - "modeling_realm": "ocnBgChem", - "standard_name": "mole_concentration_of_dissolved_inorganic_carbon_in_sea_water_abiotic_component", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_dissolved_inorganic_carbon_abiotic_analogue_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", + "cell_measures": "area: areacello volume: volcello", "long_name": "Abiotic Dissolved Inorganic Carbon Concentration", "comment": "Abiotic Dissolved inorganic carbon (CO3+HCO3+H2CO3) concentration", - "dimensions": "longitude latitude time depth0m", + "dimensions": "longitude latitude olevel time", "out_name": "dissicabio", "type": "real", "positive": "", @@ -814,8 +861,9 @@ "ok_max_mean_abs": "" }, "dissicabioos": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_mole_concentration_of_dissolved_inorganic_carbon_in_sea_water_due_to_abiotic_component", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_dissolved_inorganic_carbon_abiotic_analogue_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", @@ -831,14 +879,15 @@ "ok_max_mean_abs": "" }, "dissicnat": { - "modeling_realm": "ocnBgChem", - "standard_name": "mole_concentration_of_dissolved_inorganic_carbon_in_sea_water_natural_component", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_dissolved_inorganic_carbon_natural_analogue_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", + "cell_measures": "area: areacello volume: volcello", "long_name": "Natural Dissolved Inorganic Carbon Concentration", "comment": "Dissolved inorganic carbon (CO3+HCO3+H2CO3) concentration at preindustrial atmospheric xCO2", - "dimensions": "longitude latitude time depth0m", + "dimensions": "longitude latitude olevel time", "out_name": "dissicnat", "type": "real", "positive": "", @@ -848,8 +897,9 @@ "ok_max_mean_abs": "" }, "dissicnatos": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_mole_concentration_of_dissolved_inorganic_carbon_in_sea_water_due_to_natural_component", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_dissolved_inorganic_carbon_natural_analogue_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", @@ -865,8 +915,9 @@ "ok_max_mean_abs": "" }, "dissicos": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_mole_concentration_of_dissolved_inorganic_carbon_in_sea_water", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_dissolved_inorganic_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", @@ -882,14 +933,15 @@ "ok_max_mean_abs": "" }, "dissoc": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_dissolved_organic_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", + "cell_measures": "area: areacello volume: volcello", "long_name": "Dissolved Organic Carbon Concentration", "comment": "Sum of dissolved carbon component concentrations explicitly represented (i.e. not ~40 uM refractory unless explicit)", - "dimensions": "longitude latitude time depth0m", + "dimensions": "longitude latitude olevel time", "out_name": "dissoc", "type": "real", "positive": "", @@ -899,8 +951,9 @@ "ok_max_mean_abs": "" }, "dissocos": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_mole_concentration_of_dissolved_organic_carbon_in_sea_water", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_dissolved_organic_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", @@ -915,30 +968,14 @@ "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, - "dms": { - "modeling_realm": "ocnBgChem", - "standard_name": "mole_fraction_of_dimethyl_sulfide_in_air", - "units": "mol mol-1", - "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", - "long_name": "Mole Concentration of Dimethyl Sulphide in sea water", - "comment": "", - "dimensions": "longitude latitude time depth0m", - "out_name": "dms", - "type": "real", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, "dmso": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_dimethyl_sulfide_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Mole Concentration of Dimethyl Sulphide in sea water", + "long_name": "Mole Concentration of Dimethyl Sulphide in Sea Water", "comment": "Mole concentration of dimethyl sulphide in water", "dimensions": "longitude latitude olevel time", "out_name": "dmso", @@ -950,13 +987,14 @@ "ok_max_mean_abs": "" }, "dmsos": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_mole_concentration_of_dimethyl_sulfide_in_sea_water", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_dimethyl_sulfide_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Surface Mole Concentration of Dimethyl Sulphide in sea water", - "comment": "", + "long_name": "Surface Mole Concentration of Dimethyl Sulphide in Sea Water", + "comment": "Mole concentration of dimethyl sulphide in water in the near surface layer", "dimensions": "longitude latitude time", "out_name": "dmsos", "type": "real", @@ -967,13 +1005,14 @@ "ok_max_mean_abs": "" }, "dpco2": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "surface_carbon_dioxide_partial_pressure_difference_between_sea_water_and_air", "units": "Pa", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Delta PCO2", - "comment": "", + "long_name": "Delta CO2 Partial Pressure", + "comment": "Difference in partial pressure of carbon dioxide between sea water and air. The partial pressure of a dissolved gas in sea water is the partial pressure in air with which it would be in equilibrium. ", "dimensions": "longitude latitude time depth0m", "out_name": "dpco2", "type": "real", @@ -984,13 +1023,14 @@ "ok_max_mean_abs": "" }, "dpco2abio": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_carbon_dioxide_partial_pressure_difference_between_sea_water_and_air_due_to_abiotic_component", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "surface_carbon_dioxide_abiotic_analogue_partial_pressure_difference_between_sea_water_and_air", "units": "Pa", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Abiotic Delta PCO2", - "comment": "", + "long_name": "Abiotic Delta Pco Partial Pressure", + "comment": "Difference in partial pressure of abiotic-analogue carbon dioxide between sea water and air. The partial pressure of a dissolved gas in sea water is the partial pressure in air with which it would be in equilibrium. An abiotic analogue is used to simulate the effect on a modelled variable when biological effects on ocean carbon concentration and alkalinity are ignored.", "dimensions": "longitude latitude time depth0m", "out_name": "dpco2abio", "type": "real", @@ -1001,13 +1041,14 @@ "ok_max_mean_abs": "" }, "dpco2nat": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_carbon_dioxide_partial_pressure_difference_between_sea_water_and_air_due_to_natural_component", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "surface_carbon_dioxide_natural_analogue_partial_pressure_difference_between_sea_water_and_air", "units": "Pa", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Natural Delta PCO2", - "comment": "", + "long_name": "Natural Delta CO2 Partial Pressure ", + "comment": "Difference in partial pressure of natural-analogue carbon dioxide between sea water and air. The partial pressure of a dissolved gas in sea water is the partial pressure in air with which it would be in equilibrium. A natural analogue is used to simulate the effect on a modelled variable of imposing preindustrial atmospheric carbon dioxide concentrations, even when the model as a whole may be subjected to varying forcings. ", "dimensions": "longitude latitude time depth0m", "out_name": "dpco2nat", "type": "real", @@ -1018,13 +1059,14 @@ "ok_max_mean_abs": "" }, "dpo2": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "surface_molecular_oxygen_partial_pressure_difference_between_sea_water_and_air", "units": "Pa", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Delta PO2", - "comment": "", + "long_name": "Delta O2 Partial Pressure", + "comment": "The partial pressure of a dissolved gas in sea water is the partial pressure in air with which it would be in equilibrium. The partial pressure of a gaseous constituent of air is the pressure which it alone would exert with unchanged temperature and number of moles per unit volume. The surface called 'surface' means the lower boundary of the atmosphere.", "dimensions": "longitude latitude time depth0m", "out_name": "dpo2", "type": "real", @@ -1035,13 +1077,14 @@ "ok_max_mean_abs": "" }, "eparag100": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "sinking_mole_flux_of_aragonite_expressed_as_carbon_in_sea_water", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", "long_name": "Downward Flux of Aragonite", - "comment": "", + "comment": "The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. 'Sinking' is the gravitational settling of particulate matter suspended in a liquid. A sinking flux is positive downwards and is calculated relative to the movement of the surrounding fluid. Aragonite is a mineral that is a polymorph of calcium carbonate. The chemical formula of aragonite is CaCO3. Standard names also exist for calcite, another polymorph of calcium carbonate.", "dimensions": "longitude latitude time depth100m", "out_name": "eparag100", "type": "real", @@ -1052,13 +1095,14 @@ "ok_max_mean_abs": "" }, "epc100": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "sinking_mole_flux_of_particulate_organic_matter_expressed_as_carbon_in_sea_water", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Downward Flux of Particle Organic Carbon", - "comment": "", + "long_name": "Downward Flux of Particulate Organic Carbon", + "comment": "The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. 'Sinking' is the gravitational settling of particulate matter suspended in a liquid. A sinking flux is positive downwards and is calculated relative to the movement of the surrounding fluid.", "dimensions": "longitude latitude time depth100m", "out_name": "epc100", "type": "real", @@ -1069,13 +1113,14 @@ "ok_max_mean_abs": "" }, "epcalc100": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "sinking_mole_flux_of_calcite_expressed_as_carbon_in_sea_water", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", "long_name": "Downward Flux of Calcite", - "comment": "", + "comment": "The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. 'Sinking' is the gravitational settling of particulate matter suspended in a liquid. A sinking flux is positive downwards and is calculated relative to the movement of the surrounding fluid. Calcite is a mineral that is a polymorph of calcium carbonate. The chemical formula of calcite is CaCO3. Standard names also exist for aragonite, another polymorph of calcium carbonate.", "dimensions": "longitude latitude time depth100m", "out_name": "epcalc100", "type": "real", @@ -1086,13 +1131,14 @@ "ok_max_mean_abs": "" }, "epfe100": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "sinking_mole_flux_of_particulate_iron_in_sea_water", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", "long_name": "Downward Flux of Particulate Iron", - "comment": "", + "comment": "In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. 'Sinking' is the gravitational settling of particulate matter suspended in a liquid. A sinking flux is positive downwards and is calculated relative to the movement of the surrounding fluid.", "dimensions": "longitude latitude time depth100m", "out_name": "epfe100", "type": "real", @@ -1103,13 +1149,14 @@ "ok_max_mean_abs": "" }, "epn100": { - "modeling_realm": "ocnBgChem", - "standard_name": "sinking_mole_flux_of_particulate_nitrogen_in_sea_water", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "sinking_mole_flux_of_particulate_organic_nitrogen_in_sea_water", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", "long_name": "Downward Flux of Particulate Nitrogen", - "comment": "", + "comment": "In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. 'Sinking' is the gravitational settling of particulate matter suspended in a liquid. A sinking flux is positive downwards and is calculated relative to the movement of the surrounding fluid.", "dimensions": "longitude latitude time depth100m", "out_name": "epn100", "type": "real", @@ -1120,13 +1167,14 @@ "ok_max_mean_abs": "" }, "epp100": { - "modeling_realm": "ocnBgChem", - "standard_name": "sinking_mole_flux_of_particulate_phosphorus_in_sea_water", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "sinking_mole_flux_of_particulate_organic_phosphorus_in_sea_water", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", "long_name": "Downward Flux of Particulate Phosphorus", - "comment": "", + "comment": "In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. 'Sinking' is the gravitational settling of particulate matter suspended in a liquid. A sinking flux is positive downwards and is calculated relative to the movement of the surrounding fluid.", "dimensions": "longitude latitude time depth100m", "out_name": "epp100", "type": "real", @@ -1137,13 +1185,14 @@ "ok_max_mean_abs": "" }, "epsi100": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "sinking_mole_flux_of_particulate_silicon_in_sea_water", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Downward Flux of Particulate Silica", - "comment": "", + "long_name": "Downward Flux of Particulate Silicon", + "comment": "In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. 'Sinking' is the gravitational settling of particulate matter suspended in a liquid. A sinking flux is positive downwards and is calculated relative to the movement of the surrounding fluid.", "dimensions": "longitude latitude time depth100m", "out_name": "epsi100", "type": "real", @@ -1154,8 +1203,9 @@ "ok_max_mean_abs": "" }, "evs": { + "frequency": "mon", "modeling_realm": "ocean", - "standard_name": "water_evaporation_flux", + "standard_name": "water_evapotranspiration_flux", "units": "kg m-2 s-1", "cell_methods": "area: mean where ice_free_sea over sea time: mean", "cell_measures": "area: areacello", @@ -1171,12 +1221,13 @@ "ok_max_mean_abs": "" }, "expc": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "sinking_mole_flux_of_particulate_organic_matter_expressed_as_carbon_in_sea_water", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Sinking Particulate Organic Carbon Flux", + "long_name": "Downward Flux of Particulate Organic Carbon", "comment": "Downward flux of particulate organic carbon", "dimensions": "longitude latitude olevel time", "out_name": "expc", @@ -1188,12 +1239,13 @@ "ok_max_mean_abs": "" }, "fbddtalk": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "integral_wrt_depth_of_tendency_of_sea_water_alkalinity_expressed_as_mole_equivalent_due_to_biological_processes", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea depth: sum where sea (top 100m only) time: mean", "cell_measures": "area: areacello", - "long_name": "Rate of Change of Biological Alkalinity due to Biological Activity", + "long_name": "Rate of Change of Biological Alkalinity Due to Biological Activity", "comment": "vertical integral of net biological terms in time rate of change of alkalinity", "dimensions": "longitude latitude time olayer100m", "out_name": "fbddtalk", @@ -1205,12 +1257,13 @@ "ok_max_mean_abs": "" }, "fbddtdic": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_ocean_mole_content_of_dissolved_inorganic_carbon_due_to_biological_processes", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea depth: sum where sea (top 100m only) time: mean", "cell_measures": "area: areacello", - "long_name": "Rate of Change of Dissolved Inorganic Carbon due to Biological Activity", + "long_name": "Rate of Change of Dissolved Inorganic Carbon Due to Biological Activity", "comment": "vertical integral of net biological terms in time rate of change of dissolved inorganic carbon", "dimensions": "longitude latitude time olayer100m", "out_name": "fbddtdic", @@ -1222,12 +1275,13 @@ "ok_max_mean_abs": "" }, "fbddtdife": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_ocean_mole_content_of_dissolved_inorganic_iron_due_to_biological_processes", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea depth: sum where sea (top 100m only) time: mean", "cell_measures": "area: areacello", - "long_name": "Rate of Change of Dissolved Inorganic Iron due to Biological Activity", + "long_name": "Rate of Change of Dissolved Inorganic Iron Due to Biological Activity", "comment": "vertical integral of net biological terms in time rate of change of dissolved inorganic iron", "dimensions": "longitude latitude time olayer100m", "out_name": "fbddtdife", @@ -1239,12 +1293,13 @@ "ok_max_mean_abs": "" }, "fbddtdin": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_ocean_mole_content_of_dissolved_inorganic_nitrogen_due_to_biological_processes", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea depth: sum where sea (top 100m only) time: mean", "cell_measures": "area: areacello", - "long_name": "Rate of Change of Dissolved Inorganic Nitrogen due to Biological Activity", + "long_name": "Rate of Change of Dissolved Inorganic Nitrogen Due to Biological Activity", "comment": "vertical integral of net biological terms in time rate of change of nitrogen nutrients (e.g. NO3+NH4)", "dimensions": "longitude latitude time olayer100m", "out_name": "fbddtdin", @@ -1256,12 +1311,13 @@ "ok_max_mean_abs": "" }, "fbddtdip": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_ocean_mole_content_of_dissolved_inorganic_phosphorus_due_to_biological_processes", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea depth: sum where sea (top 100m only) time: mean", "cell_measures": "area: areacello", - "long_name": "Rate of Change of Dissolved Inorganic Phosphorus due to Biological Activity", + "long_name": "Rate of Change of Dissolved Inorganic Phosphorus Due to Biological Activity", "comment": "vertical integral of net biological terms in time rate of change of phosphate", "dimensions": "longitude latitude time olayer100m", "out_name": "fbddtdip", @@ -1273,12 +1329,13 @@ "ok_max_mean_abs": "" }, "fbddtdisi": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_ocean_mole_content_of_dissolved_inorganic_silicon_due_to_biological_processes", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea depth: sum where sea (top 100m only) time: mean", "cell_measures": "area: areacello", - "long_name": "Rate of Change of Dissolved Inorganic Silicon due to Biological Activity", + "long_name": "Rate of Change of Dissolved Inorganic Silicon Due to Biological Activity", "comment": "vertical integral of net biological terms in time rate of change of dissolved inorganic silicate", "dimensions": "longitude latitude time olayer100m", "out_name": "fbddtdisi", @@ -1290,7 +1347,8 @@ "ok_max_mean_abs": "" }, "fddtalk": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "integral_wrt_depth_of_tendency_of_sea_water_alkalinity_expressed_as_mole_equivalent", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea depth: sum where sea (top 100m only) time: mean", @@ -1307,13 +1365,14 @@ "ok_max_mean_abs": "" }, "fddtdic": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_ocean_mole_content_of_dissolved_inorganic_carbon", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea depth: sum where sea (top 100m only) time: mean", "cell_measures": "area: areacello", "long_name": "Rate of Change of Net Dissolved Inorganic Carbon", - "comment": "", + "comment": "'Content' indicates a quantity per unit area. 'tendency_of_X' means derivative of X with respect to time. 'Dissolved inorganic carbon' describes a family of chemical species in solution, including carbon dioxide, carbonic acid and the carbonate and bicarbonate anions. 'Dissolved inorganic carbon' is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute.", "dimensions": "longitude latitude time olayer100m", "out_name": "fddtdic", "type": "real", @@ -1324,7 +1383,8 @@ "ok_max_mean_abs": "" }, "fddtdife": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_ocean_mole_content_of_dissolved_inorganic_iron", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea depth: sum where sea (top 100m only) time: mean", @@ -1341,7 +1401,8 @@ "ok_max_mean_abs": "" }, "fddtdin": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_ocean_mole_content_of_dissolved_inorganic_nitrogen", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea depth: sum where sea (top 100m only) time: mean", @@ -1358,12 +1419,13 @@ "ok_max_mean_abs": "" }, "fddtdip": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_ocean_mole_content_of_dissolved_inorganic_phosphorus", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea depth: sum where sea (top 100m only) time: mean", "cell_measures": "area: areacello", - "long_name": "Rate of Change of Net Dissolved Inorganic Phosphate", + "long_name": "Rate of Change of Net Dissolved Inorganic Phosphorus", "comment": "vertical integral of net time rate of change of phosphate", "dimensions": "longitude latitude time olayer100m", "out_name": "fddtdip", @@ -1375,7 +1437,8 @@ "ok_max_mean_abs": "" }, "fddtdisi": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_ocean_mole_content_of_dissolved_inorganic_silicon", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea depth: sum where sea (top 100m only) time: mean", @@ -1392,13 +1455,14 @@ "ok_max_mean_abs": "" }, "fg13co2": { - "modeling_realm": "ocnBgChem", - "standard_name": "air_sea_flux_of_13CO2", - "units": "mol m-2 s-1", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "surface_downward_mass_flux_of_13C_dioxide_abiotic_analogue_expressed_as_13C", + "units": "kg m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Surface Downward Flux of Abiotic 13CO2", - "comment": "", + "long_name": "Surface Downward Flux of 13CO2", + "comment": "Gas exchange flux of carbon-13 as CO2 (positive into ocean)", "dimensions": "longitude latitude time depth0m", "out_name": "fg13co2", "type": "real", @@ -1409,8 +1473,9 @@ "ok_max_mean_abs": "" }, "fg14co2abio": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_downward_mass_flux_of_abiotic_14_carbon_dioxide_expressed_as_carbon", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "surface_downward_mass_flux_of_14C_dioxide_abiotic_analogue_expressed_as_carbon", "units": "kg m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", @@ -1426,12 +1491,13 @@ "ok_max_mean_abs": "" }, "fgcfc11": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "surface_downward_mole_flux_of_cfc11", - "units": "mol sec-1 m-2", + "units": "mol m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Surface Downward CFC11 flux", + "long_name": "Surface Downward CFC11 Flux", "comment": "gas exchange flux of CFC11", "dimensions": "longitude latitude time", "out_name": "fgcfc11", @@ -1443,12 +1509,13 @@ "ok_max_mean_abs": "" }, "fgcfc12": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "surface_downward_mole_flux_of_cfc12", - "units": "mol sec-1 m-2", + "units": "mol m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Surface Downward CFC12 flux", + "long_name": "Surface Downward CFC12 Flux", "comment": "gas exchange flux of CFC12", "dimensions": "longitude latitude time", "out_name": "fgcfc12", @@ -1460,7 +1527,8 @@ "ok_max_mean_abs": "" }, "fgco2": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "surface_downward_mass_flux_of_carbon_dioxide_expressed_as_carbon", "units": "kg m-2 s-1", "cell_methods": "area: mean where sea time: mean", @@ -1477,8 +1545,9 @@ "ok_max_mean_abs": "" }, "fgco2abio": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_downward_mass_flux_of_abiotic_carbon_dioxide_expressed_as_carbon", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "surface_downward_mass_flux_of_carbon_dioxide_abiotic_analogue_expressed_as_carbon", "units": "kg m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", @@ -1494,8 +1563,9 @@ "ok_max_mean_abs": "" }, "fgco2nat": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_downward_mass_flux_of_natural_carbon_dioxide_expressed_as_carbon", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "surface_downward_mass_flux_of_carbon_dioxide_natural_analogue_expressed_as_carbon", "units": "kg m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", @@ -1511,7 +1581,8 @@ "ok_max_mean_abs": "" }, "fgdms": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "surface_upward_mole_flux_of_dimethyl_sulfide", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea time: mean", @@ -1521,14 +1592,15 @@ "dimensions": "longitude latitude time depth0m", "out_name": "fgdms", "type": "real", - "positive": "", + "positive": "up", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "fgo2": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "surface_downward_mole_flux_of_molecular_oxygen", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea time: mean", @@ -1538,19 +1610,20 @@ "dimensions": "longitude latitude time depth0m", "out_name": "fgo2", "type": "real", - "positive": "", + "positive": "down", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "fgsf6": { + "frequency": "mon", "modeling_realm": "ocean", - "standard_name": "surface_downward_mole_flux_of_sf6", - "units": "mol sec-1 m-2", + "standard_name": "surface_downward_mole_flux_of_sulfur_hexafluoride", + "units": "mol m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Surface Downward SF6 flux", + "long_name": "Surface Downward SF6 Flux", "comment": "gas exchange flux of SF6", "dimensions": "longitude latitude time", "out_name": "fgsf6", @@ -1562,12 +1635,13 @@ "ok_max_mean_abs": "" }, "ficeberg": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "water_flux_into_sea_water_from_icebergs", "units": "kg m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Water Flux into Sea Water From Icebergs", + "long_name": "Water Flux into Sea Water from Icebergs", "comment": "computed as the iceberg melt water flux into the ocean divided by the area of the ocean portion of the grid cell.", "dimensions": "longitude latitude olevel time", "out_name": "ficeberg", @@ -1579,12 +1653,13 @@ "ok_max_mean_abs": "" }, "ficeberg2d": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "water_flux_into_sea_water_from_icebergs", "units": "kg m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Water Flux into Sea Water From Icebergs", + "long_name": "Water Flux into Sea Water from Icebergs", "comment": "computed as the iceberg melt water flux into the ocean divided by the area of the ocean portion of the grid cell.", "dimensions": "longitude latitude time", "out_name": "ficeberg", @@ -1596,13 +1671,14 @@ "ok_max_mean_abs": "" }, "frfe": { - "modeling_realm": "ocnBgChem", - "standard_name": "tendency_of_ocean_mole_content_of_iron_due_to_sedimentation", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "minus_tendency_of_ocean_mole_content_of_iron_due_to_sedimentation", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", "long_name": "Iron Loss to Sediments", - "comment": "", + "comment": "'Content' indicates a quantity per unit area. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. 'tendency_of_X' means derivative of X with respect to time.", "dimensions": "longitude latitude time", "out_name": "frfe", "type": "real", @@ -1613,8 +1689,9 @@ "ok_max_mean_abs": "" }, "fric": { - "modeling_realm": "ocnBgChem", - "standard_name": "tendency_of_ocean_mole_content_of_inorganic_carbon_due_to_sedimentation", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "minus_tendency_of_ocean_mole_content_of_inorganic_carbon_due_to_sedimentation", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", @@ -1630,12 +1707,13 @@ "ok_max_mean_abs": "" }, "friver": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "water_flux_into_sea_water_from_rivers", "units": "kg m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Water Flux into Sea Water From Rivers", + "long_name": "Water Flux into Sea Water from Rivers", "comment": "computed as the river flux of water into the ocean divided by the area of the ocean portion of the grid cell.", "dimensions": "longitude latitude time", "out_name": "friver", @@ -1647,13 +1725,14 @@ "ok_max_mean_abs": "" }, "frn": { - "modeling_realm": "ocnBgChem", - "standard_name": "tendency_of_ocean_mole_content_of_elemental_nitrogen_due_to_denitrification_and_sedimentation", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "minus_tendency_of_ocean_mole_content_of_elemental_nitrogen_due_to_denitrification_and_sedimentation", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Nitrogen Loss to Sediments and through Denitrification", - "comment": "", + "long_name": "Nitrogen Loss to Sediments and Through Denitrification", + "comment": "'Content' indicates a quantity per unit area. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. 'Denitrification' is the conversion of nitrate into gaseous compounds such as nitric oxide, nitrous oxide and molecular nitrogen which are then emitted to the atmosphere. 'Sedimentation' is the sinking of particulate matter to the floor of a body of water. 'tendency_of_X' means derivative of X with respect to time.", "dimensions": "longitude latitude time", "out_name": "frn", "type": "real", @@ -1664,8 +1743,9 @@ "ok_max_mean_abs": "" }, "froc": { - "modeling_realm": "ocnBgChem", - "standard_name": "tendency_of_ocean_mole_content_of_organic_carbon_due_to_sedimentation", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "minus_tendency_of_ocean_mole_content_of_organic_carbon_due_to_sedimentation", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", @@ -1681,7 +1761,8 @@ "ok_max_mean_abs": "" }, "fsfe": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_ocean_mole_content_of_iron_due_to_deposition_and_runoff_and_sediment_dissolution", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea time: mean", @@ -1698,12 +1779,13 @@ "ok_max_mean_abs": "" }, "fsitherm": { + "frequency": "mon", "modeling_realm": "ocean seaIce", "standard_name": "water_flux_into_sea_water_due_to_sea_ice_thermodynamics", "units": "kg m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Water Flux into Sea Water due to Sea Ice Thermodynamics", + "long_name": "Water Flux into Sea Water Due to Sea Ice Thermodynamics", "comment": "computed as the sea ice thermodynamic water flux into the ocean divided by the area of the ocean portion of the grid cell.", "dimensions": "longitude latitude time", "out_name": "fsitherm", @@ -1715,13 +1797,14 @@ "ok_max_mean_abs": "" }, "fsn": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_ocean_mole_content_of_elemental_nitrogen_due_to_deposition_and_fixation_and_runoff", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", "long_name": "Surface Downward Net Flux of Nitrogen", - "comment": "", + "comment": "Flux of nitrogen into the ocean due to deposition (sum of dry and wet deposition), fixation (the production of ammonia from nitrogen gas by diazotrophs) and runoff (liquid water which drains from land).", "dimensions": "longitude latitude time depth0m", "out_name": "fsn", "type": "real", @@ -1732,13 +1815,14 @@ "ok_max_mean_abs": "" }, "graz": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_grazing_of_phytoplankton", "units": "mol m-3 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", "long_name": "Total Grazing of Phytoplankton by Zooplankton", - "comment": "", + "comment": "Total grazing of phytoplankton by zooplankton defined as tendency of moles of carbon per cubic metre.", "dimensions": "longitude latitude olevel time", "out_name": "graz", "type": "real", @@ -1749,11 +1833,12 @@ "ok_max_mean_abs": "" }, "hfbasin": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "northward_ocean_heat_transport", "units": "W", - "cell_methods": "longitude: mean (basin) time: mean", - "cell_measures": "area: areacella", + "cell_methods": "longitude: sum (comment: basin sum [along zig-zag grid path]) depth: sum time: mean", + "cell_measures": "", "long_name": "Northward Ocean Heat Transport", "comment": "Contains contributions from all physical processes affecting the northward heat transport, including resolved advection, parameterized advection, lateral diffusion, etc. Diagnosed here as a function of latitude and basin. Use Celsius for temperature scale.", "dimensions": "latitude basin time", @@ -1766,12 +1851,13 @@ "ok_max_mean_abs": "" }, "hfbasinpadv": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "northward_ocean_heat_transport_due_to_parameterized_eddy_advection", "units": "W", - "cell_methods": "longitude: mean (basin) time: mean", - "cell_measures": "area: areacella", - "long_name": "northward ocean heat transport due to parameterized eddy advection", + "cell_methods": "longitude: sum (comment: basin sum [along zig-zag grid path]) depth: sum time: mean", + "cell_measures": "", + "long_name": "Northward Ocean Heat Transport Due to Parameterized Eddy Advection", "comment": "Contributions to heat transport from parameterized eddy-induced advective transport due to any subgrid advective process. Diagnosed here as a function of latitude and basin. Use Celsius for temperature scale.", "dimensions": "latitude basin time", "out_name": "hfbasinpadv", @@ -1783,12 +1869,13 @@ "ok_max_mean_abs": "" }, "hfbasinpmadv": { + "frequency": "mon", "modeling_realm": "ocean", - "standard_name": "northward_ocean_heat_transport_due_to_parameterized_mesoscale_advection", + "standard_name": "northward_ocean_heat_transport_due_to_parameterized_mesoscale_eddy_advection", "units": "W", - "cell_methods": "longitude: mean (basin) time: mean", - "cell_measures": "area: areacella", - "long_name": "northward ocean heat transport due to parameterized mesoscale advection", + "cell_methods": "longitude: sum (comment: basin sum [along zig-zag grid path]) depth: sum time: mean", + "cell_measures": "", + "long_name": "Northward Ocean Heat Transport Due to Parameterized Mesoscale Advection", "comment": "Contributions to heat transport from parameterized mesoscale eddy-induced advective transport. Diagnosed here as a function of latitude and basin. Use Celsius for temperature scale.", "dimensions": "latitude basin time", "out_name": "hfbasinpmadv", @@ -1800,12 +1887,13 @@ "ok_max_mean_abs": "" }, "hfbasinpmdiff": { + "frequency": "mon", "modeling_realm": "ocean", - "standard_name": "northward_ocean_heat_transport_due_to_parameterized_mesoscale_diffusion", + "standard_name": "northward_ocean_heat_transport_due_to_parameterized_mesoscale_eddy_diffusion", "units": "W", - "cell_methods": "longitude: mean (basin) time: mean", - "cell_measures": "area: areacella", - "long_name": "northward ocean heat transport due to parameterized mesoscale diffusion", + "cell_methods": "longitude: sum (comment: basin sum [along zig-zag grid path]) depth: sum time: mean", + "cell_measures": "", + "long_name": "Northward Ocean Heat Transport Due to Parameterized Mesoscale Diffusion", "comment": "Contributions to heat transport from parameterized mesoscale eddy-induced diffusive transport (i.e., neutral diffusion). Diagnosed here as a function of latitude and basin.", "dimensions": "latitude basin time", "out_name": "hfbasinpmdiff", @@ -1817,12 +1905,13 @@ "ok_max_mean_abs": "" }, "hfbasinpsmadv": { + "frequency": "mon", "modeling_realm": "ocean", - "standard_name": "northward_ocean_heat_transport_due_to_parameterized_submesoscale_advection", + "standard_name": "northward_ocean_heat_transport_due_to_parameterized_submesoscale_eddy_advection", "units": "W", - "cell_methods": "longitude: mean (basin) time: mean", - "cell_measures": "area: areacella", - "long_name": "northward ocean heat transport due to parameterized submesoscale advection", + "cell_methods": "longitude: sum (comment: basin sum [along zig-zag grid path]) depth: sum time: mean", + "cell_measures": "", + "long_name": "Northward Ocean Heat Transport Due to Parameterized Submesoscale Advection", "comment": "Contributions to heat transport from parameterized mesoscale eddy-induced advective transport. Diagnosed here as a function of latitude and basin. Use Celsius for temperature scale.", "dimensions": "latitude basin time", "out_name": "hfbasinpsmadv", @@ -1834,13 +1923,14 @@ "ok_max_mean_abs": "" }, "hfcorr": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "heat_flux_correction", "units": "W m-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", "long_name": "Heat Flux Correction", - "comment": "", + "comment": "Flux correction is also called 'flux adjustment'. A positive flux correction is downward i.e. added to the ocean. In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions": "longitude latitude time", "out_name": "hfcorr", "type": "real", @@ -1851,6 +1941,7 @@ "ok_max_mean_abs": "" }, "hfds": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "surface_downward_heat_flux_in_sea_water", "units": "W m-2", @@ -1868,12 +1959,13 @@ "ok_max_mean_abs": "" }, "hfevapds": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "temperature_flux_due_to_evaporation_expressed_as_heat_flux_out_of_sea_water", "units": "W m-2", "cell_methods": "area: mean where ice_free_sea over sea time: mean", "cell_measures": "area: areacello", - "long_name": "Temperature Flux due to Evaporation Expressed as Heat Flux Out of Sea Water", + "long_name": "Temperature Flux Due to Evaporation Expressed as Heat Flux out of Sea Water", "comment": "This is defined as 'where ice_free_sea over sea'", "dimensions": "longitude latitude time", "out_name": "hfevapds", @@ -1885,13 +1977,14 @@ "ok_max_mean_abs": "" }, "hfgeou": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "upward_geothermal_heat_flux_at_sea_floor", "units": "W m-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", "long_name": "Upward Geothermal Heat Flux at Sea Floor", - "comment": "", + "comment": "Upward geothermal heat flux per unit area on the sea floor", "dimensions": "longitude latitude time", "out_name": "hfgeou", "type": "real", @@ -1902,13 +1995,14 @@ "ok_max_mean_abs": "" }, "hfibthermds": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "heat_flux_into_sea_water_due_to_iceberg_thermodynamics", "units": "W m-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Heat Flux into Sea Water due to Iceberg Thermodynamics", - "comment": "", + "long_name": "Heat Flux into Sea Water Due to Iceberg Thermodynamics", + "comment": "In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. ' Iceberg thermodynamics' refers to the addition or subtraction of mass due to surface and basal fluxes, i.e., due to melting, sublimation and fusion.", "dimensions": "longitude latitude olevel time", "out_name": "hfibthermds", "type": "real", @@ -1919,13 +2013,14 @@ "ok_max_mean_abs": "" }, "hfibthermds2d": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "heat_flux_into_sea_water_due_to_iceberg_thermodynamics", "units": "W m-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Heat Flux into Sea Water due to Iceberg Thermodynamics", - "comment": "", + "long_name": "Heat Flux into Sea Water Due to Iceberg Thermodynamics", + "comment": "In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. ' Iceberg thermodynamics' refers to the addition or subtraction of mass due to surface and basal fluxes, i.e., due to melting, sublimation and fusion.", "dimensions": "longitude latitude time", "out_name": "hfibthermds", "type": "real", @@ -1936,6 +2031,7 @@ "ok_max_mean_abs": "" }, "hflso": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "surface_downward_latent_heat_flux", "units": "W m-2", @@ -1946,19 +2042,20 @@ "dimensions": "longitude latitude time", "out_name": "hflso", "type": "real", - "positive": "down", + "positive": "up", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "hfrainds": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "temperature_flux_due_to_rainfall_expressed_as_heat_flux_into_sea_water", "units": "W m-2", "cell_methods": "area: mean where ice_free_sea over sea time: mean", "cell_measures": "area: areacello", - "long_name": "Temperature Flux due to Rainfall Expressed as Heat Flux into Sea Water", + "long_name": "Temperature Flux Due to Rainfall Expressed as Heat Flux into Sea Water", "comment": "This is defined as 'where ice_free_sea over sea'; i.e., the total flux (considered here) entering the ice-free portion of the grid cell divided by the area of the ocean portion of the grid cell. All such heat fluxes are computed based on Celsius scale.", "dimensions": "longitude latitude time", "out_name": "hfrainds", @@ -1970,13 +2067,14 @@ "ok_max_mean_abs": "" }, "hfrunoffds": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "temperature_flux_due_to_runoff_expressed_as_heat_flux_into_sea_water", "units": "W m-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Temperature Flux due to Runoff Expressed as Heat Flux into Sea Water", - "comment": "", + "long_name": "Temperature Flux Due to Runoff Expressed as Heat Flux into Sea Water", + "comment": "Heat flux associated with liquid water which drains from land. It is calculated relative to the heat that would be transported by runoff water entering the sea at zero degrees Celsius. ", "dimensions": "longitude latitude olevel time", "out_name": "hfrunoffds", "type": "real", @@ -1987,13 +2085,14 @@ "ok_max_mean_abs": "" }, "hfrunoffds2d": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "temperature_flux_due_to_runoff_expressed_as_heat_flux_into_sea_water", "units": "W m-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Temperature Flux due to Runoff Expressed as Heat Flux into Sea Water", - "comment": "", + "long_name": "Temperature Flux Due to Runoff Expressed as Heat Flux into Sea Water", + "comment": "Heat flux associated with liquid water which drains from land. It is calculated relative to the heat that would be transported by runoff water entering the sea at zero degrees Celsius. ", "dimensions": "longitude latitude time", "out_name": "hfrunoffds", "type": "real", @@ -2004,13 +2103,14 @@ "ok_max_mean_abs": "" }, "hfsifrazil": { + "frequency": "mon", "modeling_realm": "ocean seaIce", "standard_name": "heat_flux_into_sea_water_due_to_freezing_of_frazil_ice", "units": "W m-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Heat Flux into Sea Water due to Frazil Ice Formation", - "comment": "", + "long_name": "Heat Flux into Sea Water Due to Frazil Ice Formation", + "comment": "In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. 'Frazil' consists of needle like crystals of ice, typically between three and four millimeters in diameter, which form as sea water begins to freeze. Salt is expelled during the freezing process and frazil ice consists of nearly pure fresh water.", "dimensions": "longitude latitude olevel time", "out_name": "hfsifrazil", "type": "real", @@ -2021,13 +2121,14 @@ "ok_max_mean_abs": "" }, "hfsifrazil2d": { + "frequency": "mon", "modeling_realm": "ocean seaIce", "standard_name": "heat_flux_into_sea_water_due_to_freezing_of_frazil_ice", "units": "W m-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Heat Flux into Sea Water due to Frazil Ice Formation", - "comment": "", + "long_name": "Heat Flux into Sea Water Due to Frazil Ice Formation", + "comment": "In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. 'Frazil' consists of needle like crystals of ice, typically between three and four millimeters in diameter, which form as sea water begins to freeze. Salt is expelled during the freezing process and frazil ice consists of nearly pure fresh water.", "dimensions": "longitude latitude time", "out_name": "hfsifrazil", "type": "real", @@ -2038,13 +2139,14 @@ "ok_max_mean_abs": "" }, "hfsnthermds": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "heat_flux_into_sea_water_due_to_snow_thermodynamics", "units": "W m-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Heat Flux into Sea Water due to Snow Thermodynamics", - "comment": "", + "long_name": "Heat Flux into Sea Water Due to Snow Thermodynamics", + "comment": "In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. 'Snow thermodynamics' refers to the addition or subtraction of mass due to surface and basal fluxes, i.e., due to melting, sublimation and fusion.", "dimensions": "longitude latitude olevel time", "out_name": "hfsnthermds", "type": "real", @@ -2055,13 +2157,14 @@ "ok_max_mean_abs": "" }, "hfsnthermds2d": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "heat_flux_into_sea_water_due_to_snow_thermodynamics", "units": "W m-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Heat Flux into Sea Water due to Snow Thermodynamics", - "comment": "", + "long_name": "Heat Flux into Sea Water Due to Snow Thermodynamics", + "comment": "In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. 'Snow thermodynamics' refers to the addition or subtraction of mass due to surface and basal fluxes, i.e., due to melting, sublimation and fusion.", "dimensions": "longitude latitude time", "out_name": "hfsnthermds", "type": "real", @@ -2072,31 +2175,33 @@ "ok_max_mean_abs": "" }, "hfsso": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "surface_downward_sensible_heat_flux", "units": "W m-2", "cell_methods": "area: mean where ice_free_sea over sea time: mean", "cell_measures": "area: areacello", "long_name": "Surface Downward Sensible Heat Flux", - "comment": "This is defined as 'where ice_free_sea over sea'", + "comment": "Upward sensible heat flux over sea ice free sea. The surface sensible heat flux, also called turbulent heat flux, is the exchange of heat between the surface and the air by motion of air.", "dimensions": "longitude latitude time", "out_name": "hfsso", "type": "real", - "positive": "down", + "positive": "up", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "hfx": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "ocean_heat_x_transport", "units": "W", - "cell_methods": "time: mean", - "cell_measures": "--OPT", + "cell_methods": "area: mean where sea time: mean", + "cell_measures": "area: areacello", "long_name": "Ocean Heat X Transport", "comment": "Contains all contributions to 'x-ward' heat transport from resolved and parameterized processes. Use Celsius for temperature scale.", - "dimensions": "longitude latitude olevel time", + "dimensions": "longitude latitude time", "out_name": "hfx", "type": "real", "positive": "", @@ -2106,14 +2211,15 @@ "ok_max_mean_abs": "" }, "hfy": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "ocean_heat_y_transport", "units": "W", - "cell_methods": "time: mean", - "cell_measures": "--OPT", + "cell_methods": "area: mean where sea time: mean", + "cell_measures": "area: areacello", "long_name": "Ocean Heat Y Transport", "comment": "Contains all contributions to 'y-ward' heat transport from resolved and parameterized processes. Use Celsius for temperature scale.", - "dimensions": "longitude latitude olevel time", + "dimensions": "longitude latitude time", "out_name": "hfy", "type": "real", "positive": "", @@ -2123,12 +2229,13 @@ "ok_max_mean_abs": "" }, "htovgyre": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "northward_ocean_heat_transport_due_to_gyre", "units": "W", - "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", - "long_name": "Northward Ocean Heat Transport due to Gyre", + "cell_methods": "longitude: sum (comment: basin sum [along zig-zag grid path]) depth: sum time: mean", + "cell_measures": "", + "long_name": "Northward Ocean Heat Transport Due to Gyre", "comment": "From all advective mass transport processes, resolved and parameterized.", "dimensions": "latitude basin time", "out_name": "htovgyre", @@ -2140,12 +2247,13 @@ "ok_max_mean_abs": "" }, "htovovrt": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "northward_ocean_heat_transport_due_to_overturning", "units": "W", - "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", - "long_name": "Northward Ocean Heat Transport due to Overturning", + "cell_methods": "longitude: sum (comment: basin sum [along zig-zag grid path]) depth: sum time: mean", + "cell_measures": "", + "long_name": "Northward Ocean Heat Transport Due to Overturning", "comment": "From all advective mass transport processes, resolved and parameterized.", "dimensions": "latitude basin time", "out_name": "htovovrt", @@ -2157,12 +2265,13 @@ "ok_max_mean_abs": "" }, "icfriver": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_ocean_mole_content_of_inorganic_carbon_due_to_runoff_and_sediment_dissolution", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Flux of Inorganic Carbon Into Ocean Surface by Runoff", + "long_name": "Flux of Inorganic Carbon into Ocean Surface by Runoff", "comment": "Inorganic Carbon supply to ocean through runoff (separate from gas exchange)", "dimensions": "longitude latitude time depth0m", "out_name": "icfriver", @@ -2174,7 +2283,8 @@ "ok_max_mean_abs": "" }, "intdic": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "ocean_mass_content_of_dissolved_inorganic_carbon", "units": "kg m-2", "cell_methods": "area: mean where sea depth: sum where sea time: mean", @@ -2191,7 +2301,8 @@ "ok_max_mean_abs": "" }, "intdoc": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "ocean_mass_content_of_dissolved_organic_carbon", "units": "kg m-2", "cell_methods": "area: mean where sea depth: sum where sea time: mean", @@ -2208,7 +2319,8 @@ "ok_max_mean_abs": "" }, "intparag": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_ocean_mole_content_of_aragonite_expressed_as_carbon_due_to_biological_production", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea depth: sum where sea time: mean", @@ -2225,7 +2337,8 @@ "ok_max_mean_abs": "" }, "intpbfe": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_ocean_mole_content_of_iron_due_to_biological_production", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea depth: sum where sea time: mean", @@ -2242,7 +2355,8 @@ "ok_max_mean_abs": "" }, "intpbn": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_ocean_mole_content_of_nitrogen_due_to_biological_production", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea depth: sum where sea time: mean", @@ -2259,7 +2373,8 @@ "ok_max_mean_abs": "" }, "intpbp": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_ocean_mole_content_of_phosphorus_due_to_biological_production", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea depth: sum where sea time: mean", @@ -2276,12 +2391,13 @@ "ok_max_mean_abs": "" }, "intpbsi": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_ocean_mole_content_of_silicon_due_to_biological_production", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea depth: sum where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Silica Production", + "long_name": "Silicon Production", "comment": "Vertically integrated biogenic silica production", "dimensions": "longitude latitude time", "out_name": "intpbsi", @@ -2293,7 +2409,8 @@ "ok_max_mean_abs": "" }, "intpcalcite": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_ocean_mole_content_of_calcite_expressed_as_carbon_due_to_biological_production", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea depth: sum where sea time: mean", @@ -2310,7 +2427,8 @@ "ok_max_mean_abs": "" }, "intpn2": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_ocean_mole_content_of_elemental_nitrogen_due_to_fixation", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea depth: sum where sea time: mean", @@ -2327,7 +2445,8 @@ "ok_max_mean_abs": "" }, "intpoc": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "ocean_mass_content_of_particulate_organic_matter_expressed_as_carbon", "units": "kg m-2", "cell_methods": "area: mean where sea depth: sum where sea time: mean", @@ -2344,7 +2463,8 @@ "ok_max_mean_abs": "" }, "intpp": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_phytoplankton", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea depth: sum where sea time: mean", @@ -2361,13 +2481,14 @@ "ok_max_mean_abs": "" }, "intppcalc": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_calcareous_phytoplankton", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea depth: sum where sea time: mean", "cell_measures": "area: areacello", "long_name": "Net Primary Mole Productivity of Carbon by Calcareous Phytoplankton", - "comment": "", + "comment": "Vertically integrated primary (organic carbon) production by the calcareous phytoplankton component alone", "dimensions": "longitude latitude time", "out_name": "intppcalc", "type": "real", @@ -2378,7 +2499,8 @@ "ok_max_mean_abs": "" }, "intppdiat": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_diatoms", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea depth: sum where sea time: mean", @@ -2395,13 +2517,14 @@ "ok_max_mean_abs": "" }, "intppdiaz": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_diazotrophs", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea depth: sum where sea time: mean", "cell_measures": "area: areacello", "long_name": "Net Primary Mole Productivity of Carbon by Diazotrophs", - "comment": "", + "comment": "Vertically integrated primary (organic carbon) production by the diazotrophs alone", "dimensions": "longitude latitude time", "out_name": "intppdiaz", "type": "real", @@ -2412,7 +2535,8 @@ "ok_max_mean_abs": "" }, "intppmisc": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_miscellaneous_phytoplankton", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea depth: sum where sea time: mean", @@ -2429,7 +2553,8 @@ "ok_max_mean_abs": "" }, "intppnitrate": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "net_primary_mole_productivity_of_biomass_expressed_as_carbon_due_to_nitrate_utilization", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea depth: sum where sea time: mean", @@ -2446,13 +2571,14 @@ "ok_max_mean_abs": "" }, "intpppico": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "net_primary_mole_productivity_of_biomass_expressed_as_carbon_by_picophytoplankton", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea depth: sum where sea time: mean", "cell_measures": "area: areacello", "long_name": "Net Primary Mole Productivity of Carbon by Picophytoplankton", - "comment": "", + "comment": "Vertically integrated primary (organic carbon) production by the picophytoplankton component alone", "dimensions": "longitude latitude time", "out_name": "intpppico", "type": "real", @@ -2463,13 +2589,14 @@ "ok_max_mean_abs": "" }, "limfecalc": { - "modeling_realm": "ocnBgChem", - "standard_name": "iron_limitation_of_calcareous_phytoplankton", - "units": "1.0", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "iron_growth_limitation_of_calcareous_phytoplankton", + "units": "1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Iron limitation of Calcareous Phytoplankton", - "comment": "", + "long_name": "Iron Limitation of Calcareous Phytoplankton", + "comment": "'Calcareous phytoplankton' are phytoplankton that produce calcite. Calcite is a mineral that is a polymorph of calcium carbonate. The chemical formula of calcite is CaCO3. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. 'Iron growth limitation' means the ratio of the growth rate of a species population in the environment (where there is a finite availability of iron) to the theoretical growth rate if there were no such limit on iron availability.", "dimensions": "longitude latitude time", "out_name": "limfecalc", "type": "real", @@ -2480,13 +2607,14 @@ "ok_max_mean_abs": "" }, "limfediat": { - "modeling_realm": "ocnBgChem", - "standard_name": "iron_limitation_of_diatoms", - "units": "1.0", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "iron_growth_limitation_of_diatoms", + "units": "1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Iron limitation of Diatoms", - "comment": "", + "long_name": "Iron Limitation of Diatoms", + "comment": "Diatoms are phytoplankton with an external skeleton made of silica. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. 'Iron growth limitation' means the ratio of the growth rate of a species population in the environment (where there is a finite availability of iron) to the theoretical growth rate if there were no such limit on iron availability.", "dimensions": "longitude latitude time", "out_name": "limfediat", "type": "real", @@ -2497,13 +2625,14 @@ "ok_max_mean_abs": "" }, "limfediaz": { - "modeling_realm": "ocnBgChem", - "standard_name": "iron_limitation_of_diazotrophs", - "units": "1.0", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "iron_growth_limitation_of_diazotrophs", + "units": "1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Iron limitation of Diazotrophs", - "comment": "", + "long_name": "Iron Limitation of Diazotrophs", + "comment": "In ocean modelling, diazotrophs are phytoplankton of the phylum cyanobacteria distinct from other phytoplankton groups in their ability to fix nitrogen gas in addition to nitrate and ammonium. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. 'Iron growth limitation' means the ratio of the growth rate of a species population in the environment (where there is a finite availability of iron) to the theoretical growth rate if there were no such limit on iron availability.", "dimensions": "longitude latitude time", "out_name": "limfediaz", "type": "real", @@ -2514,13 +2643,14 @@ "ok_max_mean_abs": "" }, "limfemisc": { - "modeling_realm": "ocnBgChem", - "standard_name": "iron_limitation_of_miscellaneous_phytoplankton", - "units": "1.0", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "iron_growth_limitation_of_miscellaneous_phytoplankton", + "units": "1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", "long_name": "Iron Limitation of Other Phytoplankton", - "comment": "", + "comment": "Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. 'Miscellaneous phytoplankton' are all those phytoplankton that are not diatoms, diazotrophs, calcareous phytoplankton, picophytoplankton or other separately named components of the phytoplankton population. 'Iron growth limitation' means the ratio of the growth rate of a species population in the environment (where there is a finite availability of iron) to the theoretical growth rate if there were no such limit on iron availability.", "dimensions": "longitude latitude time", "out_name": "limfemisc", "type": "real", @@ -2531,13 +2661,14 @@ "ok_max_mean_abs": "" }, "limfepico": { - "modeling_realm": "ocnBgChem", - "standard_name": "iron_limitation_of_picophytoplankton", - "units": "1.0", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "iron_growth_limitation_of_picophytoplankton", + "units": "1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Iron limitation of Picophytoplankton", - "comment": "", + "long_name": "Iron Limitation of Picophytoplankton", + "comment": "Picophytoplankton are phytoplankton of less than 2 micrometers in size. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. 'Iron growth limitation' means the ratio of the growth rate of a species population in the environment (where there is a finite availability of iron) to the theoretical growth rate if there were no such limit on iron availability.", "dimensions": "longitude latitude time", "out_name": "limfepico", "type": "real", @@ -2548,13 +2679,14 @@ "ok_max_mean_abs": "" }, "limirrcalc": { - "modeling_realm": "ocnBgChem", - "standard_name": "irradiance_limitation_of_calcareous_phytoplankton", - "units": "1.0", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "growth_limitation_of_calcareous_phytoplankton_due_to_solar_irradiance", + "units": "1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Irradiance limitation of Calcareous Phytoplankton", - "comment": "", + "long_name": "Irradiance Limitation of Calcareous Phytoplankton", + "comment": "Growth limitation of calcareous phytoplankton due to solar irradiance. 'Growth limitation due to solar irradiance' means the ratio of the growth rate of a species population in the environment (where the amount of sunlight reaching a location may be limited) to the theoretical growth rate if there were no such limit on solar irradiance.", "dimensions": "longitude latitude time", "out_name": "limirrcalc", "type": "real", @@ -2565,13 +2697,14 @@ "ok_max_mean_abs": "" }, "limirrdiat": { - "modeling_realm": "ocnBgChem", - "standard_name": "irradiance_limitation_of_diatoms", - "units": "1.0", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "growth_limitation_of_diatoms_due_to_solar_irradiance", + "units": "1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Irradiance limitation of Diatoms", - "comment": "", + "long_name": "Irradiance Limitation of Diatoms", + "comment": "Growth limitation of diatoms due to solar irradiance. 'Growth limitation due to solar irradiance' means the ratio of the growth rate of a species population in the environment (where the amount of sunlight reaching a location may be limited) to the theoretical growth rate if there were no such limit on solar irradiance.", "dimensions": "longitude latitude time", "out_name": "limirrdiat", "type": "real", @@ -2582,13 +2715,14 @@ "ok_max_mean_abs": "" }, "limirrdiaz": { - "modeling_realm": "ocnBgChem", - "standard_name": "irradiance_limitation_of_diazotrophs", - "units": "1.0", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "growth_limitation_of_diazotrophs_due_to_solar_irradiance", + "units": "1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Irradiance limitation of Diazotrophs", - "comment": "", + "long_name": "Irradiance Limitation of Diazotrophs", + "comment": "Growth limitation of diazotrophs due to solar irradiance. 'Growth limitation due to solar irradiance' means the ratio of the growth rate of a species population in the environment (where the amount of sunlight reaching a location may be limited) to the theoretical growth rate if there were no such limit on solar irradiance.", "dimensions": "longitude latitude time", "out_name": "limirrdiaz", "type": "real", @@ -2599,13 +2733,14 @@ "ok_max_mean_abs": "" }, "limirrmisc": { - "modeling_realm": "ocnBgChem", - "standard_name": "irradiance_limitation_of_miscellaneous_phytoplankton", - "units": "1.0", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "growth_limitation_of_miscellaneous_phytoplankton_due_to_solar_irradiance", + "units": "1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", "long_name": "Irradiance Limitation of Other Phytoplankton", - "comment": "", + "comment": "Growth limitation of miscellaneous phytoplankton due to solar irradiance. 'Growth limitation due to solar irradiance' means the ratio of the growth rate of a species population in the environment (where the amount of sunlight reaching a location may be limited) to the theoretical growth rate if there were no such limit on solar irradiance.", "dimensions": "longitude latitude time", "out_name": "limirrmisc", "type": "real", @@ -2616,13 +2751,14 @@ "ok_max_mean_abs": "" }, "limirrpico": { - "modeling_realm": "ocnBgChem", - "standard_name": "irradiance_limitation_of_picophytoplankton", - "units": "1.0", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "growth_limitation_of_picophytoplankton_due_to_solar_irradiance", + "units": "1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Irradiance limitation of Picophytoplankton", - "comment": "", + "long_name": "Irradiance Limitation of Picophytoplankton", + "comment": "Growth limitation of picophytoplankton due to solar irradiance. 'Growth limitation due to solar irradiance' means the ratio of the growth rate of a species population in the environment (where the amount of sunlight reaching a location may be limited) to the theoretical growth rate if there were no such limit on solar irradiance.", "dimensions": "longitude latitude time", "out_name": "limirrpico", "type": "real", @@ -2633,13 +2769,14 @@ "ok_max_mean_abs": "" }, "limncalc": { - "modeling_realm": "ocnBgChem", - "standard_name": "nitrogen_limitation_of_calcareous_phytoplankton", - "units": "1.0", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "nitrogen_growth_limitation_of_calcareous_phytoplankton", + "units": "1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Nitrogen limitation of Calcareous Phytoplankton", - "comment": "", + "long_name": "Nitrogen Limitation of Calcareous Phytoplankton", + "comment": "'Calcareous phytoplankton' are phytoplankton that produce calcite. Calcite is a mineral that is a polymorph of calcium carbonate. The chemical formula of calcite is CaCO3. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. 'Nitrogen growth limitation' means the ratio of the growth rate of a species population in the environment (where there is a finite availability of nitrogen) to the theoretical growth rate if there were no such limit on nitrogen availability.", "dimensions": "longitude latitude time", "out_name": "limncalc", "type": "real", @@ -2650,13 +2787,14 @@ "ok_max_mean_abs": "" }, "limndiat": { - "modeling_realm": "ocnBgChem", - "standard_name": "nitrogen_limitation_of_diatoms", - "units": "1.0", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "nitrogen_growth_limitation_of_diatoms", + "units": "1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Nitrogen limitation of Diatoms", - "comment": "", + "long_name": "Nitrogen Limitation of Diatoms", + "comment": "Diatoms are phytoplankton with an external skeleton made of silica. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. 'Nitrogen growth limitation' means the ratio of the growth rate of a species population in the environment (where there is a finite availability of nitrogen) to the theoretical growth rate if there were no such limit on nitrogen availability.", "dimensions": "longitude latitude time", "out_name": "limndiat", "type": "real", @@ -2667,13 +2805,14 @@ "ok_max_mean_abs": "" }, "limndiaz": { - "modeling_realm": "ocnBgChem", - "standard_name": "nitrogen_limitation_of_diazotrophs", - "units": "1.0", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "nitrogen_growth_limitation_of_diazotrophs", + "units": "1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Nitrogen limitation of Diazotrophs", - "comment": "", + "long_name": "Nitrogen Limitation of Diazotrophs", + "comment": "In ocean modelling, diazotrophs are phytoplankton of the phylum cyanobacteria distinct from other phytoplankton groups in their ability to fix nitrogen gas in addition to nitrate and ammonium. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. 'Nitrogen growth limitation' means the ratio of the growth rate of a species population in the environment (where there is a finite availability of nitrogen) to the theoretical growth rate if there were no such limit on nitrogen availability.", "dimensions": "longitude latitude time", "out_name": "limndiaz", "type": "real", @@ -2684,13 +2823,14 @@ "ok_max_mean_abs": "" }, "limnmisc": { - "modeling_realm": "ocnBgChem", - "standard_name": "nitrogen_limitation_of_miscellaneous_phytoplankton", - "units": "1.0", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "nitrogen_growth_limitation_of_miscellaneous_phytoplankton", + "units": "1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", "long_name": "Nitrogen Limitation of Other Phytoplankton", - "comment": "", + "comment": "Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. 'Miscellaneous phytoplankton' are all those phytoplankton that are not diatoms, diazotrophs, calcareous phytoplankton, picophytoplankton or other separately named components of the phytoplankton population. 'Nitrogen growth limitation' means the ratio of the growth rate of a species population in the environment (where there is a finite availability of nitrogen) to the theoretical growth rate if there were no such limit on nitrogen availability.", "dimensions": "longitude latitude time", "out_name": "limnmisc", "type": "real", @@ -2701,13 +2841,14 @@ "ok_max_mean_abs": "" }, "limnpico": { - "modeling_realm": "ocnBgChem", - "standard_name": "nitrogen_limitation_of_picophytoplankton", - "units": "1.0", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "nitrogen_growth_limitation_of_picophytoplankton", + "units": "1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Nitrogen limitation of Picophytoplankton", - "comment": "", + "long_name": "Nitrogen Limitation of Picophytoplankton", + "comment": "Picophytoplankton are phytoplankton of less than 2 micrometers in size. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. 'Nitrogen growth limitation' means the ratio of the growth rate of a species population in the environment (where there is a finite availability of nitrogen) to the theoretical growth rate if there were no such limit on nitrogen availability.", "dimensions": "longitude latitude time", "out_name": "limnpico", "type": "real", @@ -2718,12 +2859,13 @@ "ok_max_mean_abs": "" }, "masscello": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "sea_water_mass_per_unit_area", "units": "kg m-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Sea Water Mass Per Unit Area", + "long_name": "Ocean Grid-Cell Mass per Area", "comment": "Tracer grid-cell mass per unit area used for computing tracer budgets. For Boussinesq models with static ocean grid cell thickness, masscello = rhozero*thickcello, where thickcello is static cell thickness and rhozero is constant Boussinesq reference density. More generally, masscello is time dependent and reported as part of Omon.", "dimensions": "longitude latitude olevel time", "out_name": "masscello", @@ -2735,13 +2877,14 @@ "ok_max_mean_abs": "" }, "masso": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "sea_water_mass", "units": "kg", "cell_methods": "area: sum where sea time: mean", "cell_measures": "", "long_name": "Sea Water Mass", - "comment": "Total mass of liquid seawater. For Boussinesq models, report this diagnostic as Boussinesq reference density times total volume.", + "comment": "Total mass of liquid sea water. For Boussinesq models, report this diagnostic as Boussinesq reference density times total volume.", "dimensions": "time", "out_name": "masso", "type": "real", @@ -2752,13 +2895,14 @@ "ok_max_mean_abs": "" }, "mfo": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "sea_water_transport_across_line", "units": "kg s-1", "cell_methods": "time: mean", - "cell_measures": "area: areacella", + "cell_measures": "", "long_name": "Sea Water Transport", - "comment": "", + "comment": "Transport across_line means that which crosses a particular line on the Earth's surface; formally this means the integral along the line of the normal component of the transport.", "dimensions": "oline time", "out_name": "mfo", "type": "real", @@ -2769,6 +2913,7 @@ "ok_max_mean_abs": "" }, "mlotst": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "ocean_mixed_layer_thickness_defined_by_sigma_t", "units": "m", @@ -2786,6 +2931,7 @@ "ok_max_mean_abs": "" }, "mlotstmax": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "ocean_mixed_layer_thickness_defined_by_sigma_t", "units": "m", @@ -2803,6 +2949,7 @@ "ok_max_mean_abs": "" }, "mlotstmin": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "ocean_mixed_layer_thickness_defined_by_sigma_t", "units": "m", @@ -2820,13 +2967,14 @@ "ok_max_mean_abs": "" }, "mlotstsq": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "square_of_ocean_mixed_layer_thickness_defined_by_sigma_t", "units": "m2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", "long_name": "Square of Ocean Mixed Layer Thickness Defined by Sigma T", - "comment": "", + "comment": "The phrase 'square_of_X' means X*X. The ocean mixed layer is the upper part of the ocean, regarded as being well-mixed. The base of the mixed layer defined by 'temperature', 'sigma', 'sigma_theta', 'sigma_t' or vertical diffusivity is the level at which the quantity indicated differs from its surface value by a certain amount. A coordinate variable or scalar coordinate variable with standard name sea_water_sigma_t_difference can be used to specify the sigma_t criterion that determines the layer thickness. Sigma-t of sea water is the density of water at atmospheric pressure (i.e. the surface) having the same temperature and salinity, minus 1000 kg m-3. 'Thickness' means the vertical extent of a layer.", "dimensions": "longitude latitude time", "out_name": "mlotstsq", "type": "real", @@ -2837,6 +2985,7 @@ "ok_max_mean_abs": "" }, "msftbarot": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "ocean_barotropic_mass_streamfunction", "units": "kg s-1", @@ -2854,11 +3003,12 @@ "ok_max_mean_abs": "" }, "msftmrho": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "ocean_meridional_overturning_mass_streamfunction", "units": "kg s-1", - "cell_methods": "longitude: mean (comment: basin mean[ along zig-zag grid path]) time: mean", - "cell_measures": "area: areacella", + "cell_methods": "longitude: sum (comment: basin sum [along zig-zag grid path]) depth: sum time: mean", + "cell_measures": "", "long_name": "Ocean Meridional Overturning Mass Streamfunction", "comment": "Overturning mass streamfunction arising from all advective mass transport processes, resolved and parameterized.", "dimensions": "latitude rho basin time", @@ -2871,12 +3021,13 @@ "ok_max_mean_abs": "" }, "msftmrhompa": { + "frequency": "mon", "modeling_realm": "ocean", - "standard_name": "ocean_meridional_overturning_mass_streamfunction_due_to_parameterized_mesoscale_advection", + "standard_name": "ocean_meridional_overturning_mass_streamfunction_due_to_parameterized_mesoscale_eddy_advection", "units": "kg s-1", - "cell_methods": "longitude: mean (comment: basin mean[ along zig-zag grid path]) time: mean", - "cell_measures": "area: areacella", - "long_name": "ocean meridional overturning mass streamfunction due to parameterized mesoscale advection", + "cell_methods": "longitude: sum (comment: basin sum [along zig-zag grid path]) depth: sum time: mean", + "cell_measures": "", + "long_name": "Ocean Meridional Overturning Mass Streamfunction Due to Parameterized Mesoscale Advection", "comment": "CMIP5 called this 'due to Bolus Advection'. Name change respects the more general physics of the mesoscale parameterizations.", "dimensions": "latitude rho basin time", "out_name": "msftmrhompa", @@ -2887,16 +3038,17 @@ "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, - "msftmyz": { + "msftmz": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "ocean_meridional_overturning_mass_streamfunction", "units": "kg s-1", - "cell_methods": "longitude: mean (comment: basin mean[ along zig-zag grid path]) time: mean", - "cell_measures": "area: areacella", + "cell_methods": "longitude: sum (comment: basin sum [along zig-zag grid path]) depth: sum time: mean", + "cell_measures": "", "long_name": "Ocean Meridional Overturning Mass Streamfunction", "comment": "Overturning mass streamfunction arising from all advective mass transport processes, resolved and parameterized.", "dimensions": "latitude olevel basin time", - "out_name": "msftmyz", + "out_name": "msftmz", "type": "real", "positive": "", "valid_min": "", @@ -2905,12 +3057,13 @@ "ok_max_mean_abs": "" }, "msftmzmpa": { + "frequency": "mon", "modeling_realm": "ocean", - "standard_name": "ocean_meridional_overturning_mass_streamfunction_due_to_parameterized_mesoscale_advection", + "standard_name": "ocean_meridional_overturning_mass_streamfunction_due_to_parameterized_mesoscale_eddy_advection", "units": "kg s-1", - "cell_methods": "longitude: mean (comment: basin mean[ along zig-zag grid path]) time: mean", - "cell_measures": "area: areacella", - "long_name": "ocean meridional overturning mass streamfunction due to parameterized mesoscale advection", + "cell_methods": "longitude: sum (comment: basin sum [along zig-zag grid path]) depth: sum time: mean", + "cell_measures": "", + "long_name": "Ocean Meridional Overturning Mass Streamfunction Due to Parameterized Mesoscale Advection", "comment": "CMIP5 called this 'due to Bolus Advection'. Name change respects the more general physics of the mesoscale parameterizations.", "dimensions": "latitude olevel basin time", "out_name": "msftmzmpa", @@ -2922,12 +3075,13 @@ "ok_max_mean_abs": "" }, "msftmzsmpa": { + "frequency": "mon", "modeling_realm": "ocean", - "standard_name": "ocean_meridional_overturning_mass_streamfunction_due_to_parameterized_submesoscale_advection", + "standard_name": "ocean_meridional_overturning_mass_streamfunction_due_to_parameterized_submesoscale_eddy_advection", "units": "kg s-1", - "cell_methods": "longitude: mean (comment: basin mean[ along zig-zag grid path]) time: mean", - "cell_measures": "area: areacella", - "long_name": "ocean meridional overturning mass streamfunction due to parameterized submesoscale advection", + "cell_methods": "longitude: sum (comment: basin sum [along zig-zag grid path]) depth: sum time: mean", + "cell_measures": "", + "long_name": "Ocean Meridional Overturning Mass Streamfunction Due to Parameterized Submesoscale Advection", "comment": "Report only if there is a submesoscale eddy parameterization.", "dimensions": "latitude olevel basin time", "out_name": "msftmzsmpa", @@ -2939,14 +3093,15 @@ "ok_max_mean_abs": "" }, "msftyrho": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "ocean_y_overturning_mass_streamfunction", "units": "kg s-1", "cell_methods": "time: mean grid_longitude: mean", - "cell_measures": "area: areacella", + "cell_measures": "", "long_name": "Ocean Y Overturning Mass Streamfunction", "comment": "Overturning mass streamfunction arising from all advective mass transport processes, resolved and parameterized.", - "dimensions": "latitude rho basin time", + "dimensions": "gridlatitude rho basin time", "out_name": "msftyrho", "type": "real", "positive": "", @@ -2956,14 +3111,15 @@ "ok_max_mean_abs": "" }, "msftyrhompa": { + "frequency": "mon", "modeling_realm": "ocean", - "standard_name": "ocean_y_overturning_mass_streamfunction_due_to_parameterized_mesoscale_advection", + "standard_name": "ocean_y_overturning_mass_streamfunction_due_to_parameterized_mesoscale_eddy_advection", "units": "kg s-1", "cell_methods": "time: mean grid_longitude: mean", - "cell_measures": "area: areacella", - "long_name": "ocean Y overturning mass streamfunction due to parameterized mesoscale advection", + "cell_measures": "", + "long_name": "Ocean Y Overturning Mass Streamfunction Due to Parameterized Mesoscale Advection", "comment": "CMIP5 called this 'due to Bolus Advection'. Name change respects the more general physics of the mesoscale parameterizations.", - "dimensions": "latitude rho basin time", + "dimensions": "gridlatitude rho basin time", "out_name": "msftyrhompa", "type": "real", "positive": "", @@ -2972,16 +3128,17 @@ "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, - "msftyyz": { + "msftyz": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "ocean_y_overturning_mass_streamfunction", "units": "kg s-1", "cell_methods": "time: mean grid_longitude: mean", - "cell_measures": "area: areacella", + "cell_measures": "", "long_name": "Ocean Y Overturning Mass Streamfunction", "comment": "Overturning mass streamfunction arising from all advective mass transport processes, resolved and parameterized.", - "dimensions": "latitude olevel basin time", - "out_name": "msftyyz", + "dimensions": "gridlatitude olevel basin time", + "out_name": "msftyz", "type": "real", "positive": "", "valid_min": "", @@ -2990,14 +3147,15 @@ "ok_max_mean_abs": "" }, "msftyzmpa": { + "frequency": "mon", "modeling_realm": "ocean", - "standard_name": "ocean_y_overturning_mass_streamfunction_due_to_parameterized_mesoscale_advection", + "standard_name": "ocean_y_overturning_mass_streamfunction_due_to_parameterized_mesoscale_eddy_advection", "units": "kg s-1", "cell_methods": "time: mean grid_longitude: mean", - "cell_measures": "area: areacella", - "long_name": "ocean Y overturning mass streamfunction due to parameterized mesoscale advection", + "cell_measures": "", + "long_name": "Ocean Y Overturning Mass Streamfunction Due to Parameterized Mesoscale Advection", "comment": "CMIP5 called this 'due to Bolus Advection'. Name change respects the more general physics of the mesoscale parameterizations.", - "dimensions": "latitude olevel basin time", + "dimensions": "gridlatitude olevel basin time", "out_name": "msftyzmpa", "type": "real", "positive": "", @@ -3007,12 +3165,13 @@ "ok_max_mean_abs": "" }, "msftyzsmpa": { + "frequency": "mon", "modeling_realm": "ocean", - "standard_name": "ocean_meridional_overturning_mass_streamfunction_due_to_parameterized_submesoscale_advection", + "standard_name": "ocean_meridional_overturning_mass_streamfunction_due_to_parameterized_submesoscale_eddy_advection", "units": "kg s-1", - "cell_methods": "longitude: mean (comment: basin mean[ along zig-zag grid path]) time: mean", - "cell_measures": "area: areacella", - "long_name": "ocean Y overturning mass streamfunction due to parameterized submesoscale advection", + "cell_methods": "longitude: sum (comment: basin sum [along zig-zag grid path]) depth: sum time: mean", + "cell_measures": "", + "long_name": "Ocean Y Overturning Mass Streamfunction Due to Parameterized Submesoscale Advection", "comment": "Report only if there is a submesoscale eddy parameterization.", "dimensions": "latitude olevel basin time", "out_name": "msftyzsmpa", @@ -3024,14 +3183,15 @@ "ok_max_mean_abs": "" }, "nh4": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_ammonium_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", + "cell_measures": "area: areacello volume: volcello", "long_name": "Dissolved Ammonium Concentration", - "comment": "", - "dimensions": "longitude latitude time depth0m", + "comment": "Mole concentration means moles (amount of substance) per unit volume and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y.", + "dimensions": "longitude latitude olevel time", "out_name": "nh4", "type": "real", "positive": "", @@ -3041,13 +3201,14 @@ "ok_max_mean_abs": "" }, "nh4os": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_mole_concentration_of_ammonium_in_sea_water", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_ammonium_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", "long_name": "Surface Dissolved Ammonium Concentration", - "comment": "", + "comment": "Mole concentration means moles (amount of substance) per unit volume and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y.", "dimensions": "longitude latitude time", "out_name": "nh4os", "type": "real", @@ -3058,14 +3219,15 @@ "ok_max_mean_abs": "" }, "no3": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_nitrate_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", + "cell_measures": "area: areacello volume: volcello", "long_name": "Dissolved Nitrate Concentration", - "comment": "", - "dimensions": "longitude latitude time depth0m", + "comment": "Mole concentration means moles (amount of substance) per unit volume and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y.", + "dimensions": "longitude latitude olevel time", "out_name": "no3", "type": "real", "positive": "", @@ -3075,13 +3237,14 @@ "ok_max_mean_abs": "" }, "no3os": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_mole_concentration_of_nitrate_in_sea_water", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_nitrate_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", "long_name": "Surface Dissolved Nitrate Concentration", - "comment": "", + "comment": "Mole concentration means moles (amount of substance) per unit volume and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y.", "dimensions": "longitude latitude time", "out_name": "no3os", "type": "real", @@ -3092,14 +3255,15 @@ "ok_max_mean_abs": "" }, "o2": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_dissolved_molecular_oxygen_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", + "cell_measures": "area: areacello volume: volcello", "long_name": "Dissolved Oxygen Concentration", - "comment": "", - "dimensions": "longitude latitude time depth0m", + "comment": "'Mole concentration' means number of moles per unit volume, also called 'molarity', and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'.", + "dimensions": "longitude latitude olevel time", "out_name": "o2", "type": "real", "positive": "", @@ -3109,13 +3273,14 @@ "ok_max_mean_abs": "" }, "o2min": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_dissolved_molecular_oxygen_in_sea_water_at_shallowest_local_minimum_in_vertical_profile", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", "long_name": "Oxygen Minimum Concentration", - "comment": "", + "comment": "'Mole concentration' means number of moles per unit volume, also called 'molarity', and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The concentration of any chemical species, whether particulate or dissolved, may vary with depth in the ocean. A depth profile may go through one or more local minima in concentration. The mole_concentration_of_molecular_oxygen_in_sea_water_at_shallowest_local_minimum_in_vertical_profile is the mole concentration of oxygen at the local minimum in the concentration profile that occurs closest to the sea surface.", "dimensions": "longitude latitude time", "out_name": "o2min", "type": "real", @@ -3126,13 +3291,14 @@ "ok_max_mean_abs": "" }, "o2os": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_mole_concentration_of_dissolved_molecular_oxygen_in_sea_water", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_dissolved_molecular_oxygen_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", "long_name": "Surface Dissolved Oxygen Concentration", - "comment": "", + "comment": "'Mole concentration' means number of moles per unit volume, also called 'molarity', and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'.", "dimensions": "longitude latitude time", "out_name": "o2os", "type": "real", @@ -3143,14 +3309,15 @@ "ok_max_mean_abs": "" }, "o2sat": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_dissolved_molecular_oxygen_in_sea_water_at_saturation", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", + "cell_measures": "area: areacello volume: volcello", "long_name": "Dissolved Oxygen Concentration at Saturation", - "comment": "", - "dimensions": "longitude latitude time depth0m", + "comment": "'Mole concentration at saturation' means the mole concentration in a saturated solution. Mole concentration means number of moles per unit volume, also called 'molarity', and is used in the construction 'mole_concentration_of_X_in_Y', where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'.", + "dimensions": "longitude latitude olevel time", "out_name": "o2sat", "type": "real", "positive": "", @@ -3160,13 +3327,14 @@ "ok_max_mean_abs": "" }, "o2satos": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_mole_concentration_of_dissolved_molecular_oxygen_in_sea_water_at_saturation", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_dissolved_molecular_oxygen_in_sea_water_at_saturation", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", "long_name": "Surface Dissolved Oxygen Concentration at Saturation", - "comment": "", + "comment": "'Mole concentration at saturation' means the mole concentration in a saturated solution. Mole concentration means number of moles per unit volume, also called 'molarity', and is used in the construction 'mole_concentration_of_X_in_Y', where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'.", "dimensions": "longitude latitude time", "out_name": "o2satos", "type": "real", @@ -3177,13 +3345,14 @@ "ok_max_mean_abs": "" }, "obvfsq": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "square_of_brunt_vaisala_frequency_in_sea_water", "units": "s-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", "long_name": "Square of Brunt Vaisala Frequency in Sea Water", - "comment": "", + "comment": "The phrase 'square_of_X' means X*X. Frequency is the number of oscillations of a wave per unit time. Brunt-Vaisala frequency is also sometimes called 'buoyancy frequency' and is a measure of the vertical stratification of the medium.", "dimensions": "longitude latitude olevel time", "out_name": "obvfsq", "type": "real", @@ -3194,12 +3363,13 @@ "ok_max_mean_abs": "" }, "ocfriver": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_ocean_mole_content_of_organic_carbon_due_to_runoff_and_sediment_dissolution", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Flux of Organic Carbon Into Ocean Surface by Runoff", + "long_name": "Flux of Organic Carbon into Ocean Surface by Runoff", "comment": "Organic Carbon supply to ocean through runoff (separate from gas exchange)", "dimensions": "longitude latitude time depth0m", "out_name": "ocfriver", @@ -3210,31 +3380,15 @@ "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, - "pbfe": { - "modeling_realm": "ocnBgChem", - "standard_name": "tendency_of_mole_concentration_of_iron_in_sea_water_due_to_biological_production", - "units": "mol m-3 s-1", - "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", - "long_name": "Biogenic Iron Production", - "comment": "", - "dimensions": "longitude latitude time depth0m", - "out_name": "pbfe", - "type": "real", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, "pbo": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "sea_water_pressure_at_sea_floor", "units": "Pa", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Sea Water Pressure at Sea floor", - "comment": "", + "long_name": "Sea Water Pressure at Sea Floor", + "comment": "'Sea water pressure' is the pressure that exists in the medium of sea water. It includes the pressure due to overlying sea water, sea ice, air and any other medium that may be present.", "dimensions": "longitude latitude time", "out_name": "pbo", "type": "real", @@ -3244,32 +3398,16 @@ "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, - "pbsi": { - "modeling_realm": "ocnBgChem", - "standard_name": "tendency_of_mole_concentration_of_silicon_in_sea_water_due_to_biological_production", - "units": "mol m-3 s-1", - "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", - "long_name": "Biogenic Silica Production", - "comment": "", - "dimensions": "longitude latitude time depth0m", - "out_name": "pbsi", - "type": "real", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, "ph": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "sea_water_ph_reported_on_total_scale", - "units": "1.0", + "units": "1", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", + "cell_measures": "area: areacello volume: volcello", "long_name": "pH", "comment": "negative log of hydrogen ion concentration with the concentration expressed as mol H kg-1.", - "dimensions": "longitude latitude time depth0m", + "dimensions": "longitude latitude olevel time", "out_name": "ph", "type": "real", "positive": "", @@ -3279,14 +3417,15 @@ "ok_max_mean_abs": "" }, "phabio": { - "modeling_realm": "ocnBgChem", - "standard_name": "sea_water_ph_reported_on_total_scale_due_to_abiotic_component", - "units": "1.0", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "sea_water_ph_abiotic_analogue_reported_on_total_scale", + "units": "1", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", + "cell_measures": "area: areacello volume: volcello", "long_name": "Abiotic pH", "comment": "negative log10 of hydrogen ion concentration with the concentration expressed as mol H kg-1 (abiotic component)..", - "dimensions": "longitude latitude time depth0m", + "dimensions": "longitude latitude olevel time", "out_name": "phabio", "type": "real", "positive": "", @@ -3296,9 +3435,10 @@ "ok_max_mean_abs": "" }, "phabioos": { - "modeling_realm": "ocnBgChem", - "standard_name": "sea_water_ph_reported_on_total_scale_due_to_abiotic_component", - "units": "1.0", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "sea_water_ph_abiotic_analogue_reported_on_total_scale", + "units": "1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", "long_name": "Surface Abiotic pH", @@ -3313,14 +3453,15 @@ "ok_max_mean_abs": "" }, "phnat": { - "modeling_realm": "ocnBgChem", - "standard_name": "sea_water_ph_reported_on_total_scale_due_to_natural_component", - "units": "1.0", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "sea_water_ph_natural_analogue_reported_on_total_scale", + "units": "1", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", + "cell_measures": "area: areacello volume: volcello", "long_name": "Natural pH", "comment": "negative log10 of hydrogen ion concentration with the concentration expressed as mol H kg-1.", - "dimensions": "longitude latitude time depth0m", + "dimensions": "longitude latitude olevel time", "out_name": "phnat", "type": "real", "positive": "", @@ -3330,9 +3471,10 @@ "ok_max_mean_abs": "" }, "phnatos": { - "modeling_realm": "ocnBgChem", - "standard_name": "sea_water_ph_reported_on_total_scale_due_to_natural_component", - "units": "1.0", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "sea_water_ph_natural_analogue_reported_on_total_scale", + "units": "1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", "long_name": "Surface Natural pH", @@ -3347,9 +3489,10 @@ "ok_max_mean_abs": "" }, "phos": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "sea_water_ph_reported_on_total_scale", - "units": "1.0", + "units": "1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", "long_name": "Surface pH", @@ -3364,14 +3507,15 @@ "ok_max_mean_abs": "" }, "phyc": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_phytoplankton_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", + "cell_measures": "area: areacello volume: volcello", "long_name": "Phytoplankton Carbon Concentration", "comment": "sum of phytoplankton carbon component concentrations. In most (all?) cases this is the sum of phycdiat and phycmisc (i.e., 'Diatom Carbon Concentration' and 'Non-Diatom Phytoplankton Carbon Concentration'", - "dimensions": "longitude latitude time depth0m", + "dimensions": "longitude latitude olevel time", "out_name": "phyc", "type": "real", "positive": "", @@ -3381,14 +3525,15 @@ "ok_max_mean_abs": "" }, "phycalc": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_calcareous_phytoplankton_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", - "long_name": "Mole Concentration of Calcareous Phytoplankton expressed as Carbon in sea water", + "cell_measures": "area: areacello volume: volcello", + "long_name": "Mole Concentration of Calcareous Phytoplankton Expressed as Carbon in Sea Water", "comment": "carbon concentration from calcareous (calcite-producing) phytoplankton component alone", - "dimensions": "longitude latitude time depth0m", + "dimensions": "longitude latitude olevel time", "out_name": "phycalc", "type": "real", "positive": "", @@ -3398,12 +3543,13 @@ "ok_max_mean_abs": "" }, "phycalcos": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_mole_concentration_of_calcareous_phytoplankton_expressed_as_carbon_in_sea_water", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_calcareous_phytoplankton_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Surface Mole Concentration of Calcareous Phytoplankton expressed as Carbon in Sea Water", + "long_name": "Surface Mole Concentration of Calcareous Phytoplankton Expressed as Carbon in Sea Water", "comment": "carbon concentration from calcareous (calcite-producing) phytoplankton component alone", "dimensions": "longitude latitude time", "out_name": "phycalcos", @@ -3415,12 +3561,13 @@ "ok_max_mean_abs": "" }, "phycos": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_phytoplankton_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Surface Phytoplankton Carbon Concentration", + "long_name": "Sea Surface Phytoplankton Carbon Concentration", "comment": "sum of phytoplankton organic carbon component concentrations at the sea surface", "dimensions": "longitude latitude time", "out_name": "phycos", @@ -3432,14 +3579,15 @@ "ok_max_mean_abs": "" }, "phydiat": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_diatoms_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", - "long_name": "Mole Concentration of Diatoms expressed as Carbon in sea water", + "cell_measures": "area: areacello volume: volcello", + "long_name": "Mole Concentration of Diatoms Expressed as Carbon in Sea Water", "comment": "carbon from the diatom phytoplankton component concentration alone", - "dimensions": "longitude latitude time depth0m", + "dimensions": "longitude latitude olevel time", "out_name": "phydiat", "type": "real", "positive": "", @@ -3449,12 +3597,13 @@ "ok_max_mean_abs": "" }, "phydiatos": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_mole_concentration_of_diatoms_expressed_as_carbon_in_sea_water", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_diatoms_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Surface Mole Concentration of Diatoms expressed as Carbon in Sea Water", + "long_name": "Surface Mole Concentration of Diatoms Expressed as Carbon in Sea Water", "comment": "carbon from the diatom phytoplankton component concentration alone", "dimensions": "longitude latitude time", "out_name": "phydiatos", @@ -3466,14 +3615,15 @@ "ok_max_mean_abs": "" }, "phydiaz": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_diazotrophs_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", - "long_name": "Mole Concentration of Diazotrophs Expressed as Carbon in sea water", + "cell_measures": "area: areacello volume: volcello", + "long_name": "Mole Concentration of Diazotrophs Expressed as Carbon in Sea Water", "comment": "carbon concentration from the diazotrophic phytoplankton component alone", - "dimensions": "longitude latitude time depth0m", + "dimensions": "longitude latitude olevel time", "out_name": "phydiaz", "type": "real", "positive": "", @@ -3483,8 +3633,9 @@ "ok_max_mean_abs": "" }, "phydiazos": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_mole_concentration_of_diazotrophs_expressed_as_carbon_in_sea_water", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_diazotrophs_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", @@ -3500,14 +3651,15 @@ "ok_max_mean_abs": "" }, "phyfe": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_phytoplankton_expressed_as_iron_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", - "long_name": "Mole Concentration of Total Phytoplankton expressed as Iron in sea water", + "cell_measures": "area: areacello volume: volcello", + "long_name": "Mole Concentration of Total Phytoplankton Expressed as Iron in Sea Water", "comment": "sum of phytoplankton iron component concentrations", - "dimensions": "longitude latitude time depth0m", + "dimensions": "longitude latitude olevel time", "out_name": "phyfe", "type": "real", "positive": "", @@ -3517,12 +3669,13 @@ "ok_max_mean_abs": "" }, "phyfeos": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_mole_concentration_of_phytoplankton_expressed_as_iron_in_sea_water", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_phytoplankton_expressed_as_iron_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Surface Mass Concentration of Diazotrophs expressed as Chlorophyll in sea water", + "long_name": "Surface Mole Concentration of Total Phytoplankton Expressed as Iron in Sea Water", "comment": "sum of phytoplankton iron component concentrations", "dimensions": "longitude latitude time", "out_name": "phyfeos", @@ -3534,14 +3687,15 @@ "ok_max_mean_abs": "" }, "phymisc": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_miscellaneous_phytoplankton_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", - "long_name": "Mole Concentration of Miscellaneous Phytoplankton expressed as Carbon in sea water", + "cell_measures": "area: areacello volume: volcello", + "long_name": "Mole Concentration of Miscellaneous Phytoplankton Expressed as Carbon in Sea Water", "comment": "carbon concentration from additional phytoplankton component alone", - "dimensions": "longitude latitude time depth0m", + "dimensions": "longitude latitude olevel time", "out_name": "phymisc", "type": "real", "positive": "", @@ -3551,12 +3705,13 @@ "ok_max_mean_abs": "" }, "phymiscos": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_mole_concentration_of_miscellaneous_phytoplankton_expressed_as_carbon_in_sea_water", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_miscellaneous_phytoplankton_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Surface Mole Concentration of Miscellaneous Phytoplankton expressed as Carbon in Sea Water", + "long_name": "Surface Mole Concentration of Miscellaneous Phytoplankton Expressed as Carbon in Sea Water", "comment": "carbon concentration from additional phytoplankton component alone", "dimensions": "longitude latitude time", "out_name": "phymiscos", @@ -3568,14 +3723,15 @@ "ok_max_mean_abs": "" }, "phyn": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_phytoplankton_expressed_as_nitrogen_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", - "long_name": "Mole Concentration of Total Phytoplankton expressed as Nitrogen in sea water", + "cell_measures": "area: areacello volume: volcello", + "long_name": "Mole Concentration of Total Phytoplankton Expressed as Nitrogen in Sea Water", "comment": "sum of phytoplankton nitrogen component concentrations", - "dimensions": "longitude latitude time depth0m", + "dimensions": "longitude latitude olevel time", "out_name": "phyn", "type": "real", "positive": "", @@ -3585,12 +3741,13 @@ "ok_max_mean_abs": "" }, "phynos": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_mole_concentration_of_phytoplankton_expressed_as_nitrogen_in_sea_water", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_phytoplankton_expressed_as_nitrogen_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Surface Mole Concentration of Phytoplankton Nitrogen in sea water", + "long_name": "Surface Mole Concentration of Phytoplankton Nitrogen in Sea Water", "comment": "sum of phytoplankton nitrogen component concentrations", "dimensions": "longitude latitude time", "out_name": "phynos", @@ -3602,14 +3759,15 @@ "ok_max_mean_abs": "" }, "phyp": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_phytoplankton_expressed_as_phosphorus_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", - "long_name": "Mole Concentration of Total Phytoplankton expressed as Phosphorus in sea water", + "cell_measures": "area: areacello volume: volcello", + "long_name": "Mole Concentration of Total Phytoplankton Expressed as Phosphorus in Sea Water", "comment": "sum of phytoplankton phosphorus components", - "dimensions": "longitude latitude time depth0m", + "dimensions": "longitude latitude olevel time", "out_name": "phyp", "type": "real", "positive": "", @@ -3619,14 +3777,15 @@ "ok_max_mean_abs": "" }, "phypico": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_picophytoplankton_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", - "long_name": "Mole Concentration of Picophytoplankton expressed as Carbon in sea water", + "cell_measures": "area: areacello volume: volcello", + "long_name": "Mole Concentration of Picophytoplankton Expressed as Carbon in Sea Water", "comment": "carbon concentration from the picophytoplankton (<2 um) component alone", - "dimensions": "longitude latitude time depth0m", + "dimensions": "longitude latitude olevel time", "out_name": "phypico", "type": "real", "positive": "", @@ -3636,12 +3795,13 @@ "ok_max_mean_abs": "" }, "phypicoos": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_mole_concentration_of_picophytoplankton_expressed_as_carbon_in_sea_water", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_picophytoplankton_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Surface Mole Concentration of Picophytoplankton expressed as Carbon in Sea Water", + "long_name": "Surface Mole Concentration of Picophytoplankton Expressed as Carbon in Sea Water", "comment": "carbon concentration from the picophytoplankton (<2 um) component alone", "dimensions": "longitude latitude time", "out_name": "phypicoos", @@ -3653,12 +3813,13 @@ "ok_max_mean_abs": "" }, "phypos": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_mole_concentration_of_phytoplankton_expressed_as_phosphorus_in_sea_water", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_phytoplankton_expressed_as_phosphorus_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Surface Mole Concentration of Total Phytoplankton expressed as Phosphorus in sea water", + "long_name": "Surface Mole Concentration of Total Phytoplankton Expressed as Phosphorus in Sea Water", "comment": "sum of phytoplankton phosphorus components", "dimensions": "longitude latitude time", "out_name": "phypos", @@ -3670,14 +3831,15 @@ "ok_max_mean_abs": "" }, "physi": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_phytoplankton_expressed_as_silicon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", - "long_name": "Mole Concentration of Total Phytoplankton expressed as Silicon in sea water", + "cell_measures": "area: areacello volume: volcello", + "long_name": "Mole Concentration of Total Phytoplankton Expressed as Silicon in Sea Water", "comment": "sum of phytoplankton silica component concentrations", - "dimensions": "longitude latitude time depth0m", + "dimensions": "longitude latitude olevel time", "out_name": "physi", "type": "real", "positive": "", @@ -3687,12 +3849,13 @@ "ok_max_mean_abs": "" }, "physios": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_mole_concentration_of_phytoplankton_expressed_as_silicon_in_sea_water", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_phytoplankton_expressed_as_silicon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Surface Mole Concentration of Total Phytoplankton expressed as Silicon in sea water", + "long_name": "Surface Mole Concentration of Total Phytoplankton Expressed as Silicon in Sea Water", "comment": "sum of phytoplankton silica component concentrations", "dimensions": "longitude latitude time", "out_name": "physios", @@ -3703,32 +3866,16 @@ "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, - "pnitrate": { - "modeling_realm": "ocnBgChem", - "standard_name": "tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_nitrate_utilization", - "units": "mol m-3 s-1", - "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", - "long_name": "Primary Carbon Production by Phytoplankton due to Nitrate Uptake Alone", - "comment": "Primary (organic carbon) production by phytoplankton due to nitrate uptake alone", - "dimensions": "longitude latitude time depth0m", - "out_name": "pnitrate", - "type": "real", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, "po4": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_dissolved_inorganic_phosphorus_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", + "cell_measures": "area: areacello volume: volcello", "long_name": "Total Dissolved Inorganic Phosphorus Concentration", - "comment": "", - "dimensions": "longitude latitude time depth0m", + "comment": "Mole concentration means number of moles per unit volume, also called 'molarity', and is used in the construction 'mole_concentration_of_X_in_Y', where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. 'Dissolved inorganic phosphorus' means the sum of all inorganic phosphorus in solution (including phosphate, hydrogen phosphate, dihydrogen phosphate, and phosphoric acid).", + "dimensions": "longitude latitude olevel time", "out_name": "po4", "type": "real", "positive": "", @@ -3738,13 +3885,14 @@ "ok_max_mean_abs": "" }, "po4os": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_mole_concentration_of_dissolved_inorganic_phosphorus_in_sea_water", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_dissolved_inorganic_phosphorus_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", "long_name": "Surface Total Dissolved Inorganic Phosphorus Concentration", - "comment": "", + "comment": "Mole concentration means number of moles per unit volume, also called 'molarity', and is used in the construction 'mole_concentration_of_X_in_Y', where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. 'Dissolved inorganic phosphorus' means the sum of all inorganic phosphorus in solution (including phosphate, hydrogen phosphate, dihydrogen phosphate, and phosphoric acid).", "dimensions": "longitude latitude time", "out_name": "po4os", "type": "real", @@ -3755,14 +3903,15 @@ "ok_max_mean_abs": "" }, "pon": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_particulate_organic_matter_expressed_as_nitrogen_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", - "long_name": "Mole Concentration of Particulate Organic Matter expressed as Nitrogen in sea water", + "cell_measures": "area: areacello volume: volcello", + "long_name": "Mole Concentration of Particulate Organic Matter Expressed as Nitrogen in Sea Water", "comment": "sum of particulate organic nitrogen component concentrations", - "dimensions": "longitude latitude time depth0m", + "dimensions": "longitude latitude olevel time", "out_name": "pon", "type": "real", "positive": "", @@ -3772,12 +3921,13 @@ "ok_max_mean_abs": "" }, "ponos": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_mole_concentration_of_particulate_organic_matter_expressed_as_nitrogen_in_sea_water", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_particulate_organic_matter_expressed_as_nitrogen_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Surface Mole Concentration of Particulate Organic Matter expressed as Nitrogen in sea water", + "long_name": "Surface Mole Concentration of Particulate Organic Matter Expressed as Nitrogen in Sea Water", "comment": "sum of particulate organic nitrogen component concentrations", "dimensions": "longitude latitude time", "out_name": "ponos", @@ -3789,14 +3939,15 @@ "ok_max_mean_abs": "" }, "pop": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_particulate_organic_matter_expressed_as_phosphorus_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", - "long_name": "Mole Concentration of Particulate Organic Matter expressed as Phosphorus in sea water", + "cell_measures": "area: areacello volume: volcello", + "long_name": "Mole Concentration of Particulate Organic Matter Expressed as Phosphorus in Sea Water", "comment": "sum of particulate organic phosphorus component concentrations", - "dimensions": "longitude latitude time depth0m", + "dimensions": "longitude latitude olevel time", "out_name": "pop", "type": "real", "positive": "", @@ -3806,12 +3957,13 @@ "ok_max_mean_abs": "" }, "popos": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_mole_concentration_of_particulate_organic_matter_expressed_as_phosphorus_in_sea_water", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_particulate_organic_matter_expressed_as_phosphorus_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Surface Mole Concentration of Particulate Organic Matter expressed as Phosphorus in sea water", + "long_name": "Surface Mole Concentration of Particulate Organic Matter Expressed as Phosphorus in Sea Water", "comment": "sum of particulate organic phosphorus component concentrations", "dimensions": "longitude latitude time", "out_name": "popos", @@ -3823,15 +3975,34 @@ "ok_max_mean_abs": "" }, "pp": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production", + "units": "mol m-3 s-1", + "cell_methods": "area: mean where sea time: mean", + "cell_measures": "area: areacello volume: volcello", + "long_name": "Primary Carbon Production by Phytoplankton", + "comment": "total primary (organic carbon) production by phytoplankton", + "dimensions": "longitude latitude olevel time", + "out_name": "pp", + "type": "real", + "positive": "", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, + "ppos": { + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production", "units": "mol m-3 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Primary Carbon Production by Total Phytoplankton", + "long_name": "Primary Carbon Production by Phytoplankton", "comment": "total primary (organic carbon) production by phytoplankton", "dimensions": "longitude latitude time depth0m", - "out_name": "pp", + "out_name": "ppos", "type": "real", "positive": "", "valid_min": "", @@ -3840,13 +4011,14 @@ "ok_max_mean_abs": "" }, "prra": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "rainfall_flux", "units": "kg m-2 s-1", "cell_methods": "area: mean where ice_free_sea over sea time: mean", "cell_measures": "area: areacello", "long_name": "Rainfall Flux where Ice Free Ocean over Sea", - "comment": "", + "comment": "In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions": "longitude latitude time", "out_name": "prra", "type": "real", @@ -3857,13 +4029,14 @@ "ok_max_mean_abs": "" }, "prsn": { + "frequency": "mon", "modeling_realm": "atmos", "standard_name": "snowfall_flux", "units": "kg m-2 s-1", "cell_methods": "area: mean where ice_free_sea over sea time: mean", "cell_measures": "area: areacello", "long_name": "Snowfall Flux where Ice Free Ocean over Sea", - "comment": "at surface; includes precipitation of all forms of water in the solid phase", + "comment": "At surface; includes precipitation of all forms of water in the solid phase", "dimensions": "longitude latitude time", "out_name": "prsn", "type": "real", @@ -3874,13 +4047,14 @@ "ok_max_mean_abs": "" }, "pso": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "sea_water_pressure_at_sea_water_surface", "units": "Pa", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", "long_name": "Sea Water Pressure at Sea Water Surface", - "comment": "", + "comment": "The surface called 'surface' means the lower boundary of the atmosphere. 'Sea water pressure' is the pressure that exists in the medium of sea water. It includes the pressure due to overlying sea water, sea ice, air and any other medium that may be present.", "dimensions": "longitude latitude time", "out_name": "pso", "type": "real", @@ -3891,6 +4065,7 @@ "ok_max_mean_abs": "" }, "rlntds": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "surface_net_downward_longwave_flux", "units": "W m-2", @@ -3908,13 +4083,14 @@ "ok_max_mean_abs": "" }, "rsdo": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "downwelling_shortwave_flux_in_sea_water", "units": "W m-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", "long_name": "Downwelling Shortwave Radiation in Sea Water", - "comment": "", + "comment": "Downwelling radiation is radiation from above. It does not mean 'net downward'. When thought of as being incident on a surface, a radiative flux is sometimes called 'irradiance'. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called 'vector irradiance'. In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. 'shortwave' means shortwave radiation.", "dimensions": "longitude latitude olevel time", "out_name": "rsdo", "type": "real", @@ -3925,6 +4101,7 @@ "ok_max_mean_abs": "" }, "rsntds": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "net_downward_shortwave_flux_at_sea_water_surface", "units": "W m-2", @@ -3942,13 +4119,14 @@ "ok_max_mean_abs": "" }, "sf6": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "mole_concentration_of_sulfur_hexafluoride_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Moles Per Unit Mass of SF6 in sea water", - "comment": "", + "long_name": "Mole Concentration of SF6 in Sea Water", + "comment": "Mole concentration means number of moles per unit volume, also called 'molarity', and is used in the construction 'mole_concentration_of_X_in_Y', where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula of sulfur hexafluoride is SF6.", "dimensions": "longitude latitude olevel time", "out_name": "sf6", "type": "real", @@ -3959,6 +4137,7 @@ "ok_max_mean_abs": "" }, "sfdsi": { + "frequency": "mon", "modeling_realm": "ocean seaIce", "standard_name": "downward_sea_ice_basal_salt_flux", "units": "kg m-2 s-1", @@ -3969,13 +4148,14 @@ "dimensions": "longitude latitude time", "out_name": "sfdsi", "type": "real", - "positive": "", + "positive": "down", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "sfriver": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "salt_flux_into_sea_water_from_rivers", "units": "kg m-2 s-1", @@ -3993,14 +4173,15 @@ "ok_max_mean_abs": "" }, "si": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_dissolved_inorganic_silicon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", + "cell_measures": "area: areacello volume: volcello", "long_name": "Total Dissolved Inorganic Silicon Concentration", - "comment": "", - "dimensions": "longitude latitude time depth0m", + "comment": "Mole concentration means number of moles per unit volume, also called 'molarity', and is used in the construction 'mole_concentration_of_X_in_Y', where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. 'Dissolved inorganic silicon' means the sum of all inorganic silicon in solution (including silicic acid and its first dissociated anion SiO(OH)3-).", + "dimensions": "longitude latitude olevel time", "out_name": "si", "type": "real", "positive": "", @@ -4010,13 +4191,14 @@ "ok_max_mean_abs": "" }, "sios": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_mole_concentration_of_dissolved_inorganic_silicon_in_sea_water", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_dissolved_inorganic_silicon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", "long_name": "Surface Total Dissolved Inorganic Silicon Concentration", - "comment": "", + "comment": "Mole concentration means number of moles per unit volume, also called 'molarity', and is used in the construction 'mole_concentration_of_X_in_Y', where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. 'Dissolved inorganic silicon' means the sum of all inorganic silicon in solution (including silicic acid and its first dissociated anion SiO(OH)3-).", "dimensions": "longitude latitude time", "out_name": "sios", "type": "real", @@ -4027,12 +4209,13 @@ "ok_max_mean_abs": "" }, "sltovgyre": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "northward_ocean_salt_transport_due_to_gyre", "units": "kg s-1", - "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", - "long_name": "Northward Ocean Salt Transport due to Gyre", + "cell_methods": "longitude: sum (comment: basin sum [along zig-zag grid path]) depth: sum time: mean", + "cell_measures": "", + "long_name": "Northward Ocean Salt Transport Due to Gyre", "comment": "From all advective mass transport processes, resolved and parameterized.", "dimensions": "latitude basin time", "out_name": "sltovgyre", @@ -4044,12 +4227,13 @@ "ok_max_mean_abs": "" }, "sltovovrt": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "northward_ocean_salt_transport_due_to_overturning", "units": "kg s-1", - "cell_methods": "longitude: mean time: mean", - "cell_measures": "area: areacella", - "long_name": "Northward Ocean Salt Transport due to Overturning", + "cell_methods": "longitude: sum (comment: basin sum [along zig-zag grid path]) depth: sum time: mean", + "cell_measures": "", + "long_name": "Northward Ocean Salt Transport Due to Overturning", "comment": "From all advective mass transport processes, resolved and parameterized.", "dimensions": "latitude basin time", "out_name": "sltovovrt", @@ -4061,13 +4245,14 @@ "ok_max_mean_abs": "" }, "so": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "sea_water_salinity", "units": "0.001", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", "long_name": "Sea Water Salinity", - "comment": "", + "comment": "Sea water salinity is the salt content of sea water, often on the Practical Salinity Scale of 1978. However, the unqualified term 'salinity' is generic and does not necessarily imply any particular method of calculation. The units of salinity are dimensionless and the units attribute should normally be given as 1e-3 or 0.001 i.e. parts per thousand. ", "dimensions": "longitude latitude olevel time", "out_name": "so", "type": "real", @@ -4078,12 +4263,13 @@ "ok_max_mean_abs": "" }, "sob": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "sea_water_salinity_at_sea_floor", "units": "0.001", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "sea water salinity at sea floor", + "long_name": "Sea Water Salinity at Sea Floor", "comment": "Model prognostic salinity at bottom-most model grid cell", "dimensions": "longitude latitude time", "out_name": "sob", @@ -4095,13 +4281,14 @@ "ok_max_mean_abs": "" }, "soga": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "sea_water_salinity", "units": "0.001", "cell_methods": "area: mean where sea time: mean", "cell_measures": "", "long_name": "Global Mean Sea Water Salinity", - "comment": "", + "comment": "Sea water salinity is the salt content of sea water, often on the Practical Salinity Scale of 1978. However, the unqualified term 'salinity' is generic and does not necessarily imply any particular method of calculation. The units of salinity are dimensionless and the units attribute should normally be given as 1e-3 or 0.001 i.e. parts per thousand. ", "dimensions": "time", "out_name": "soga", "type": "real", @@ -4112,13 +4299,14 @@ "ok_max_mean_abs": "" }, "sos": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "sea_surface_salinity", "units": "0.001", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", "long_name": "Sea Surface Salinity", - "comment": "", + "comment": "Sea water salinity is the salt content of sea water, often on the Practical Salinity Scale of 1978. However, the unqualified term 'salinity' is generic and does not necessarily imply any particular method of calculation. The units of salinity are dimensionless and the units attribute should normally be given as 1e-3 or 0.001 i.e. parts per thousand. ", "dimensions": "longitude latitude time", "out_name": "sos", "type": "real", @@ -4129,13 +4317,14 @@ "ok_max_mean_abs": "" }, "sosga": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "sea_surface_salinity", "units": "0.001", "cell_methods": "area: mean where sea time: mean", "cell_measures": "", "long_name": "Global Average Sea Surface Salinity", - "comment": "", + "comment": "Sea water salinity is the salt content of sea water, often on the Practical Salinity Scale of 1978. However, the unqualified term 'salinity' is generic and does not necessarily imply any particular method of calculation. The units of salinity are dimensionless and the units attribute should normally be given as 1e-3 or 0.001 i.e. parts per thousand. ", "dimensions": "time", "out_name": "sosga", "type": "real", @@ -4146,13 +4335,14 @@ "ok_max_mean_abs": "" }, "sossq": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "square_of_sea_surface_salinity", "units": "1e-06", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", "long_name": "Square of Sea Surface Salinity", - "comment": "", + "comment": "Sea water salinity is the salt content of sea water, often on the Practical Salinity Scale of 1978. However, the unqualified term 'salinity' is generic and does not necessarily imply any particular method of calculation. The units of salinity are dimensionless and the units attribute should normally be given as 1e-3 or 0.001 i.e. parts per thousand. ", "dimensions": "longitude latitude time", "out_name": "sossq", "type": "real", @@ -4163,13 +4353,14 @@ "ok_max_mean_abs": "" }, "spco2": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "surface_partial_pressure_of_carbon_dioxide_in_sea_water", "units": "Pa", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", "long_name": "Surface Aqueous Partial Pressure of CO2", - "comment": "", + "comment": "The surface called 'surface' means the lower boundary of the atmosphere. The partial pressure of a dissolved gas in sea water is the partial pressure in air with which it would be in equilibrium. The partial pressure of a gaseous constituent of air is the pressure which it alone would exert with unchanged temperature and number of moles per unit volume. The chemical formula for carbon dioxide is CO2.", "dimensions": "longitude latitude time depth0m", "out_name": "spco2", "type": "real", @@ -4180,13 +4371,14 @@ "ok_max_mean_abs": "" }, "spco2abio": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_partial_pressure_of_carbon_dioxide_in_sea_water_due_to_abiotic_component", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "surface_carbon_dioxide_abiotic_analogue_partial_pressure_difference_between_sea_water_and_air", "units": "Pa", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", "long_name": "Abiotic Surface Aqueous Partial Pressure of CO2", - "comment": "", + "comment": "The surface called 'surface' means the lower boundary of the atmosphere. The chemical formula for carbon dioxide is CO2. In ocean biogeochemistry models, an 'abiotic analogue' is used to simulate the effect on a modelled variable when biological effects on ocean carbon concentration and alkalinity are ignored. The partial pressure of a gaseous constituent of air is the pressure which it alone would exert with unchanged temperature and number of moles per unit volume. The partial pressure of a dissolved gas in sea water is the partial pressure in air with which it would be in equilibrium. The partial pressure difference between sea water and air is positive when the partial pressure of the dissolved gas in sea water is greater than the partial pressure in air.", "dimensions": "longitude latitude time depth0m", "out_name": "spco2abio", "type": "real", @@ -4197,13 +4389,14 @@ "ok_max_mean_abs": "" }, "spco2nat": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_partial_pressure_of_carbon_dioxide_in_sea_water_due_to_natural_component", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "surface_carbon_dioxide_natural_analogue_partial_pressure_difference_between_sea_water_and_air", "units": "Pa", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", "long_name": "Natural Surface Aqueous Partial Pressure of CO2", - "comment": "", + "comment": "The surface called 'surface' means the lower boundary of the atmosphere. The chemical formula for carbon dioxide is CO2. In ocean biogeochemistry models, a 'natural analogue' is used to simulate the effect on a modelled variable of imposing preindustrial atmospheric carbon dioxide concentrations, even when the model as a whole may be subjected to varying forcings. The partial pressure of a gaseous constituent of air is the pressure which it alone would exert with unchanged temperature and number of moles per unit volume. The partial pressure of a dissolved gas in sea water is the partial pressure in air with which it would be in equilibrium. The partial pressure difference between sea water and air is positive when the partial pressure of the dissolved gas in sea water is greater than the partial pressure in air.", "dimensions": "longitude latitude time depth0m", "out_name": "spco2nat", "type": "real", @@ -4214,14 +4407,15 @@ "ok_max_mean_abs": "" }, "talk": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "sea_water_alkalinity_expressed_as_mole_equivalent", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", + "cell_measures": "area: areacello volume: volcello", "long_name": "Total Alkalinity", "comment": "total alkalinity equivalent concentration (including carbonate, nitrogen, silicate, and borate components)", - "dimensions": "longitude latitude time depth0m", + "dimensions": "longitude latitude olevel time", "out_name": "talk", "type": "real", "positive": "", @@ -4231,14 +4425,15 @@ "ok_max_mean_abs": "" }, "talknat": { - "modeling_realm": "ocnBgChem", - "standard_name": "seawater_alkalinity_expressed_as_mole_equivalent_natural_component", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "sea_water_alkalinity_natural_analogue_expressed_as_mole_equivalent", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", + "cell_measures": "area: areacello volume: volcello", "long_name": "Natural Total Alkalinity", "comment": "total alkalinity equivalent concentration (including carbonate, borate, phosphorus, silicon, and nitrogen components) at preindustrial atmospheric xCO2", - "dimensions": "longitude latitude time depth0m", + "dimensions": "longitude latitude olevel time", "out_name": "talknat", "type": "real", "positive": "", @@ -4248,8 +4443,9 @@ "ok_max_mean_abs": "" }, "talknatos": { - "modeling_realm": "ocnBgChem", - "standard_name": "sea_water_alkalinity_expressed_as_mole_equivalent_due_to_natural_component", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "sea_water_alkalinity_natural_analogue_expressed_as_mole_equivalent", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", @@ -4265,7 +4461,8 @@ "ok_max_mean_abs": "" }, "talkos": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "sea_water_alkalinity_expressed_as_mole_equivalent", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", @@ -4282,6 +4479,7 @@ "ok_max_mean_abs": "" }, "tauucorr": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "surface_downward_x_stress_correction", "units": "N m-2", @@ -4299,6 +4497,7 @@ "ok_max_mean_abs": "" }, "tauuo": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "surface_downward_x_stress", "units": "N m-2", @@ -4316,6 +4515,7 @@ "ok_max_mean_abs": "" }, "tauvcorr": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "surface_downward_y_stress_correction", "units": "N m-2", @@ -4333,6 +4533,7 @@ "ok_max_mean_abs": "" }, "tauvo": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "surface_downward_y_stress", "units": "N m-2", @@ -4350,6 +4551,7 @@ "ok_max_mean_abs": "" }, "thetao": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "sea_water_potential_temperature", "units": "degC", @@ -4367,6 +4569,7 @@ "ok_max_mean_abs": "" }, "thetaoga": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "sea_water_potential_temperature", "units": "degC", @@ -4384,13 +4587,14 @@ "ok_max_mean_abs": "" }, "thkcello": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "cell_thickness", "units": "m", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", "long_name": "Ocean Model Cell Thickness", - "comment": "", + "comment": "'Thickness' means the vertical extent of a layer. 'Cell' refers to a model grid-cell.", "dimensions": "longitude latitude olevel time", "out_name": "thkcello", "type": "real", @@ -4401,6 +4605,7 @@ "ok_max_mean_abs": "" }, "tob": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "sea_water_potential_temperature_at_sea_floor", "units": "degC", @@ -4418,13 +4623,14 @@ "ok_max_mean_abs": "" }, "tos": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "sea_surface_temperature", - "units": "K", + "units": "degC", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", "long_name": "Sea Surface Temperature", - "comment": "temperature of liquid ocean. Note that the correct standard_name for this variable is 'sea_surface_temperature', not 'surface_temperature', but this was discovered too late to correct. To maintain consistency across CMIP5 models, the wrong standard_name will continue to be used.", + "comment": "Temperature of upper boundary of the liquid ocean, including temperatures below sea-ice and floating ice shelves.", "dimensions": "longitude latitude time", "out_name": "tos", "type": "real", @@ -4435,13 +4641,14 @@ "ok_max_mean_abs": "" }, "tosga": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "sea_surface_temperature", "units": "degC", "cell_methods": "area: mean where sea time: mean", "cell_measures": "", "long_name": "Global Average Sea Surface Temperature", - "comment": "This may differ from 'surface temperature' in regions of sea ice.This may differ from 'surface temperature' in regions of sea ice.For models using conservative temperature as prognostic field, they should report the SST as surface potent", + "comment": "Temperature of upper boundary of the liquid ocean, including temperatures below sea-ice and floating ice shelves.", "dimensions": "time", "out_name": "tosga", "type": "real", @@ -4452,13 +4659,14 @@ "ok_max_mean_abs": "" }, "tossq": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "square_of_sea_surface_temperature", "units": "degC2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", "long_name": "Square of Sea Surface Temperature", - "comment": "square of temperature of liquid ocean, averaged over the day.", + "comment": "Square of temperature of liquid ocean.", "dimensions": "longitude latitude time", "out_name": "tossq", "type": "real", @@ -4469,6 +4677,7 @@ "ok_max_mean_abs": "" }, "umo": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "ocean_mass_x_transport", "units": "kg s-1", @@ -4486,6 +4695,7 @@ "ok_max_mean_abs": "" }, "uo": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "sea_water_x_velocity", "units": "m s-1", @@ -4503,6 +4713,7 @@ "ok_max_mean_abs": "" }, "vmo": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "ocean_mass_y_transport", "units": "kg s-1", @@ -4520,13 +4731,14 @@ "ok_max_mean_abs": "" }, "vo": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "sea_water_y_velocity", "units": "m s-1", "cell_methods": "time: mean", "cell_measures": "--OPT", "long_name": "Sea Water Y Velocity", - "comment": "Prognostic x-ward velocity component resolved by the model.", + "comment": "Prognostic y-ward velocity component resolved by the model.", "dimensions": "longitude latitude olevel time", "out_name": "vo", "type": "real", @@ -4536,14 +4748,33 @@ "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, + "volcello": { + "frequency": "mon", + "modeling_realm": "ocean", + "standard_name": "ocean_volume", + "units": "m3", + "cell_methods": "area: mean where sea time: mean", + "cell_measures": "area: areacello volume: volcello", + "long_name": "Ocean Grid-Cell Volume", + "comment": "grid-cell volume ca. 2000.", + "dimensions": "longitude latitude olevel time", + "out_name": "volcello", + "type": "real", + "positive": "", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, "volo": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "sea_water_volume", "units": "m3", "cell_methods": "area: sum where sea time: mean", "cell_measures": "", "long_name": "Sea Water Volume", - "comment": "Total volume of liquid seawater.", + "comment": "Total volume of liquid sea water.", "dimensions": "time", "out_name": "volo", "type": "real", @@ -4554,6 +4785,7 @@ "ok_max_mean_abs": "" }, "vsf": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "virtual_salt_flux_into_sea_water", "units": "kg m-2 s-1", @@ -4571,6 +4803,7 @@ "ok_max_mean_abs": "" }, "vsfcorr": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "virtual_salt_flux_correction", "units": "kg m-2 s-1", @@ -4588,12 +4821,13 @@ "ok_max_mean_abs": "" }, "vsfevap": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "virtual_salt_flux_into_sea_water_due_to_evaporation", "units": "kg m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Virtual Salt Flux into Sea Water due to Evaporation", + "long_name": "Virtual Salt Flux into Sea Water Due to Evaporation", "comment": "zero for models using real water fluxes.", "dimensions": "longitude latitude time", "out_name": "vsfevap", @@ -4605,12 +4839,13 @@ "ok_max_mean_abs": "" }, "vsfpr": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "virtual_salt_flux_into_sea_water_due_to_rainfall", "units": "kg m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Virtual Salt Flux into Sea Water due to Rainfall", + "long_name": "Virtual Salt Flux into Sea Water Due to Rainfall", "comment": "zero for models using real water fluxes.", "dimensions": "longitude latitude time", "out_name": "vsfpr", @@ -4622,12 +4857,13 @@ "ok_max_mean_abs": "" }, "vsfriver": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "virtual_salt_flux_into_sea_water_from_rivers", "units": "kg m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Virtual Salt Flux into Sea Water From Rivers", + "long_name": "Virtual Salt Flux into Sea Water from Rivers", "comment": "zero for models using real water fluxes.", "dimensions": "longitude latitude time", "out_name": "vsfriver", @@ -4639,12 +4875,13 @@ "ok_max_mean_abs": "" }, "vsfsit": { + "frequency": "mon", "modeling_realm": "ocean seaIce", "standard_name": "virtual_salt_flux_into_sea_water_due_to_sea_ice_thermodynamics", "units": "kg m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Virtual Salt Flux into Sea Water due to Sea Ice Thermodynamics", + "long_name": "Virtual Salt Flux into Sea Water Due to Sea Ice Thermodynamics", "comment": "This variable measures the virtual salt flux into sea water due to the melting of sea ice. It is set to zero in models which receive a real water flux.", "dimensions": "longitude latitude time", "out_name": "vsfsit", @@ -4656,6 +4893,7 @@ "ok_max_mean_abs": "" }, "wfcorr": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "water_flux_correction", "units": "kg m-2 s-1", @@ -4673,6 +4911,7 @@ "ok_max_mean_abs": "" }, "wfo": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "water_flux_into_sea_water", "units": "kg m-2 s-1", @@ -4690,6 +4929,7 @@ "ok_max_mean_abs": "" }, "wfonocorr": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "water_flux_into_sea_water_without_flux_correction", "units": "kg m-2 s-1", @@ -4707,6 +4947,7 @@ "ok_max_mean_abs": "" }, "wmo": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "upward_ocean_mass_transport", "units": "kg s-1", @@ -4724,13 +4965,14 @@ "ok_max_mean_abs": "" }, "wo": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "upward_sea_water_velocity", "units": "m s-1", "cell_methods": "time: mean", "cell_measures": "--OPT", - "long_name": "Sea Water Z Velocity", - "comment": "", + "long_name": "Sea Water Vertical Velocity", + "comment": "A velocity is a vector quantity. 'Upward' indicates a vector component which is positive when directed upward (negative downward).", "dimensions": "longitude latitude olevel time", "out_name": "wo", "type": "real", @@ -4741,6 +4983,7 @@ "ok_max_mean_abs": "" }, "zfullo": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "depth_below_geoid", "units": "m", @@ -4758,14 +5001,15 @@ "ok_max_mean_abs": "" }, "zhalfo": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "depth_below_geoid", "units": "m", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello volume: volcello", + "cell_measures": "area: areacello", "long_name": "Depth Below Geoid of Interfaces Between Ocean Layers", "comment": "Depth below geoid", - "dimensions": "longitude latitude olevel time", + "dimensions": "longitude latitude olevhalf time", "out_name": "zhalfo", "type": "real", "positive": "", @@ -4775,14 +5019,15 @@ "ok_max_mean_abs": "" }, "zmeso": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_mesozooplankton_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", - "long_name": "Mole Concentration of Mesozooplankton expressed as Carbon in sea water", + "cell_measures": "area: areacello volume: volcello", + "long_name": "Mole Concentration of Mesozooplankton Expressed as Carbon in Sea Water", "comment": "carbon concentration from mesozooplankton (20-200 um) component alone", - "dimensions": "longitude latitude time depth0m", + "dimensions": "longitude latitude olevel time", "out_name": "zmeso", "type": "real", "positive": "", @@ -4792,12 +5037,13 @@ "ok_max_mean_abs": "" }, "zmesoos": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_mole_concentration_of_mesozooplankton_expressed_as_carbon_in_sea_water", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_mesozooplankton_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Surface Mole Concentration of Mesozooplankton expressed as Carbon in Sea Water", + "long_name": "Surface Mole Concentration of Mesozooplankton Expressed as Carbon in Sea Water", "comment": "carbon concentration from mesozooplankton (20-200 um) component alone", "dimensions": "longitude latitude time", "out_name": "zmesoos", @@ -4809,14 +5055,15 @@ "ok_max_mean_abs": "" }, "zmicro": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_microzooplankton_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", - "long_name": "Mole Concentration of Microzooplankton expressed as Carbon in sea water", + "cell_measures": "area: areacello volume: volcello", + "long_name": "Mole Concentration of Microzooplankton Expressed as Carbon in Sea Water", "comment": "carbon concentration from the microzooplankton (<20 um) component alone", - "dimensions": "longitude latitude time depth0m", + "dimensions": "longitude latitude olevel time", "out_name": "zmicro", "type": "real", "positive": "", @@ -4826,12 +5073,13 @@ "ok_max_mean_abs": "" }, "zmicroos": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_mole_concentration_of_microzooplankton_expressed_as_carbon_in_sea_water", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_microzooplankton_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Surface Mole Concentration of Microzooplankton expressed as Carbon in Sea Water", + "long_name": "Surface Mole Concentration of Microzooplankton Expressed as Carbon in Sea Water", "comment": "carbon concentration from the microzooplankton (<20 um) component alone", "dimensions": "longitude latitude time", "out_name": "zmicroos", @@ -4843,14 +5091,15 @@ "ok_max_mean_abs": "" }, "zmisc": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_miscellaneous_zooplankton_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", - "long_name": "Mole Concetration of Other Zooplankton expressed as Carbon in sea water", + "cell_measures": "area: areacello volume: volcello", + "long_name": "Mole Concentration of Other Zooplankton Expressed as Carbon in Sea Water", "comment": "carbon from additional zooplankton component concentrations alone (e.g. Micro, meso). Since the models all have different numbers of components, this variable has been included to provide a check for intercomparison between models since some phytoplankton groups are supersets.", - "dimensions": "longitude latitude time depth0m", + "dimensions": "longitude latitude olevel time", "out_name": "zmisc", "type": "real", "positive": "", @@ -4860,12 +5109,13 @@ "ok_max_mean_abs": "" }, "zmiscos": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_mole_concentration_of_miscellaneous_zooplankton_expressed_as_carbon_in_sea_water", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_miscellaneous_zooplankton_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Surface Mole Concentraiton of Other Zooplankton expressed as Carbon in sea water", + "long_name": "Surface Mole Concentration of Other Zooplankton Expressed as Carbon in Sea Water", "comment": "carbon from additional zooplankton component concentrations alone (e.g. Micro, meso). Since the models all have different numbers of components, this variable has been included to provide a check for intercomparison between models since some phytoplankton groups are supersets.", "dimensions": "longitude latitude time", "out_name": "zmiscos", @@ -4877,7 +5127,8 @@ "ok_max_mean_abs": "" }, "zo2min": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "depth_at_shallowest_local_minimum_in_vertical_profile_of_mole_concentration_of_dissolved_molecular_oxygen_in_sea_water", "units": "m", "cell_methods": "area: mean where sea time: mean", @@ -4894,14 +5145,15 @@ "ok_max_mean_abs": "" }, "zooc": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_zooplankton_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello", + "cell_measures": "area: areacello volume: volcello", "long_name": "Zooplankton Carbon Concentration", "comment": "sum of zooplankton carbon component concentrations", - "dimensions": "longitude latitude time depth0m", + "dimensions": "longitude latitude olevel time", "out_name": "zooc", "type": "real", "positive": "", @@ -4911,8 +5163,9 @@ "ok_max_mean_abs": "" }, "zoocos": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_mole_concentration_of_zooplankton_expressed_as_carbon_in_sea_water", + "frequency": "mon", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_zooplankton_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", @@ -4928,6 +5181,7 @@ "ok_max_mean_abs": "" }, "zos": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "sea_surface_height_above_geoid", "units": "m", @@ -4945,6 +5199,7 @@ "ok_max_mean_abs": "" }, "zossq": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "square_of_sea_surface_height_above_geoid", "units": "m2", @@ -4962,6 +5217,7 @@ "ok_max_mean_abs": "" }, "zostoga": { + "frequency": "mon", "modeling_realm": "ocean", "standard_name": "global_average_thermosteric_sea_level_change", "units": "m", @@ -4979,7 +5235,8 @@ "ok_max_mean_abs": "" }, "zsatarag": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "minimum_depth_of_aragonite_undersaturation_in_sea_water", "units": "m", "cell_methods": "area: mean where sea time: mean", @@ -4996,7 +5253,8 @@ "ok_max_mean_abs": "" }, "zsatcalc": { - "modeling_realm": "ocnBgChem", + "frequency": "mon", + "modeling_realm": "ocnBgchem", "standard_name": "minimum_depth_of_calcite_undersaturation_in_sea_water", "units": "m", "cell_methods": "area: mean where sea time: mean", diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Oyr.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Oyr.json index 90e6de9fd0..795091883c 100644 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Oyr.json +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_Oyr.json @@ -1,21 +1,22 @@ { "Header": { - "data_specs_version": "01.00.10", + "data_specs_version": "01.00.30", + "cmor_version": "3.4", "table_id": "Table Oyr", - "realm": "ocnBgChem", - "frequency": "yr", - "cmor_version": "3.2", - "table_date": "10 May 2017", + "realm": "ocnBgchem", + "table_date": "11 March 2019", "missing_value": "1e20", + "int_missing_value": "-999", "product": "model-output", "approx_interval": "365.00000", "generic_levels": "olevel", "mip_era": "CMIP6", - "Conventions": "CF-1.7 CMIP-6.0" + "Conventions": "CF-1.7 CMIP-6.2" }, "variable_entry": { "arag": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_aragonite_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", @@ -32,7 +33,8 @@ "ok_max_mean_abs": "" }, "bacc": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_bacteria_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", @@ -49,12 +51,13 @@ "ok_max_mean_abs": "" }, "bddtalk": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_sea_water_alkalinity_expressed_as_mole_equivalent_due_to_biological_processes", "units": "mol m-3 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Rate of Change of Alkalinity due to Biological Activity", + "long_name": "Rate of Change of Alkalinity Due to Biological Activity", "comment": "Net total of biological terms in time rate of change of alkalinity", "dimensions": "longitude latitude olevel time", "out_name": "bddtalk", @@ -66,12 +69,13 @@ "ok_max_mean_abs": "" }, "bddtdic": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_mole_concentration_of_dissolved_inorganic_carbon_in_sea_water_due_to_biological_processes", "units": "mol m-3 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Rate of Change of Dissolved Inorganic Carbon due to Biological Activity", + "long_name": "Rate of Change of Dissolved Inorganic Carbon Due to Biological Activity", "comment": "Net total of biological terms in time rate of change of dissolved inorganic carbon", "dimensions": "longitude latitude olevel time", "out_name": "bddtdic", @@ -83,12 +87,13 @@ "ok_max_mean_abs": "" }, "bddtdife": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_mole_concentration_of_dissolved_inorganic_iron_in_sea_water_due_to_biological_processes", "units": "mol m-3 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Rate of Change of Dissolved Inorganic Iron due to Biological Activity", + "long_name": "Rate of Change of Dissolved Inorganic Iron Due to Biological Activity", "comment": "Net total of biological terms in time rate of change of dissolved inorganic iron", "dimensions": "longitude latitude olevel time", "out_name": "bddtdife", @@ -100,12 +105,13 @@ "ok_max_mean_abs": "" }, "bddtdin": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_mole_concentration_of_dissolved_inorganic_nitrogen_in_sea_water_due_to_biological_processes", "units": "mol m-3 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Rate of Change of Nitrogen Nutrient due to Biological Activity", + "long_name": "Rate of Change of Nitrogen Nutrient Due to Biological Activity", "comment": "Net total of biological terms in time rate of change of nitrogen nutrients (e.g. NO3+NH4)", "dimensions": "longitude latitude olevel time", "out_name": "bddtdin", @@ -117,12 +123,13 @@ "ok_max_mean_abs": "" }, "bddtdip": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_mole_concentration_of_dissolved_inorganic_phosphorus_in_sea_water_due_to_biological_processes", "units": "mol m-3 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Rate of Change of Dissolved phosphorus due to Biological Activity", + "long_name": "Rate of Change of Dissolved Phosphorus Due to Biological Activity", "comment": "Net of biological terms in time rate of change of dissolved phosphate", "dimensions": "longitude latitude olevel time", "out_name": "bddtdip", @@ -134,12 +141,13 @@ "ok_max_mean_abs": "" }, "bddtdisi": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_mole_concentration_of_dissolved_inorganic_silicon_in_sea_water_due_to_biological_processes", "units": "mol m-3 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Rate of Change of Dissolved Inorganic silicon due to Biological Activity", + "long_name": "Rate of Change of Dissolved Inorganic Silicon Due to Biological Activity", "comment": "Net of biological terms in time rate of change of dissolved inorganic silicon", "dimensions": "longitude latitude olevel time", "out_name": "bddtdisi", @@ -151,12 +159,13 @@ "ok_max_mean_abs": "" }, "bfe": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_particulate_organic_matter_expressed_as_iron_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Mole Concentration of Particulate Organic Matter expressed as Iron in sea water", + "long_name": "Mole Concentration of Particulate Organic Matter Expressed as Iron in Sea Water", "comment": "Sum of particulate organic iron component concentrations", "dimensions": "longitude latitude olevel time", "out_name": "bfe", @@ -168,12 +177,13 @@ "ok_max_mean_abs": "" }, "bsi": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_particulate_matter_expressed_as_silicon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Mole Concentration of Particulate Organic Matter expressed as silicon in sea water", + "long_name": "Mole Concentration of Particulate Organic Matter Expressed as Silicon in Sea Water", "comment": "Sum of particulate silica component concentrations", "dimensions": "longitude latitude olevel time", "out_name": "bsi", @@ -185,7 +195,8 @@ "ok_max_mean_abs": "" }, "calc": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_calcite_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", @@ -202,13 +213,14 @@ "ok_max_mean_abs": "" }, "cfc11": { + "frequency": "yr", "modeling_realm": "ocean", "standard_name": "mole_concentration_of_cfc11_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Mole Concentration of CFC-11 in sea water", - "comment": "", + "long_name": "Mole Concentration of CFC11 in Sea Water", + "comment": "Mole concentration means number of moles per unit volume, also called 'molarity', and is used in the construction 'mole_concentration_of_X_in_Y', where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula of CFC11 is CFCl3. The IUPAC name for CFC11 is trichloro-fluoro-methane.", "dimensions": "longitude latitude olevel time", "out_name": "cfc11", "type": "real", @@ -219,13 +231,14 @@ "ok_max_mean_abs": "" }, "cfc12": { + "frequency": "yr", "modeling_realm": "ocean", "standard_name": "mole_concentration_of_cfc12_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Mole Concentration of CFC-12 in sea water", - "comment": "", + "long_name": "Mole Concentration of CFC12 in Sea Water", + "comment": "Mole concentration means number of moles per unit volume, also called 'molarity', and is used in the construction 'mole_concentration_of_X_in_Y', where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for CFC12 is CF2Cl2. The IUPAC name for CFC12 is dichloro-difluoro-methane.", "dimensions": "longitude latitude olevel time", "out_name": "cfc12", "type": "real", @@ -236,12 +249,13 @@ "ok_max_mean_abs": "" }, "chl": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "mass_concentration_of_phytoplankton_expressed_as_chlorophyll_in_sea_water", "units": "kg m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Mass Concentration of Total Chlorophyll in sea water", + "long_name": "Mass Concentration of Total Phytoplankton Expressed as Chlorophyll in Sea Water", "comment": "Sum of chlorophyll from all phytoplankton group concentrations. In most models this is equal to chldiat+chlmisc, that is the sum of Diatom Chlorophyll Mass Concentration and Other Phytoplankton Chlorophyll Mass Concentration", "dimensions": "longitude latitude olevel time", "out_name": "chl", @@ -253,12 +267,13 @@ "ok_max_mean_abs": "" }, "chlcalc": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "mass_concentration_of_calcareous_phytoplankton_expressed_as_chlorophyll_in_sea_water", "units": "kg m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Mass Concentration of Calcareous Phytoplankton expressed as Chlorophyll in sea water", + "long_name": "Mass Concentration of Calcareous Phytoplankton Expressed as Chlorophyll in Sea Water", "comment": "chlorophyll concentration from the calcite-producing phytoplankton component alone", "dimensions": "longitude latitude olevel time", "out_name": "chlcalc", @@ -270,12 +285,13 @@ "ok_max_mean_abs": "" }, "chldiat": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "mass_concentration_of_diatoms_expressed_as_chlorophyll_in_sea_water", "units": "kg m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Mass Concentration of Diatom expressed as Chlorophyll in sea water", + "long_name": "Mass Concentration of Diatoms Expressed as Chlorophyll in Sea Water", "comment": "Chlorophyll from diatom phytoplankton component concentration alone", "dimensions": "longitude latitude olevel time", "out_name": "chldiat", @@ -287,12 +303,13 @@ "ok_max_mean_abs": "" }, "chldiaz": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "mass_concentration_of_diazotrophs_expressed_as_chlorophyll_in_sea_water", "units": "kg m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Mass Concentration of Diazotrophs expressed as Chlorophyll in sea water", + "long_name": "Mass Concentration of Diazotrophs Expressed as Chlorophyll in Sea Water", "comment": "Chlorophyll concentration from the diazotrophic phytoplankton component alone", "dimensions": "longitude latitude olevel time", "out_name": "chldiaz", @@ -304,12 +321,13 @@ "ok_max_mean_abs": "" }, "chlmisc": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "mass_concentration_of_miscellaneous_phytoplankton_expressed_as_chlorophyll_in_sea_water", "units": "kg m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Mass Concentration of Other Phytoplankton expressed as Chlorophyll in sea water", + "long_name": "Mass Concentration of Other Phytoplankton Expressed as Chlorophyll in Sea Water", "comment": "Chlorophyll from additional phytoplankton component concentrations alone", "dimensions": "longitude latitude olevel time", "out_name": "chlmisc", @@ -321,12 +339,13 @@ "ok_max_mean_abs": "" }, "chlpico": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "mass_concentration_of_picophytoplankton_expressed_as_chlorophyll_in_sea_water", "units": "kg m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Mass Concentration of Picophytoplankton expressed as Chlorophyll in sea water", + "long_name": "Mass Concentration of Picophytoplankton Expressed as Chlorophyll in Sea Water", "comment": "chlorophyll concentration from the picophytoplankton (<2 um) component alone", "dimensions": "longitude latitude olevel time", "out_name": "chlpico", @@ -338,13 +357,14 @@ "ok_max_mean_abs": "" }, "co3": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_carbonate_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Carbonate ion Concentration", - "comment": "", + "long_name": "Carbonate Ion Concentration", + "comment": "Mole concentration (number of moles per unit volume: molarity) of the carbonate anion (CO3).", "dimensions": "longitude latitude olevel time", "out_name": "co3", "type": "real", @@ -355,13 +375,14 @@ "ok_max_mean_abs": "" }, "co3abio": { - "modeling_realm": "ocnBgChem", - "standard_name": "mole_concentration_of_carbonate_expressed_as_carbon_in_sea_water_due_to_abiotic_component", + "frequency": "yr", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_carbonate_abiotic_analogue_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Abiotic Carbonate ion Concentration", - "comment": "", + "long_name": "Abiotic Carbonate Ion Concentration", + "comment": "Mole concentration (number of moles per unit volume: molarity) of the abiotic-analogue carbonate anion (CO3). An abiotic analogue is used to simulate the effect on a modelled variable when biological effects on ocean carbon concentration and alkalinity are ignored. ", "dimensions": "longitude latitude olevel time", "out_name": "co3abio", "type": "real", @@ -372,13 +393,14 @@ "ok_max_mean_abs": "" }, "co3nat": { - "modeling_realm": "ocnBgChem", - "standard_name": "mole_concentration_of_carbonate_expressed_as_carbon_in_sea_water_due_to_natural_component", + "frequency": "yr", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_carbonate_natural_analogue_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Natural Carbonate ion Concentration", - "comment": "", + "long_name": "Natural Carbonate Ion Concentration", + "comment": "Surface mole concentration (number of moles per unit volume: molarity) of the natural-analogue carbonate anion (CO3). A natural analogue is used to simulate the effect on a modelled variable of imposing preindustrial atmospheric carbon dioxide concentrations, even when the model as a whole may be subjected to varying forcings. ", "dimensions": "longitude latitude olevel time", "out_name": "co3nat", "type": "real", @@ -389,13 +411,14 @@ "ok_max_mean_abs": "" }, "co3satarag": { - "modeling_realm": "ocnBgChem", - "standard_name": "mole_concentration_of_aragonite_expressed_as_carbon_in_sea_water_at_saturation", + "frequency": "yr", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_carbonate_expressed_as_carbon_at_equilibrium_with_pure_aragonite_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Carbonate ion Concentration for sea water in equilibrium with pure Aragonite", - "comment": "", + "long_name": "Mole Concentration of Carbonate Ion in Equilibrium with Pure Aragonite in Sea Water", + "comment": "Mole concentration (number of moles per unit volume: molarity) of the carbonate anion (CO3) for sea water in equilibrium with pure Aragonite. Aragonite (CaCO3) is a mineral that is a polymorph of calcium carbonate.", "dimensions": "longitude latitude olevel time", "out_name": "co3satarag", "type": "real", @@ -406,13 +429,14 @@ "ok_max_mean_abs": "" }, "co3satcalc": { - "modeling_realm": "ocnBgChem", - "standard_name": "mole_concentration_of_calcite_expressed_as_carbon_in_sea_water_at_saturation", + "frequency": "yr", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_carbonate_expressed_as_carbon_at_equilibrium_with_pure_calcite_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Carbonate ion Concentration for sea water in equilibrium with pure Calcite", - "comment": "", + "long_name": "Mole Concentration of Carbonate Ion in Equilibrium with Pure Calcite in Sea Water", + "comment": "Mole concentration (number of moles per unit volume: molarity) of the carbonate anion (CO3) for sea water in equilibrium with pure calcite. Aragonite (CaCO3) is a mineral that is a polymorph of calcium carbonate.", "dimensions": "longitude latitude olevel time", "out_name": "co3satcalc", "type": "real", @@ -423,7 +447,8 @@ "ok_max_mean_abs": "" }, "darag": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_mole_concentration_of_aragonite_expressed_as_carbon_in_sea_water_due_to_dissolution", "units": "mol m-3 s-1", "cell_methods": "area: mean where sea time: mean", @@ -440,7 +465,8 @@ "ok_max_mean_abs": "" }, "dcalc": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_mole_concentration_of_calcite_expressed_as_carbon_in_sea_water_due_to_dissolution", "units": "mol m-3 s-1", "cell_methods": "area: mean where sea time: mean", @@ -457,7 +483,8 @@ "ok_max_mean_abs": "" }, "detoc": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_organic_detritus_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", @@ -474,12 +501,13 @@ "ok_max_mean_abs": "" }, "dfe": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_dissolved_iron_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Mole Concentration of Dissolved Iron in sea water", + "long_name": "Dissolved Iron Concentration", "comment": "Dissolved iron in sea water, including both Fe2+ and Fe3+ ions (but not particulate detrital iron)", "dimensions": "longitude latitude olevel time", "out_name": "dfe", @@ -491,13 +519,14 @@ "ok_max_mean_abs": "" }, "difmxybo": { + "frequency": "yr", "modeling_realm": "ocean", "standard_name": "ocean_momentum_xy_biharmonic_diffusivity", "units": "m4 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "ocean momentum xy biharmonic diffusivity", - "comment": "Lateral biharmonic viscosity applied to the momentum equitions.", + "long_name": "Ocean Momentum XY Biharmonic Diffusivity", + "comment": "Lateral biharmonic viscosity applied to the momentum equations.", "dimensions": "longitude latitude olevel time", "out_name": "difmxybo", "type": "real", @@ -508,13 +537,14 @@ "ok_max_mean_abs": "" }, "difmxylo": { + "frequency": "yr", "modeling_realm": "ocean", "standard_name": "ocean_momentum_xy_laplacian_diffusivity", "units": "m2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "ocean momentum xy laplacian diffusivity", - "comment": "Lateral Laplacian viscosity applied to the momentum equitions.", + "long_name": "Ocean Momentum XY Laplacian Diffusivity", + "comment": "Lateral Laplacian viscosity applied to the momentum equations.", "dimensions": "longitude latitude olevel time", "out_name": "difmxylo", "type": "real", @@ -525,12 +555,13 @@ "ok_max_mean_abs": "" }, "diftrblo": { + "frequency": "yr", "modeling_realm": "ocean", - "standard_name": "ocean_tracer_bolus_laplacian_diffusivity", + "standard_name": "ocean_tracer_laplacian_diffusivity_due_to_parameterized_mesoscale_eddy_advection", "units": "m2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "ocean tracer diffusivity due to parameterized mesoscale advection", + "long_name": "Ocean Tracer Diffusivity Due to Parameterized Mesoscale Advection", "comment": "Ocean tracer diffusivity associated with parameterized eddy-induced advective transport. Sometimes this diffusivity is called the 'thickness' diffusivity. For CMIP5, this diagnostic was called 'ocean tracer bolus laplacian diffusivity'. The CMIP6 name is physically more relevant.", "dimensions": "longitude latitude olevel time", "out_name": "diftrblo", @@ -542,12 +573,13 @@ "ok_max_mean_abs": "" }, "diftrelo": { + "frequency": "yr", "modeling_realm": "ocean", "standard_name": "ocean_tracer_epineutral_laplacian_diffusivity", "units": "m2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "ocean tracer epineutral laplacian diffusivity", + "long_name": "Ocean Tracer Epineutral Laplacian Diffusivity", "comment": "Ocean tracer diffusivity associated with parameterized eddy-induced diffusive transport oriented along neutral or isopycnal directions. Sometimes this diffusivity is called the neutral diffusivity or isopycnal diffusivity or Redi diffusivity.", "dimensions": "longitude latitude olevel time", "out_name": "diftrelo", @@ -559,12 +591,13 @@ "ok_max_mean_abs": "" }, "difvho": { + "frequency": "yr", "modeling_realm": "ocean", "standard_name": "ocean_vertical_heat_diffusivity", "units": "m2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "ocean vertical heat diffusivity", + "long_name": "Ocean Vertical Heat Diffusivity", "comment": "Vertical/dianeutral diffusivity applied to prognostic temperature field.", "dimensions": "longitude latitude olevel time", "out_name": "difvho", @@ -576,12 +609,13 @@ "ok_max_mean_abs": "" }, "difvso": { + "frequency": "yr", "modeling_realm": "ocean", "standard_name": "ocean_vertical_salt_diffusivity", "units": "m2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "ocean vertical salt diffusivity", + "long_name": "Ocean Vertical Salt Diffusivity", "comment": "Vertical/dianeutral diffusivity applied to prognostic salinity field.", "dimensions": "longitude latitude olevel time", "out_name": "difvso", @@ -593,12 +627,13 @@ "ok_max_mean_abs": "" }, "dispkexyfo": { + "frequency": "yr", "modeling_realm": "ocean", "standard_name": "ocean_kinetic_energy_dissipation_per_unit_area_due_to_xy_friction", "units": "W m-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "ocean kinetic energy dissipation per unit area due to xy friction", + "long_name": "Ocean Kinetic Energy Dissipation per Unit Area Due to XY Friction", "comment": "Depth integrated impacts on kinetic energy arising from lateral frictional dissipation associated with Laplacian and/or biharmonic viscosity. For CMIP5, this diagnostic was 3d, whereas the CMIP6 depth integrated diagnostic is sufficient for many purposes and reduces archive requirements.", "dimensions": "longitude latitude time", "out_name": "dispkexyfo", @@ -610,13 +645,14 @@ "ok_max_mean_abs": "" }, "dissi13c": { - "modeling_realm": "ocnBgChem", - "standard_name": "mole_concentration_of_dissolved_inorganic_carbon13_in_sea_water", + "frequency": "yr", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_dissolved_inorganic_13C_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Dissolved Inorganic 13Carbon Concentration", - "comment": "Dissolved inorganic 14carbon (CO3+HCO3+H2CO3) concentration", + "long_name": "Dissolved Inorganic Carbon-13 Concentration", + "comment": "Dissolved inorganic carbon-13 (CO3+HCO3+H2CO3) concentration", "dimensions": "longitude latitude olevel time", "out_name": "dissi13c", "type": "real", @@ -627,13 +663,14 @@ "ok_max_mean_abs": "" }, "dissi14cabio": { - "modeling_realm": "ocnBgChem", - "standard_name": "mole_concentration_of_dissolved_inorganic_carbon14_in_sea_water", + "frequency": "yr", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_dissolved_inorganic_14C_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Abiotic Dissolved Inorganic 14Carbon Concentration", - "comment": "Abiotic Dissolved inorganic 14carbon (CO3+HCO3+H2CO3) concentration", + "long_name": "Abiotic Dissolved Inorganic Carbon-14 Concentration", + "comment": "Abiotic Dissolved inorganic carbon-14 (CO3+HCO3+H2CO3) concentration", "dimensions": "longitude latitude olevel time", "out_name": "dissi14cabio", "type": "real", @@ -644,7 +681,8 @@ "ok_max_mean_abs": "" }, "dissic": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_dissolved_inorganic_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", @@ -661,8 +699,9 @@ "ok_max_mean_abs": "" }, "dissicabio": { - "modeling_realm": "ocnBgChem", - "standard_name": "mole_concentration_of_dissolved_inorganic_carbon_in_sea_water_abiotic_component", + "frequency": "yr", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_dissolved_inorganic_carbon_abiotic_analogue_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", @@ -678,8 +717,9 @@ "ok_max_mean_abs": "" }, "dissicnat": { - "modeling_realm": "ocnBgChem", - "standard_name": "mole_concentration_of_dissolved_inorganic_carbon_in_sea_water_natural_component", + "frequency": "yr", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_dissolved_inorganic_carbon_natural_analogue_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", @@ -695,7 +735,8 @@ "ok_max_mean_abs": "" }, "dissoc": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_dissolved_organic_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", @@ -711,67 +752,17 @@ "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, - "dms": { - "modeling_realm": "ocnBgChem", - "standard_name": "mole_fraction_of_dimethyl_sulfide_in_air", - "units": "mol mol-1", - "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello volume: volcello", - "long_name": "Mole Concentration of Dimethyl Sulphide in sea water", - "comment": "", - "dimensions": "longitude latitude olevel time", - "out_name": "dms", - "type": "real", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "dpocdtcalc": { - "modeling_realm": "ocnBgChem", - "standard_name": "tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_calcareous_phytoplankton", - "units": "mol m-3 s-1", - "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello volume: volcello", - "long_name": "Tendency of Mole Concentration of Organic Carbon in sea water due to Net Primary Production by Calcareous Phytoplankton", - "comment": "Primary (organic carbon) production by the calcite-producing phytoplankton component alone", - "dimensions": "longitude latitude olevel time", - "out_name": "dpocdtcalc", - "type": "real", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "dpocdtdiaz": { - "modeling_realm": "ocnBgChem", - "standard_name": "tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_diazotrophs", - "units": "mol m-3 s-1", - "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello volume: volcello", - "long_name": "Tendency of Mole Concentration of Organic Carbon in sea water due to Net Primary Production by Diazotrophs", - "comment": "Primary (organic carbon) production by the diazotrophic phytoplankton component alone", - "dimensions": "longitude latitude olevel time", - "out_name": "dpocdtdiaz", - "type": "real", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "dpocdtpico": { - "modeling_realm": "ocnBgChem", - "standard_name": "tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_picophytoplankton", - "units": "mol m-3 s-1", + "dmso": { + "frequency": "yr", + "modeling_realm": "ocnBgchem", + "standard_name": "mole_concentration_of_dimethyl_sulfide_in_sea_water", + "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Tendency of Mole Concentration of Organic Carbon in sea water due to Net Primary Production by Picophytoplankton", - "comment": "Primary (organic carbon) production by the picophytoplankton (<2 um) component alone", + "long_name": "Mole Concentration of Dimethyl Sulphide in Sea Water", + "comment": "Mole concentration of dimethyl sulphide in water", "dimensions": "longitude latitude olevel time", - "out_name": "dpocdtpico", + "out_name": "dmso", "type": "real", "positive": "", "valid_min": "", @@ -780,12 +771,13 @@ "ok_max_mean_abs": "" }, "exparag": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "sinking_mole_flux_of_aragonite_expressed_as_carbon_in_sea_water", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Sinking Aragonite Flux", + "long_name": "Downward Flux of Aragonite", "comment": "Downward flux of Aragonite", "dimensions": "longitude latitude olevel time", "out_name": "exparag", @@ -797,12 +789,13 @@ "ok_max_mean_abs": "" }, "expc": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "sinking_mole_flux_of_particulate_organic_matter_expressed_as_carbon_in_sea_water", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Sinking Particulate Organic Carbon Flux", + "long_name": "Downward Flux of Particulate Organic Carbon", "comment": "Downward flux of particulate organic carbon", "dimensions": "longitude latitude olevel time", "out_name": "expc", @@ -814,12 +807,13 @@ "ok_max_mean_abs": "" }, "expcalc": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "sinking_mole_flux_of_calcite_expressed_as_carbon_in_sea_water", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Sinking Calcite Flux", + "long_name": "Downward Flux of Calcite", "comment": "Downward flux of Calcite", "dimensions": "longitude latitude olevel time", "out_name": "expcalc", @@ -831,13 +825,14 @@ "ok_max_mean_abs": "" }, "expfe": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "sinking_mole_flux_of_particulate_iron_in_sea_water", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", "long_name": "Sinking Particulate Iron Flux", - "comment": "", + "comment": "In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. 'Sinking' is the gravitational settling of particulate matter suspended in a liquid. A sinking flux is positive downwards and is calculated relative to the movement of the surrounding fluid.", "dimensions": "longitude latitude olevel time", "out_name": "expfe", "type": "real", @@ -848,13 +843,14 @@ "ok_max_mean_abs": "" }, "expn": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "sinking_mole_flux_of_particulate_organic_nitrogen_in_sea_water", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", "long_name": "Sinking Particulate Organic Nitrogen Flux", - "comment": "", + "comment": "In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. 'Sinking' is the gravitational settling of particulate matter suspended in a liquid. A sinking flux is positive downwards and is calculated relative to the movement of the surrounding fluid.", "dimensions": "longitude latitude olevel time", "out_name": "expn", "type": "real", @@ -865,13 +861,14 @@ "ok_max_mean_abs": "" }, "expp": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "sinking_mole_flux_of_particulate_organic_phosphorus_in_sea_water", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", "long_name": "Sinking Particulate Organic Phosphorus Flux", - "comment": "", + "comment": "In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. 'Sinking' is the gravitational settling of particulate matter suspended in a liquid. A sinking flux is positive downwards and is calculated relative to the movement of the surrounding fluid.", "dimensions": "longitude latitude olevel time", "out_name": "expp", "type": "real", @@ -882,13 +879,14 @@ "ok_max_mean_abs": "" }, "expsi": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "sinking_mole_flux_of_particulate_silicon_in_sea_water", "units": "mol m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Sinking Particulate Silica Flux", - "comment": "", + "long_name": "Sinking Particulate Silicon Flux", + "comment": "In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. 'Sinking' is the gravitational settling of particulate matter suspended in a liquid. A sinking flux is positive downwards and is calculated relative to the movement of the surrounding fluid.", "dimensions": "longitude latitude olevel time", "out_name": "expsi", "type": "real", @@ -899,12 +897,13 @@ "ok_max_mean_abs": "" }, "fediss": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_mole_concentration_of_dissolved_iron_in_sea_water_due_to_dissolution_from_inorganic_particles", "units": "mol m-3 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Particle Source of Dissolved Iron", + "long_name": "Particulate Source of Dissolved Iron", "comment": "Dissolution, remineralization and desorption of iron back to the dissolved phase", "dimensions": "longitude latitude olevel time", "out_name": "fediss", @@ -916,12 +915,13 @@ "ok_max_mean_abs": "" }, "fescav": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_mole_concentration_of_dissolved_iron_in_sea_water_due_to_scavenging_by_inorganic_particles", "units": "mol m-3 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Nonbiogenic Iron Scavenging", + "long_name": "Non-Biogenic Iron Scavenging", "comment": "Dissolved Fe removed through nonbiogenic scavenging onto particles", "dimensions": "longitude latitude olevel time", "out_name": "fescav", @@ -933,13 +933,14 @@ "ok_max_mean_abs": "" }, "fg13co2": { - "modeling_realm": "ocnBgChem", - "standard_name": "air_sea_flux_of_13CO2", - "units": "mol m-2 s-1", + "frequency": "yr", + "modeling_realm": "ocnBgchem", + "standard_name": "surface_downward_mass_flux_of_13C_dioxide_abiotic_analogue_expressed_as_13C", + "units": "kg m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Surface Downward Flux of Abiotic 13CO2", - "comment": "", + "long_name": "Surface Downward Flux of 13CO2", + "comment": "Gas exchange flux of carbon-13 as CO2 (positive into ocean)", "dimensions": "longitude latitude time", "out_name": "fg13co2", "type": "real", @@ -950,8 +951,9 @@ "ok_max_mean_abs": "" }, "fg14co2abio": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_downward_mass_flux_of_abiotic_14_carbon_dioxide_expressed_as_carbon", + "frequency": "yr", + "modeling_realm": "ocnBgchem", + "standard_name": "surface_downward_mass_flux_of_14C_dioxide_abiotic_analogue_expressed_as_carbon", "units": "kg m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", @@ -967,7 +969,8 @@ "ok_max_mean_abs": "" }, "fgco2": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "surface_downward_mass_flux_of_carbon_dioxide_expressed_as_carbon", "units": "kg m-2 s-1", "cell_methods": "area: mean where sea time: mean", @@ -984,8 +987,9 @@ "ok_max_mean_abs": "" }, "fgco2abio": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_downward_mass_flux_of_abiotic_carbon_dioxide_expressed_as_carbon", + "frequency": "yr", + "modeling_realm": "ocnBgchem", + "standard_name": "surface_downward_mass_flux_of_carbon_dioxide_abiotic_analogue_expressed_as_carbon", "units": "kg m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", @@ -1001,8 +1005,9 @@ "ok_max_mean_abs": "" }, "fgco2nat": { - "modeling_realm": "ocnBgChem", - "standard_name": "surface_downward_mass_flux_of_natural_carbon_dioxide_expressed_as_carbon", + "frequency": "yr", + "modeling_realm": "ocnBgchem", + "standard_name": "surface_downward_mass_flux_of_carbon_dioxide_natural_analogue_expressed_as_carbon", "units": "kg m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", @@ -1018,13 +1023,14 @@ "ok_max_mean_abs": "" }, "graz": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_grazing_of_phytoplankton", "units": "mol m-3 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", "long_name": "Total Grazing of Phytoplankton by Zooplankton", - "comment": "", + "comment": "Total grazing of phytoplankton by zooplankton defined as tendency of moles of carbon per cubic metre.", "dimensions": "longitude latitude olevel time", "out_name": "graz", "type": "real", @@ -1035,13 +1041,14 @@ "ok_max_mean_abs": "" }, "nh4": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_ammonium_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", "long_name": "Dissolved Ammonium Concentration", - "comment": "", + "comment": "Mole concentration means moles (amount of substance) per unit volume and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y.", "dimensions": "longitude latitude olevel time", "out_name": "nh4", "type": "real", @@ -1052,13 +1059,14 @@ "ok_max_mean_abs": "" }, "no3": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_nitrate_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", "long_name": "Dissolved Nitrate Concentration", - "comment": "", + "comment": "Mole concentration means moles (amount of substance) per unit volume and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y.", "dimensions": "longitude latitude olevel time", "out_name": "no3", "type": "real", @@ -1069,13 +1077,14 @@ "ok_max_mean_abs": "" }, "o2": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_dissolved_molecular_oxygen_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", "long_name": "Dissolved Oxygen Concentration", - "comment": "", + "comment": "'Mole concentration' means number of moles per unit volume, also called 'molarity', and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'.", "dimensions": "longitude latitude olevel time", "out_name": "o2", "type": "real", @@ -1086,13 +1095,14 @@ "ok_max_mean_abs": "" }, "o2sat": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_dissolved_molecular_oxygen_in_sea_water_at_saturation", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", "long_name": "Dissolved Oxygen Concentration at Saturation", - "comment": "", + "comment": "'Mole concentration at saturation' means the mole concentration in a saturated solution. Mole concentration means number of moles per unit volume, also called 'molarity', and is used in the construction 'mole_concentration_of_X_in_Y', where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'.", "dimensions": "longitude latitude olevel time", "out_name": "o2sat", "type": "real", @@ -1103,12 +1113,13 @@ "ok_max_mean_abs": "" }, "ocontempdiff": { + "frequency": "yr", "modeling_realm": "ocean", - "standard_name": "tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_dianeutral_mixing", + "standard_name": "tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_eddy_dianeutral_mixing", "units": "W m-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "tendency of sea water conservative temperature expressed as heat content due to parameterized dianeutral mixing", + "long_name": "Tendency of Sea Water Conservative Temperature Expressed as Heat Content Due to Parameterized Dianeutral Mixing", "comment": "Tendency of heat content for a grid cell from parameterized dianeutral mixing. Reported only for models that use conservative temperature as prognostic field.", "dimensions": "longitude latitude olevel time", "out_name": "ocontempdiff", @@ -1120,12 +1131,13 @@ "ok_max_mean_abs": "" }, "ocontempmint": { + "frequency": "yr", "modeling_realm": "ocean", "standard_name": "integral_wrt_depth_of_product_of_sea_water_density_and_conservative_temperature", "units": "degC kg m-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "integral wrt depth of product of sea water density and conservative temperature", + "long_name": "Depth Integral of Product of Sea Water Density and Conservative Temperature", "comment": "Full column sum of density*cell thickness*conservative temperature. If the model is Boussinesq, then use Boussinesq reference density for the density factor.", "dimensions": "longitude latitude time", "out_name": "ocontempmint", @@ -1137,12 +1149,13 @@ "ok_max_mean_abs": "" }, "ocontemppadvect": { + "frequency": "yr", "modeling_realm": "ocean", "standard_name": "tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_eddy_advection", "units": "W m-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "tendency of sea water conservative temperature expressed as heat content due to parameterized eddy advection", + "long_name": "Tendency of Sea Water Conservative Temperature Expressed as Heat Content Due to Parameterized Eddy Advection", "comment": "Tendency of heat content for a grid cell from parameterized eddy advection (any form of eddy advection). Reported only for models that use conservative temperature as prognostic field.", "dimensions": "longitude latitude olevel time", "out_name": "ocontemppadvect", @@ -1154,12 +1167,13 @@ "ok_max_mean_abs": "" }, "ocontemppmdiff": { + "frequency": "yr", "modeling_realm": "ocean", - "standard_name": "tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_mesoscale_diffusion", + "standard_name": "tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_mesoscale_eddy_diffusion", "units": "W m-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "tendency of sea water conservative temperature expressed as heat content due to parameterized mesoscale diffusion", + "long_name": "Tendency of Sea Water Conservative Temperature Expressed as Heat Content Due to Parameterized Mesoscale Diffusion", "comment": "Tendency of heat content for a grid cell from parameterized mesoscale eddy diffusion. Reported only for models that use conservative temperature as prognostic field.", "dimensions": "longitude latitude olevel time", "out_name": "ocontemppmdiff", @@ -1171,12 +1185,13 @@ "ok_max_mean_abs": "" }, "ocontemppsmadvect": { + "frequency": "yr", "modeling_realm": "ocean", - "standard_name": "tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_submesoscale_advection", + "standard_name": "tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_parameterized_submesoscale_eddy_advection", "units": "W m-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "tendency of sea water conservative temperature expressed as heat content due to parameterized submesoscale advection", + "long_name": "Tendency of Sea Water Conservative Temperature Expressed as Heat Content Due to Parameterized Submesoscale Advection", "comment": "Tendency of heat content for a grid cell from parameterized submesoscale eddy advection. Reported only for models that use conservative temperature as prognostic field.", "dimensions": "longitude latitude olevel time", "out_name": "ocontemppsmadvect", @@ -1188,13 +1203,14 @@ "ok_max_mean_abs": "" }, "ocontemprmadvect": { + "frequency": "yr", "modeling_realm": "ocean", "standard_name": "tendency_of_sea_water_conservative_temperature_expressed_as_heat_content_due_to_residual_mean_advection", "units": "W m-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "tendency of sea water conservative temperature expressed as heat content due to residual mean (sum of Eulerian + parameterized) advection", - "comment": "", + "long_name": "Tendency of Sea Water Conservative Temperature Expressed as Heat Content Due to Residual Mean Advection", + "comment": "Conservative Temperature is defined as part of the Thermodynamic Equation of Seawater 2010 (TEOS-10) which was adopted in 2010 by the International Oceanographic Commission (IOC). The phrase 'residual mean advection' refers to the sum of the model's resolved advective transport plus any parameterized advective transport. Parameterized advective transport includes processes such as parameterized mesoscale and submesoscale transport, as well as any other advectively parameterized transport. When the parameterized advective transport is represented in the model as a skew-diffusion rather than an advection, then the parameterized skew diffusion should be included in this diagnostic, since the convergence of skew-fluxes are identical (in the continuous formulation) to the convergence of advective fluxes.", "dimensions": "longitude latitude olevel time", "out_name": "ocontemprmadvect", "type": "real", @@ -1205,12 +1221,13 @@ "ok_max_mean_abs": "" }, "ocontemptend": { + "frequency": "yr", "modeling_realm": "ocean", "standard_name": "tendency_of_sea_water_conservative_temperature_expressed_as_heat_content", "units": "W m-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "tendency of sea water conservative temperature expressed as heat content", + "long_name": "Tendency of Sea Water Conservative Temperature Expressed as Heat Content", "comment": "Tendency of heat content for a grid cell from all processes. Reported only for models that use conservative temperature as prognostic field.", "dimensions": "longitude latitude olevel time", "out_name": "ocontemptend", @@ -1222,12 +1239,13 @@ "ok_max_mean_abs": "" }, "opottempdiff": { + "frequency": "yr", "modeling_realm": "ocean", - "standard_name": "tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_dianeutral_mixing", + "standard_name": "tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_eddy_dianeutral_mixing", "units": "W m-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "tendency of sea water potential temperature expressed as heat content due to parameterized dianeutral mixing", + "long_name": "Tendency of Sea Water Potential Temperature Expressed as Heat Content Due to Parameterized Dianeutral Mixing", "comment": "Tendency of heat content for a grid cell from parameterized dianeutral mixing. Reported only for models that use potential temperature as prognostic field.", "dimensions": "longitude latitude olevel time", "out_name": "opottempdiff", @@ -1239,13 +1257,14 @@ "ok_max_mean_abs": "" }, "opottempmint": { + "frequency": "yr", "modeling_realm": "ocean", "standard_name": "integral_wrt_depth_of_product_of_sea_water_density_and_potential_temperature", "units": "degC kg m-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "integral wrt depth of product of sea water density and potential temperature", - "comment": "", + "long_name": "Integral with Respect to Depth of Product of Sea Water Density and Potential Temperature", + "comment": "Integral over the full ocean depth of the product of sea water density and potential temperature.", "dimensions": "longitude latitude time", "out_name": "opottempmint", "type": "real", @@ -1256,12 +1275,13 @@ "ok_max_mean_abs": "" }, "opottemppadvect": { + "frequency": "yr", "modeling_realm": "ocean", "standard_name": "tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_eddy_advection", "units": "W m-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "tendency of sea water potential temperature expressed as heat content due to parameterized eddy advection", + "long_name": "Tendency of Sea Water Potential Temperature Expressed as Heat Content Due to Parameterized Eddy Advection", "comment": "Tendency of heat content for a grid cell from parameterized eddy advection (any form of eddy advection). Reported only for models that use potential temperature as prognostic field.", "dimensions": "longitude latitude olevel time", "out_name": "opottemppadvect", @@ -1273,12 +1293,13 @@ "ok_max_mean_abs": "" }, "opottemppmdiff": { + "frequency": "yr", "modeling_realm": "ocean", - "standard_name": "tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_mesoscale_diffusion", + "standard_name": "tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_mesoscale_eddy_diffusion", "units": "W m-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "tendency of sea water potential temperature expressed as heat content due to parameterized mesoscale diffusion", + "long_name": "Tendency of Sea Water Potential Temperature Expressed as Heat Content Due to Parameterized Mesoscale Diffusion", "comment": "Tendency of heat content for a grid cell from parameterized mesoscale eddy diffusion. Reported only for models that use potential temperature as prognostic field.", "dimensions": "longitude latitude olevel time", "out_name": "opottemppmdiff", @@ -1290,12 +1311,13 @@ "ok_max_mean_abs": "" }, "opottemppsmadvect": { + "frequency": "yr", "modeling_realm": "ocean", - "standard_name": "tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_submesoscale_advection", + "standard_name": "tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_parameterized_submesoscale_eddy_advection", "units": "W m-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "tendency of sea water potential temperature expressed as heat content due to parameterized submesoscale advection", + "long_name": "Tendency of Sea Water Potential Temperature Expressed as Heat Content Due to Parameterized Submesoscale Advection", "comment": "Tendency of heat content for a grid cell from parameterized submesoscale eddy advection. Reported only for models that use potential temperature as prognostic field.", "dimensions": "longitude latitude olevel time", "out_name": "opottemppsmadvect", @@ -1307,13 +1329,14 @@ "ok_max_mean_abs": "" }, "opottemprmadvect": { + "frequency": "yr", "modeling_realm": "ocean", "standard_name": "tendency_of_sea_water_potential_temperature_expressed_as_heat_content_due_to_residual_mean_advection", "units": "W m-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "tendency of sea water potential temperature expressed as heat content due to residual mean advection", - "comment": "", + "long_name": "Tendency of Sea Water Potential Temperature Expressed as Heat Content Due to Residual Mean Advection", + "comment": "The phrase 'residual mean advection' refers to the sum of the model's resolved advective transport plus any parameterized advective transport. Parameterized advective transport includes processes such as parameterized mesoscale and submesoscale transport, as well as any other advectively parameterized transport. When the parameterized advective transport is represented in the model as a skew-diffusion rather than an advection, then the parameterized skew diffusion should be included in this diagnostic, since the convergence of skew-fluxes are identical (in the continuous formulation) to the convergence of advective fluxes.", "dimensions": "longitude latitude olevel time", "out_name": "opottemprmadvect", "type": "real", @@ -1324,12 +1347,13 @@ "ok_max_mean_abs": "" }, "opottemptend": { + "frequency": "yr", "modeling_realm": "ocean", "standard_name": "tendency_of_sea_water_potential_temperature_expressed_as_heat_content", "units": "W m-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "tendency of sea water potential temperature expressed as heat content", + "long_name": "Tendency of Sea Water Potential Temperature Expressed as Heat Content", "comment": "Tendency of heat content for a grid cell from all processes. Reported only for models that use potential temperature as prognostic field.", "dimensions": "longitude latitude olevel time", "out_name": "opottemptend", @@ -1341,12 +1365,13 @@ "ok_max_mean_abs": "" }, "osaltdiff": { + "frequency": "yr", "modeling_realm": "ocean", - "standard_name": "tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_dianeutral_mixing", + "standard_name": "tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_eddy_dianeutral_mixing", "units": "kg m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "tendency of sea water salinity expressed as salt content due to parameterized dianeutral mixing", + "long_name": "Tendency of Sea Water Salinity Expressed as Salt Content Due to Parameterized Dianeutral Mixing", "comment": "Tendency of salt content for a grid cell from parameterized dianeutral mixing.", "dimensions": "longitude latitude olevel time", "out_name": "osaltdiff", @@ -1358,12 +1383,13 @@ "ok_max_mean_abs": "" }, "osaltpadvect": { + "frequency": "yr", "modeling_realm": "ocean", "standard_name": "tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_eddy_advection", "units": "kg m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "tendency of sea water salinity expressed as salt content due to parameterized eddy advection", + "long_name": "Tendency of Sea Water Salinity Expressed as Salt Content Due to Parameterized Eddy Advection", "comment": "Tendency of salt content for a grid cell from parameterized eddy advection (any form of eddy advection).", "dimensions": "longitude latitude olevel time", "out_name": "osaltpadvect", @@ -1375,12 +1401,13 @@ "ok_max_mean_abs": "" }, "osaltpmdiff": { + "frequency": "yr", "modeling_realm": "ocean", - "standard_name": "tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_mesoscale_diffusion", + "standard_name": "tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_mesoscale_eddy_diffusion", "units": "kg m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "tendency of sea water salinity expressed as salt content due to parameterized mesoscale diffusion", + "long_name": "Tendency of Sea Water Salinity Expressed as Salt Content Due to Parameterized Mesoscale Diffusion", "comment": "Tendency of salt content for a grid cell from parameterized mesoscale eddy diffusion.", "dimensions": "longitude latitude olevel time", "out_name": "osaltpmdiff", @@ -1392,12 +1419,13 @@ "ok_max_mean_abs": "" }, "osaltpsmadvect": { + "frequency": "yr", "modeling_realm": "ocean", - "standard_name": "tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_submesoscale_advection", + "standard_name": "tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_parameterized_submesoscale_eddy_advection", "units": "kg m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "tendency of sea water salinity expressed as salt content due to parameterized submesoscale advection", + "long_name": "Tendency of Sea Water Salinity Expressed as Salt Content Due to Parameterized Submesoscale Advection", "comment": "Tendency of salt content for a grid cell from parameterized submesoscale eddy advection.", "dimensions": "longitude latitude olevel time", "out_name": "osaltpsmadvect", @@ -1409,13 +1437,14 @@ "ok_max_mean_abs": "" }, "osaltrmadvect": { + "frequency": "yr", "modeling_realm": "ocean", "standard_name": "tendency_of_sea_water_salinity_expressed_as_salt_content_due_to_residual_mean_advection", "units": "kg m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "tendency of sea water salinity expressed as salt content due to residual mean advection", - "comment": "", + "long_name": "Tendency of Sea Water Salinity Expressed as Salt Content Due to Residual Mean Advection", + "comment": "The phrase 'residual mean advection' refers to the sum of the model's resolved advective transport plus any parameterized advective transport. Parameterized advective transport includes processes such as parameterized mesoscale and submesoscale transport, as well as any other advectively parameterized transport. When the parameterized advective transport is represented in the model as a skew-diffusion rather than an advection, then the parameterized skew diffusion should be included in this diagnostic, since the convergence of skew-fluxes are identical (in the continuous formulation) to the convergence of advective fluxes.", "dimensions": "longitude latitude olevel time", "out_name": "osaltrmadvect", "type": "real", @@ -1426,12 +1455,13 @@ "ok_max_mean_abs": "" }, "osalttend": { + "frequency": "yr", "modeling_realm": "ocean", "standard_name": "tendency_of_sea_water_salinity_expressed_as_salt_content", "units": "kg m-2 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "tendency of sea water salinity expressed as salt content", + "long_name": "Tendency of Sea Water Salinity Expressed as Salt Content", "comment": "Tendency of salt content for a grid cell from all processes.", "dimensions": "longitude latitude olevel time", "out_name": "osalttend", @@ -1443,13 +1473,14 @@ "ok_max_mean_abs": "" }, "parag": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_mole_concentration_of_aragonite_expressed_as_carbon_in_sea_water_due_to_biological_production", "units": "mol m-3 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", "long_name": "Aragonite Production", - "comment": "", + "comment": "Production rate of Aragonite, a mineral that is a polymorph of calcium carbonate. The chemical formula of aragonite is CaCO3.", "dimensions": "longitude latitude olevel time", "out_name": "parag", "type": "real", @@ -1460,13 +1491,14 @@ "ok_max_mean_abs": "" }, "pbfe": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_mole_concentration_of_iron_in_sea_water_due_to_biological_production", "units": "mol m-3 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", "long_name": "Biogenic Iron Production", - "comment": "", + "comment": "'Mole concentration' means number of moles per unit volume, also called 'molarity', and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. 'tendency_of_X' means derivative of X with respect to time.", "dimensions": "longitude latitude olevel time", "out_name": "pbfe", "type": "real", @@ -1477,13 +1509,14 @@ "ok_max_mean_abs": "" }, "pbsi": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_mole_concentration_of_silicon_in_sea_water_due_to_biological_production", "units": "mol m-3 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Biogenic Silica Production", - "comment": "", + "long_name": "Biogenic Silicon Production", + "comment": "'Mole concentration' means number of moles per unit volume, also called 'molarity', and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. 'tendency_of_X' means derivative of X with respect to time.", "dimensions": "longitude latitude olevel time", "out_name": "pbsi", "type": "real", @@ -1494,13 +1527,14 @@ "ok_max_mean_abs": "" }, "pcalc": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_mole_concentration_of_calcite_expressed_as_carbon_in_sea_water_due_to_biological_production", "units": "mol m-3 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", "long_name": "Calcite Production", - "comment": "", + "comment": "Production rate of Calcite, a mineral that is a polymorph of calcium carbonate. The chemical formula of calcite is CaCO3. ", "dimensions": "longitude latitude olevel time", "out_name": "pcalc", "type": "real", @@ -1510,27 +1544,11 @@ "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, - "pdi": { - "modeling_realm": "ocnBgChem", - "standard_name": "tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_diatoms", - "units": "mol m-3 s-1", - "cell_methods": "area: mean where sea time: mean", - "cell_measures": "area: areacello volume: volcello", - "long_name": "Diatom Primary Carbon Production", - "comment": "Primary (organic carbon) production by the diatom component alone", - "dimensions": "longitude latitude olevel time", - "out_name": "pdi", - "type": "real", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, "ph": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "sea_water_ph_reported_on_total_scale", - "units": "1.0", + "units": "1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", "long_name": "pH", @@ -1545,9 +1563,10 @@ "ok_max_mean_abs": "" }, "phabio": { - "modeling_realm": "ocnBgChem", - "standard_name": "sea_water_ph_reported_on_total_scale_due_to_abiotic_component", - "units": "1.0", + "frequency": "yr", + "modeling_realm": "ocnBgchem", + "standard_name": "sea_water_ph_abiotic_analogue_reported_on_total_scale", + "units": "1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", "long_name": "Abiotic pH", @@ -1562,9 +1581,10 @@ "ok_max_mean_abs": "" }, "phnat": { - "modeling_realm": "ocnBgChem", - "standard_name": "sea_water_ph_reported_on_total_scale_due_to_natural_component", - "units": "1.0", + "frequency": "yr", + "modeling_realm": "ocnBgchem", + "standard_name": "sea_water_ph_natural_analogue_reported_on_total_scale", + "units": "1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", "long_name": "Natural pH", @@ -1579,7 +1599,8 @@ "ok_max_mean_abs": "" }, "phyc": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_phytoplankton_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", @@ -1596,12 +1617,13 @@ "ok_max_mean_abs": "" }, "phycalc": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_calcareous_phytoplankton_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Mole Concentration of Calcareous Phytoplankton expressed as Carbon in sea water", + "long_name": "Mole Concentration of Calcareous Phytoplankton Expressed as Carbon in Sea Water", "comment": "carbon concentration from calcareous (calcite-producing) phytoplankton component alone", "dimensions": "longitude latitude olevel time", "out_name": "phycalc", @@ -1613,12 +1635,13 @@ "ok_max_mean_abs": "" }, "phydiat": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_diatoms_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Mole Concentration of Diatoms expressed as Carbon in sea water", + "long_name": "Mole Concentration of Diatoms Expressed as Carbon in Sea Water", "comment": "carbon from the diatom phytoplankton component concentration alone", "dimensions": "longitude latitude olevel time", "out_name": "phydiat", @@ -1630,12 +1653,13 @@ "ok_max_mean_abs": "" }, "phydiaz": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_diazotrophs_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Mole Concentration of Diazotrophs Expressed as Carbon in sea water", + "long_name": "Mole Concentration of Diazotrophs Expressed as Carbon in Sea Water", "comment": "carbon concentration from the diazotrophic phytoplankton component alone", "dimensions": "longitude latitude olevel time", "out_name": "phydiaz", @@ -1647,12 +1671,13 @@ "ok_max_mean_abs": "" }, "phyfe": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_phytoplankton_expressed_as_iron_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Mole Concentration of Total Phytoplankton expressed as Iron in sea water", + "long_name": "Mole Concentration of Total Phytoplankton Expressed as Iron in Sea Water", "comment": "sum of phytoplankton iron component concentrations", "dimensions": "longitude latitude olevel time", "out_name": "phyfe", @@ -1664,12 +1689,13 @@ "ok_max_mean_abs": "" }, "phymisc": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_miscellaneous_phytoplankton_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Mole Concentration of Miscellaneous Phytoplankton expressed as Carbon in sea water", + "long_name": "Mole Concentration of Miscellaneous Phytoplankton Expressed as Carbon in Sea Water", "comment": "carbon concentration from additional phytoplankton component alone", "dimensions": "longitude latitude olevel time", "out_name": "phymisc", @@ -1681,12 +1707,13 @@ "ok_max_mean_abs": "" }, "phyn": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_phytoplankton_expressed_as_nitrogen_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Mole Concentration of Total Phytoplankton expressed as Nitrogen in sea water", + "long_name": "Mole Concentration of Total Phytoplankton Expressed as Nitrogen in Sea Water", "comment": "sum of phytoplankton nitrogen component concentrations", "dimensions": "longitude latitude olevel time", "out_name": "phyn", @@ -1698,12 +1725,13 @@ "ok_max_mean_abs": "" }, "phyp": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_phytoplankton_expressed_as_phosphorus_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Mole Concentration of Total Phytoplankton expressed as Phosphorus in sea water", + "long_name": "Mole Concentration of Total Phytoplankton Expressed as Phosphorus in Sea Water", "comment": "sum of phytoplankton phosphorus components", "dimensions": "longitude latitude olevel time", "out_name": "phyp", @@ -1715,12 +1743,13 @@ "ok_max_mean_abs": "" }, "phypico": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_picophytoplankton_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Mole Concentration of Picophytoplankton expressed as Carbon in sea water", + "long_name": "Mole Concentration of Picophytoplankton Expressed as Carbon in Sea Water", "comment": "carbon concentration from the picophytoplankton (<2 um) component alone", "dimensions": "longitude latitude olevel time", "out_name": "phypico", @@ -1732,12 +1761,13 @@ "ok_max_mean_abs": "" }, "physi": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_phytoplankton_expressed_as_silicon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Mole Concentration of Total Phytoplankton expressed as Silicon in sea water", + "long_name": "Mole Concentration of Total Phytoplankton Expressed as Silicon in Sea Water", "comment": "sum of phytoplankton silica component concentrations", "dimensions": "longitude latitude olevel time", "out_name": "physi", @@ -1749,12 +1779,13 @@ "ok_max_mean_abs": "" }, "pnitrate": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_nitrate_utilization", "units": "mol m-3 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Primary Carbon Production by Phytoplankton due to Nitrate Uptake Alone", + "long_name": "Primary Carbon Production by Phytoplankton Due to Nitrate Uptake Alone", "comment": "Primary (organic carbon) production by phytoplankton due to nitrate uptake alone", "dimensions": "longitude latitude olevel time", "out_name": "pnitrate", @@ -1766,13 +1797,14 @@ "ok_max_mean_abs": "" }, "po4": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_dissolved_inorganic_phosphorus_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", "long_name": "Total Dissolved Inorganic Phosphorus Concentration", - "comment": "", + "comment": "Mole concentration means number of moles per unit volume, also called 'molarity', and is used in the construction 'mole_concentration_of_X_in_Y', where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. 'Dissolved inorganic phosphorus' means the sum of all inorganic phosphorus in solution (including phosphate, hydrogen phosphate, dihydrogen phosphate, and phosphoric acid).", "dimensions": "longitude latitude olevel time", "out_name": "po4", "type": "real", @@ -1783,12 +1815,13 @@ "ok_max_mean_abs": "" }, "pon": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_particulate_organic_matter_expressed_as_nitrogen_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Mole Concentration of Particulate Organic Matter expressed as Nitrogen in sea water", + "long_name": "Mole Concentration of Particulate Organic Matter Expressed as Nitrogen in Sea Water", "comment": "sum of particulate organic nitrogen component concentrations", "dimensions": "longitude latitude olevel time", "out_name": "pon", @@ -1800,12 +1833,13 @@ "ok_max_mean_abs": "" }, "pop": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_particulate_organic_matter_expressed_as_phosphorus_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Mole Concentration of Particulate Organic Matter expressed as Phosphorus in sea water", + "long_name": "Mole Concentration of Particulate Organic Matter Expressed as Phosphorus in Sea Water", "comment": "sum of particulate organic phosphorus component concentrations", "dimensions": "longitude latitude olevel time", "out_name": "pop", @@ -1817,12 +1851,13 @@ "ok_max_mean_abs": "" }, "pp": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production", "units": "mol m-3 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Primary Carbon Production by Total Phytoplankton", + "long_name": "Primary Carbon Production by Phytoplankton", "comment": "total primary (organic carbon) production by phytoplankton", "dimensions": "longitude latitude olevel time", "out_name": "pp", @@ -1834,7 +1869,8 @@ "ok_max_mean_abs": "" }, "ppcalc": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_calcareous_phytoplankton", "units": "mol m-3 s-1", "cell_methods": "area: mean where sea time: mean", @@ -1851,7 +1887,8 @@ "ok_max_mean_abs": "" }, "ppdiat": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_diatoms", "units": "mol m-3 s-1", "cell_methods": "area: mean where sea time: mean", @@ -1868,7 +1905,8 @@ "ok_max_mean_abs": "" }, "ppdiaz": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_diazotrophs", "units": "mol m-3 s-1", "cell_methods": "area: mean where sea time: mean", @@ -1885,7 +1923,8 @@ "ok_max_mean_abs": "" }, "ppmisc": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_miscellaneous_phytoplankton", "units": "mol m-3 s-1", "cell_methods": "area: mean where sea time: mean", @@ -1902,7 +1941,8 @@ "ok_max_mean_abs": "" }, "pppico": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production_by_picophytoplankton", "units": "mol m-3 s-1", "cell_methods": "area: mean where sea time: mean", @@ -1919,13 +1959,14 @@ "ok_max_mean_abs": "" }, "remoc": { - "modeling_realm": "ocnBgChem", - "standard_name": "tendency_of_mole_concentration_of_organic_matter_expressed_as_carbon_in_sea_water_due_to_remineralization", + "frequency": "yr", + "modeling_realm": "ocnBgchem", + "standard_name": "tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_remineralization", "units": "mol m-3 s-1", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", "long_name": "Remineralization of Organic Carbon", - "comment": "", + "comment": "Remineralization is the degradation of organic matter into inorganic forms of carbon, nitrogen, phosphorus and other micronutrients, which consumes oxygen and releases energy.", "dimensions": "longitude latitude olevel time", "out_name": "remoc", "type": "real", @@ -1936,13 +1977,14 @@ "ok_max_mean_abs": "" }, "rsdoabsorb": { + "frequency": "yr", "modeling_realm": "ocean", "standard_name": "net_rate_of_absorption_of_shortwave_energy_in_ocean_layer", "units": "W m-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "net rate of absorption of shortwave energy in ocean layer", - "comment": "", + "long_name": "Net Rate of Absorption of Shortwave Energy in Ocean Layer", + "comment": "'shortwave' means shortwave radiation. 'Layer' means any layer with upper and lower boundaries that have constant values in some vertical coordinate. There must be a vertical coordinate variable indicating the extent of the layer(s). If the layers are model layers, the vertical coordinate can be model_level_number, but it is recommended to specify a physical coordinate (in a scalar or auxiliary coordinate variable) as well. Net absorbed radiation is the difference between absorbed and emitted radiation.", "dimensions": "longitude latitude olevel time", "out_name": "rsdoabsorb", "type": "real", @@ -1953,13 +1995,14 @@ "ok_max_mean_abs": "" }, "sf6": { + "frequency": "yr", "modeling_realm": "ocean", "standard_name": "mole_concentration_of_sulfur_hexafluoride_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Mole Concentration of SF6 in sea water", - "comment": "", + "long_name": "Mole Concentration of SF6 in Sea Water", + "comment": "Mole concentration means number of moles per unit volume, also called 'molarity', and is used in the construction 'mole_concentration_of_X_in_Y', where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula of sulfur hexafluoride is SF6.", "dimensions": "longitude latitude olevel time", "out_name": "sf6", "type": "real", @@ -1970,13 +2013,14 @@ "ok_max_mean_abs": "" }, "si": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_dissolved_inorganic_silicon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", "long_name": "Total Dissolved Inorganic Silicon Concentration", - "comment": "", + "comment": "Mole concentration means number of moles per unit volume, also called 'molarity', and is used in the construction 'mole_concentration_of_X_in_Y', where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. 'Dissolved inorganic silicon' means the sum of all inorganic silicon in solution (including silicic acid and its first dissociated anion SiO(OH)3-).", "dimensions": "longitude latitude olevel time", "out_name": "si", "type": "real", @@ -1987,12 +2031,13 @@ "ok_max_mean_abs": "" }, "somint": { + "frequency": "yr", "modeling_realm": "ocean", - "standard_name": "integral_wrt_depth_of_product_of_sea_water_density_and_prognostic_salinity", - "units": "1e-3 kg m-2", + "standard_name": "integral_wrt_depth_of_product_of_sea_water_density_and_salinity", + "units": "g m-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "integral wrt depth of product of sea water density and salinity", + "long_name": "Depth Integral of Product of Sea Water Density and Prognostic Salinity", "comment": "Full column sum of density*cell thickness*prognostic salinity. If the model is Boussinesq, then use Boussinesq reference density for the density factor.", "dimensions": "longitude latitude time", "out_name": "somint", @@ -2004,7 +2049,8 @@ "ok_max_mean_abs": "" }, "talk": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "sea_water_alkalinity_expressed_as_mole_equivalent", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", @@ -2021,8 +2067,9 @@ "ok_max_mean_abs": "" }, "talknat": { - "modeling_realm": "ocnBgChem", - "standard_name": "seawater_alkalinity_expressed_as_mole_equivalent_natural_component", + "frequency": "yr", + "modeling_realm": "ocnBgchem", + "standard_name": "sea_water_alkalinity_natural_analogue_expressed_as_mole_equivalent", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", @@ -2038,12 +2085,13 @@ "ok_max_mean_abs": "" }, "tnkebto": { + "frequency": "yr", "modeling_realm": "ocean", - "standard_name": "tendency_of_ocean_eddy_kinetic_energy_content_due_to_bolus_transport", + "standard_name": "tendency_of_ocean_eddy_kinetic_energy_content_due_to_parameterized_eddy_advection", "units": "W m-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "tendency of ocean eddy kinetic energy content due to parameterized eddy advection", + "long_name": "Tendency of Ocean Eddy Kinetic Energy Content Due to Parameterized Eddy Advection", "comment": "Depth integrated impacts on kinetic energy arising from parameterized eddy-induced advection. For CMIP5, this diagnostic was 3d, whereas the CMIP6 depth integrated diagnostic is sufficient for many purposes and reduces archive requirements.", "dimensions": "longitude latitude time", "out_name": "tnkebto", @@ -2055,12 +2103,13 @@ "ok_max_mean_abs": "" }, "tnpeo": { + "frequency": "yr", "modeling_realm": "ocean", "standard_name": "tendency_of_ocean_potential_energy_content", "units": "W m-2", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "tendency of ocean potential energy content", + "long_name": "Tendency of Ocean Potential Energy Content", "comment": "Rate that work is done against vertical stratification, as measured by the vertical heat and salt diffusivity. Report here as depth integrated two-dimensional field.", "dimensions": "longitude latitude time", "out_name": "tnpeo", @@ -2071,13 +2120,32 @@ "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, + "volcello": { + "frequency": "yr", + "modeling_realm": "ocean", + "standard_name": "ocean_volume", + "units": "m3", + "cell_methods": "area: mean where sea time: mean", + "cell_measures": "area: areacello volume: volcello", + "long_name": "Ocean Grid-Cell Volume", + "comment": "grid-cell volume ca. 2000.", + "dimensions": "longitude latitude olevel time", + "out_name": "volcello", + "type": "real", + "positive": "", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, "zmeso": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_mesozooplankton_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Mole Concentration of Mesozooplankton expressed as Carbon in sea water", + "long_name": "Mole Concentration of Mesozooplankton Expressed as Carbon in Sea Water", "comment": "carbon concentration from mesozooplankton (20-200 um) component alone", "dimensions": "longitude latitude olevel time", "out_name": "zmeso", @@ -2089,12 +2157,13 @@ "ok_max_mean_abs": "" }, "zmicro": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_microzooplankton_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Mole Concentration of Microzooplankton expressed as Carbon in sea water", + "long_name": "Mole Concentration of Microzooplankton Expressed as Carbon in Sea Water", "comment": "carbon concentration from the microzooplankton (<20 um) component alone", "dimensions": "longitude latitude olevel time", "out_name": "zmicro", @@ -2106,12 +2175,13 @@ "ok_max_mean_abs": "" }, "zmisc": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_miscellaneous_zooplankton_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello volume: volcello", - "long_name": "Mole Concetration of Other Zooplankton expressed as Carbon in sea water", + "long_name": "Mole Concentration of Other Zooplankton Expressed as Carbon in Sea Water", "comment": "carbon from additional zooplankton component concentrations alone (e.g. Micro, meso). Since the models all have different numbers of components, this variable has been included to provide a check for intercomparison between models since some phytoplankton groups are supersets.", "dimensions": "longitude latitude olevel time", "out_name": "zmisc", @@ -2123,7 +2193,8 @@ "ok_max_mean_abs": "" }, "zooc": { - "modeling_realm": "ocnBgChem", + "frequency": "yr", + "modeling_realm": "ocnBgchem", "standard_name": "mole_concentration_of_zooplankton_expressed_as_carbon_in_sea_water", "units": "mol m-3", "cell_methods": "area: mean where sea time: mean", diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_SIday.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_SIday.json index 289befec99..f9f8c4163f 100644 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_SIday.json +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_SIday.json @@ -1,27 +1,28 @@ { "Header": { - "data_specs_version": "01.00.10", + "data_specs_version": "01.00.30", + "cmor_version": "3.4", "table_id": "Table SIday", "realm": "seaIce", - "frequency": "day", - "cmor_version": "3.2", - "table_date": "10 May 2017", + "table_date": "11 March 2019", "missing_value": "1e20", + "int_missing_value": "-999", "product": "model-output", "approx_interval": "1.00000", "generic_levels": "", "mip_era": "CMIP6", - "Conventions": "CF-1.7 CMIP-6.0" + "Conventions": "CF-1.7 CMIP-6.2" }, "variable_entry": { "siconc": { + "frequency": "day", "modeling_realm": "seaIce", "standard_name": "sea_ice_area_fraction", "units": "%", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Sea Ice Area Fraction", - "comment": "Area fraction of grid cell covered by sea ice", + "long_name": "Sea-Ice Area Percentage (Ocean Grid)", + "comment": "Percentage of grid cell covered by sea ice", "dimensions": "longitude latitude time typesi", "out_name": "siconc", "type": "real", @@ -31,16 +32,17 @@ "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, - "siconco": { + "siconca": { + "frequency": "day", "modeling_realm": "seaIce", "standard_name": "sea_ice_area_fraction", "units": "%", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Sea Ice Area Fraction", - "comment": "Area fraction of grid cell covered by sea ice", + "long_name": "Sea-Ice Area Percentage (Atmospheric Grid)", + "comment": "Percentage of grid cell covered by sea ice", "dimensions": "longitude latitude time typesi", - "out_name": "siconco", + "out_name": "siconca", "type": "real", "positive": "", "valid_min": "", @@ -49,16 +51,17 @@ "ok_max_mean_abs": "" }, "sisnthick": { + "frequency": "day", "modeling_realm": "seaIce", "standard_name": "surface_snow_thickness", "units": "m", "cell_methods": "area: mean where snow over sea_ice area: time: mean where sea_ice", - "cell_measures": "area: areacella", - "long_name": "Snow thickness", + "cell_measures": "area: areacello", + "long_name": "Snow Thickness", "comment": "Actual thickness of snow (snow volume divided by snow-covered area)", "dimensions": "longitude latitude time", "out_name": "sisnthick", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -66,16 +69,17 @@ "ok_max_mean_abs": "" }, "sispeed": { + "frequency": "day", "modeling_realm": "seaIce", "standard_name": "sea_ice_speed", "units": "m s-1", "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", - "cell_measures": "area: areacella", - "long_name": "Sea-ice speed", + "cell_measures": "area: areacello", + "long_name": "Sea-Ice Speed", "comment": "Speed of ice (i.e. mean absolute velocity) to account for back-and-forth movement of the ice", "dimensions": "longitude latitude time", "out_name": "sispeed", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -83,16 +87,17 @@ "ok_max_mean_abs": "" }, "sitemptop": { + "frequency": "day", "modeling_realm": "seaIce", "standard_name": "sea_ice_surface_temperature", "units": "K", "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", - "cell_measures": "area: areacella", - "long_name": "Surface temperature of sea ice", + "cell_measures": "area: areacello", + "long_name": "Surface Temperature of Sea Ice", "comment": "Report surface temperature of snow where snow covers the sea ice.", "dimensions": "longitude latitude time", "out_name": "sitemptop", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -100,11 +105,12 @@ "ok_max_mean_abs": "" }, "sithick": { + "frequency": "day", "modeling_realm": "seaIce ocean", "standard_name": "sea_ice_thickness", "units": "m", "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", - "cell_measures": "area: areacella", + "cell_measures": "area: areacello", "long_name": "Sea Ice Thickness", "comment": "Actual (floe) thickness of sea ice (NOT volume divided by grid area as was done in CMIP5)", "dimensions": "longitude latitude time", @@ -117,16 +123,17 @@ "ok_max_mean_abs": "" }, "sitimefrac": { + "frequency": "day", "modeling_realm": "seaIce", - "standard_name": "sea_ice_time_fraction", - "units": "1.0", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "Fraction of time steps with sea ice", + "standard_name": "fraction_of_time_with_sea_ice_area_fraction_above_threshold", + "units": "1", + "cell_methods": "area: mean where sea time: mean", + "cell_measures": "area: areacello", + "long_name": "Fraction of Time Steps with Sea Ice", "comment": "Fraction of time steps of the averaging period during which sea ice is present (siconc >0 ) in a grid cell", "dimensions": "longitude latitude time", "out_name": "sitimefrac", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -134,16 +141,17 @@ "ok_max_mean_abs": "" }, "siu": { + "frequency": "day", "modeling_realm": "seaIce", "standard_name": "sea_ice_x_velocity", "units": "m s-1", "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", "cell_measures": "--MODEL", - "long_name": "X-component of sea ice velocity", + "long_name": "X-Component of Sea-Ice Velocity", "comment": "The x-velocity of ice on native model grid", "dimensions": "longitude latitude time", "out_name": "siu", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -151,16 +159,17 @@ "ok_max_mean_abs": "" }, "siv": { + "frequency": "day", "modeling_realm": "seaIce", "standard_name": "sea_ice_y_velocity", "units": "m s-1", "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", "cell_measures": "--MODEL", - "long_name": "Y-component of sea ice velocity", + "long_name": "Y-Component of Sea-Ice Velocity", "comment": "The y-velocity of ice on native model grid", "dimensions": "longitude latitude time", "out_name": "siv", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_SImon.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_SImon.json index ecfcd3c635..a8f31c21b0 100644 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_SImon.json +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_SImon.json @@ -1,47 +1,49 @@ { "Header": { - "data_specs_version": "01.00.10", + "data_specs_version": "01.00.30", + "cmor_version": "3.4", "table_id": "Table SImon", "realm": "seaIce", - "frequency": "mon", - "cmor_version": "3.2", - "table_date": "10 May 2017", + "table_date": "11 March 2019", "missing_value": "1e20", + "int_missing_value": "-999", "product": "model-output", "approx_interval": "30.00000", "generic_levels": "", "mip_era": "CMIP6", - "Conventions": "CF-1.7 CMIP-6.0" + "Conventions": "CF-1.7 CMIP-6.2" }, "variable_entry": { - "siage": { + "sfdsi": { + "frequency": "mon", "modeling_realm": "seaIce", - "standard_name": "age_of_sea_ice", - "units": "s", + "standard_name": "downward_sea_ice_basal_salt_flux", + "units": "kg m-2 s-1", "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", - "cell_measures": "area: areacella", - "long_name": "Age of sea ice", - "comment": "Age of sea ice", + "cell_measures": "area: areacello", + "long_name": "Downward Sea Ice Basal Salt Flux", + "comment": "This field is physical, and it arises since sea ice has a nonzero salt content, so it exchanges salt with the liquid ocean upon melting and freezing.", "dimensions": "longitude latitude time", - "out_name": "siage", - "type": "", - "positive": "", + "out_name": "sfdsi", + "type": "real", + "positive": "down", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, - "sialb": { + "siage": { + "frequency": "mon", "modeling_realm": "seaIce", - "standard_name": "sea_ice_albedo", - "units": "1.0", + "standard_name": "age_of_sea_ice", + "units": "s", "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", - "cell_measures": "area: areacella", - "long_name": "Sea-ice or snow albedo", - "comment": "Mean surface albedo of entire ice-covered part of grid cell", + "cell_measures": "area: areacello", + "long_name": "Age of Sea Ice", + "comment": "Age of sea ice", "dimensions": "longitude latitude time", - "out_name": "sialb", - "type": "", + "out_name": "siage", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -49,16 +51,17 @@ "ok_max_mean_abs": "" }, "siareaacrossline": { + "frequency": "mon", "modeling_realm": "seaIce", "standard_name": "sea_ice_area_transport_across_line", "units": "m2 s-1", "cell_methods": "time: mean", - "cell_measures": "area: areacella", - "long_name": "Sea ice area flux through straits", - "comment": "net (sum of transport in all directions) sea ice area transport through the following four passages, positive into the Arctic Ocean 1. Fram Strait = (11.5W,81.3N to (10.5E,79.6N) 2. Canadian Archipelego = (128.2W,70.6N) to (59.3W,82.1N) 3. Barents opening = (16.8E,76.5N) to (19.2E,70.2N) 4. Bering Strait = (171W,66.2N) to (166W,65N)", + "cell_measures": "", + "long_name": "Sea-Ice Area Flux Through Straits", + "comment": "net (sum of transport in all directions) sea ice area transport through the following four passages, positive into the Arctic Ocean 1. Fram Strait = (11.5W,81.3N to (10.5E,79.6N) 2. Canadian Archipelago = (128.2W,70.6N) to (59.3W,82.1N) 3. Barents opening = (16.8E,76.5N) to (19.2E,70.2N) 4. Bering Strait = (171W,66.2N) to (166W,65N)", "dimensions": "siline time", "out_name": "siareaacrossline", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -66,16 +69,17 @@ "ok_max_mean_abs": "" }, "siarean": { + "frequency": "mon", "modeling_realm": "seaIce", "standard_name": "sea_ice_area", "units": "1e6 km2", "cell_methods": "area: time: mean", "cell_measures": "", - "long_name": "Sea ice area North", + "long_name": "Sea-Ice Area North", "comment": "total area of sea ice in the Northern hemisphere", "dimensions": "time", "out_name": "siarean", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -83,16 +87,17 @@ "ok_max_mean_abs": "" }, "siareas": { + "frequency": "mon", "modeling_realm": "seaIce", "standard_name": "sea_ice_area", "units": "1e6 km2", "cell_methods": "area: time: mean", "cell_measures": "", - "long_name": "Sea ice area South", + "long_name": "Sea-Ice Area South", "comment": "total area of sea ice in the Southern hemisphere", "dimensions": "time", "out_name": "siareas", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -100,16 +105,17 @@ "ok_max_mean_abs": "" }, "sicompstren": { + "frequency": "mon", "modeling_realm": "seaIce", "standard_name": "compressive_strength_of_sea_ice", "units": "N m-1", "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", - "cell_measures": "area: areacella", - "long_name": "Compressive sea ice strength", - "comment": "Computed strength of the ice pack, defined as the energy (J m-2) dissipated per unit area removed from the ice pack under compression, and assumed proportional to the change in potential energy caused by ridging. For Hibler-type models, this is P (= P*hexp(-C(1-A)))", + "cell_measures": "area: areacello", + "long_name": "Compressive Sea Ice Strength", + "comment": "Computed strength of the ice pack, defined as the energy (J m-2) dissipated per unit area removed from the ice pack under compression, and assumed proportional to the change in potential energy caused by ridging. For Hibler-type models, this is P (= P*h exp(-C(1-A)) where P* is compressive strength, h ice thickness, A compactness and C strength reduction constant).", "dimensions": "longitude latitude time", "out_name": "sicompstren", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -117,13 +123,14 @@ "ok_max_mean_abs": "" }, "siconc": { + "frequency": "mon", "modeling_realm": "seaIce", "standard_name": "sea_ice_area_fraction", "units": "%", "cell_methods": "area: mean where sea time: mean", "cell_measures": "area: areacello", - "long_name": "Sea Ice Area Fraction", - "comment": "Area fraction of grid cell covered by sea ice", + "long_name": "Sea-Ice Area Percentage (Ocean Grid)", + "comment": "Percentage of grid cell covered by sea ice", "dimensions": "longitude latitude time typesi", "out_name": "siconc", "type": "real", @@ -133,16 +140,17 @@ "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, - "siconco": { + "siconca": { + "frequency": "mon", "modeling_realm": "seaIce", "standard_name": "sea_ice_area_fraction", "units": "%", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Sea Ice Area Fraction", - "comment": "Area fraction of grid cell covered by sea ice", + "long_name": "Sea-Ice Area Percentage (Atmospheric Grid)", + "comment": "Percentage of grid cell covered by sea ice", "dimensions": "longitude latitude time typesi", - "out_name": "siconco", + "out_name": "siconca", "type": "real", "positive": "", "valid_min": "", @@ -151,16 +159,17 @@ "ok_max_mean_abs": "" }, "sidconcdyn": { + "frequency": "mon", "modeling_realm": "seaIce", "standard_name": "tendency_of_sea_ice_area_fraction_due_to_dynamics", "units": "s-1", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "sea-ice area fraction change from dynamics", + "cell_methods": "area: mean where sea time: mean", + "cell_measures": "area: areacello", + "long_name": "Sea-Ice Area Percentage Tendency Due to Dynamics", "comment": "Total change in sea-ice area fraction through dynamics-related processes (advection, divergence...)", "dimensions": "longitude latitude time", "out_name": "sidconcdyn", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -168,16 +177,17 @@ "ok_max_mean_abs": "" }, "sidconcth": { + "frequency": "mon", "modeling_realm": "seaIce", "standard_name": "tendency_of_sea_ice_area_fraction_due_to_thermodynamics", "units": "s-1", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "sea-ice area fraction change from thermodynamics", + "cell_methods": "area: mean where sea time: mean", + "cell_measures": "area: areacello", + "long_name": "Sea-Ice Area Percentage Tendency Due to Thermodynamics", "comment": "Total change in sea-ice area fraction through thermodynamic processes", "dimensions": "longitude latitude time", "out_name": "sidconcth", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -185,16 +195,17 @@ "ok_max_mean_abs": "" }, "sidivvel": { + "frequency": "monPt", "modeling_realm": "seaIce", "standard_name": "divergence_of_sea_ice_velocity", "units": "s-1", "cell_methods": "area: mean where sea_ice (comment: mask=siconc) time: point", - "cell_measures": "area: areacella", - "long_name": "Divergence of the sea-ice velocity field", + "cell_measures": "area: areacello", + "long_name": "Divergence of the Sea-Ice Velocity Field", "comment": "Divergence of sea-ice velocity field (first shear strain invariant)", "dimensions": "longitude latitude time1", "out_name": "sidivvel", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -202,16 +213,17 @@ "ok_max_mean_abs": "" }, "sidmassdyn": { + "frequency": "mon", "modeling_realm": "seaIce", - "standard_name": "tendency_of_sea_ice_amount_due_to_dynamics", + "standard_name": "tendency_of_sea_ice_amount_due_to_sea_ice_dynamics", "units": "kg m-2 s-1", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "sea-ice mass change from dynamics", + "cell_methods": "area: mean where sea time: mean", + "cell_measures": "area: areacello", + "long_name": "Sea-Ice Mass Change from Dynamics", "comment": "Total change in sea-ice mass through dynamics-related processes (advection,...) divided by grid-cell area", "dimensions": "longitude latitude time", "out_name": "sidmassdyn", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -219,33 +231,35 @@ "ok_max_mean_abs": "" }, "sidmassevapsubl": { + "frequency": "mon", "modeling_realm": "seaIce", - "standard_name": "water_evaporation_flux", + "standard_name": "water_evapotranspiration_flux", "units": "kg m-2 s-1", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "sea-ice mass change through evaporation and sublimation", + "cell_methods": "area: mean where sea time: mean", + "cell_measures": "area: areacello", + "long_name": "Sea-Ice Mass Change Through Evaporation and Sublimation", "comment": "The rate of change of sea-ice mass change through evaporation and sublimation divided by grid-cell area", "dimensions": "longitude latitude time", "out_name": "sidmassevapsubl", - "type": "", - "positive": "", + "type": "real", + "positive": "up", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "sidmassgrowthbot": { + "frequency": "mon", "modeling_realm": "seaIce", "standard_name": "tendency_of_sea_ice_amount_due_to_congelation_ice_accumulation", "units": "kg m-2 s-1", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "sea-ice mass change through basal growth", + "cell_methods": "area: mean where sea time: mean", + "cell_measures": "area: areacello", + "long_name": "Sea-Ice Mass Change Through Basal Growth", "comment": "The rate of change of sea ice mass due to vertical growth of existing sea ice at its base divided by grid-cell area.", "dimensions": "longitude latitude time", "out_name": "sidmassgrowthbot", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -253,16 +267,17 @@ "ok_max_mean_abs": "" }, "sidmassgrowthwat": { + "frequency": "mon", "modeling_realm": "seaIce", - "standard_name": "tendency_of_sea_ice_amount_due_to_freezing_in_open_water", + "standard_name": "tendency_of_sea_ice_amount_due_to_frazil_ice_accumulation_in_leads", "units": "kg m-2 s-1", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "sea-ice mass change through growth in supercooled open water (aka frazil)", + "cell_methods": "area: mean where sea time: mean", + "cell_measures": "area: areacello", + "long_name": "Sea-Ice Mass Change Through Growth in Supercooled Open Water (Frazil)", "comment": "The rate of change of sea ice mass due to sea ice formation in supercooled water (often through frazil formation) divided by grid-cell area. Together, sidmassgrowthwat and sidmassgrowthbot should give total ice growth", "dimensions": "longitude latitude time", "out_name": "sidmassgrowthwat", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -270,16 +285,17 @@ "ok_max_mean_abs": "" }, "sidmasslat": { + "frequency": "mon", "modeling_realm": "seaIce", "standard_name": "tendency_of_sea_ice_amount_due_to_lateral_melting", "units": "kg m-2 s-1", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "Lateral sea ice melt rate", + "cell_methods": "area: mean where sea time: mean", + "cell_measures": "area: areacello", + "long_name": "Lateral Sea Ice Melt Rate", "comment": "The rate of change of sea ice mass through lateral melting divided by grid-cell area (report 0 if not explicitly calculated thermodynamically)", "dimensions": "longitude latitude time", "out_name": "sidmasslat", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -287,16 +303,17 @@ "ok_max_mean_abs": "" }, "sidmassmeltbot": { + "frequency": "mon", "modeling_realm": "seaIce", "standard_name": "tendency_of_sea_ice_amount_due_to_basal_melting", "units": "kg m-2 s-1", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "sea-ice mass change through bottom melting", + "cell_methods": "area: mean where sea time: mean", + "cell_measures": "area: areacello", + "long_name": "Sea-Ice Mass Change Through Bottom Melting", "comment": "The rate of change of sea ice mass through melting at the ice bottom divided by grid-cell area", "dimensions": "longitude latitude time", "out_name": "sidmassmeltbot", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -304,16 +321,17 @@ "ok_max_mean_abs": "" }, "sidmassmelttop": { + "frequency": "mon", "modeling_realm": "seaIce", "standard_name": "tendency_of_sea_ice_amount_due_to_surface_melting", "units": "kg m-2 s-1", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "sea-ice mass change through surface melting", + "cell_methods": "area: mean where sea time: mean", + "cell_measures": "area: areacello", + "long_name": "Sea-Ice Mass Change Through Surface Melting", "comment": "The rate of change of sea ice mass through melting at the ice surface divided by grid-cell area", "dimensions": "longitude latitude time", "out_name": "sidmassmelttop", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -321,16 +339,17 @@ "ok_max_mean_abs": "" }, "sidmasssi": { + "frequency": "mon", "modeling_realm": "seaIce", - "standard_name": "tendency_of_sea_ice_amount_due_to_snow_conversion", + "standard_name": "tendency_of_sea_ice_amount_due_to_conversion_of_snow_to_sea_ice", "units": "kg m-2 s-1", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "sea-ice mass change through snow-to-ice conversion", + "cell_methods": "area: mean where sea time: mean", + "cell_measures": "area: areacello", + "long_name": "Sea-Ice Mass Change Through Snow-to-Ice Conversion", "comment": "The rate of change of sea ice mass due to transformation of snow to sea ice divided by grid-cell area", "dimensions": "longitude latitude time", "out_name": "sidmasssi", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -338,16 +357,17 @@ "ok_max_mean_abs": "" }, "sidmassth": { + "frequency": "mon", "modeling_realm": "seaIce", - "standard_name": "tendency_of_sea_ice_amount_due_to_thermodynamics", + "standard_name": "tendency_of_sea_ice_amount_due_to_sea_ice_thermodynamics", "units": "kg m-2 s-1", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "sea-ice mass change from thermodynamics", + "cell_methods": "area: mean where sea time: mean", + "cell_measures": "area: areacello", + "long_name": "Sea-Ice Mass Change from Thermodynamics", "comment": "Total change in sea-ice mass from thermodynamic processes divided by grid-cell area", "dimensions": "longitude latitude time", "out_name": "sidmassth", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -355,16 +375,17 @@ "ok_max_mean_abs": "" }, "sidmasstranx": { + "frequency": "mon", "modeling_realm": "seaIce", "standard_name": "sea_ice_x_transport", "units": "kg s-1", "cell_methods": "time: mean", "cell_measures": "--MODEL", - "long_name": "X-component of sea-ice mass transport", + "long_name": "X-Component of Sea-Ice Mass Transport", "comment": "Includes transport of both sea ice and snow by advection", "dimensions": "longitude latitude time", "out_name": "sidmasstranx", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -372,16 +393,17 @@ "ok_max_mean_abs": "" }, "sidmasstrany": { + "frequency": "mon", "modeling_realm": "seaIce", "standard_name": "sea_ice_y_transport", "units": "kg s-1", "cell_methods": "time: mean", "cell_measures": "--MODEL", - "long_name": "Y-component of sea-ice mass transport", + "long_name": "Y-Component of Sea-Ice Mass Transport", "comment": "Includes transport of both sea ice and snow by advection", "dimensions": "longitude latitude time", "out_name": "sidmasstrany", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -389,16 +411,17 @@ "ok_max_mean_abs": "" }, "sidragbot": { + "frequency": "mon", "modeling_realm": "seaIce", - "standard_name": "surface_drag_coefficient_for_momentum_in_water", - "units": "1.0", + "standard_name": "sea_ice_basal_drag_coefficient_for_momentum_in_sea_water", + "units": "1", "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", - "cell_measures": "area: areacella", - "long_name": "Ocean drag coefficient", + "cell_measures": "area: areacello", + "long_name": "Ocean Drag Coefficient", "comment": "Oceanic drag coefficient that is used to calculate the oceanic momentum drag on sea ice", "dimensions": "longitude latitude time", "out_name": "sidragbot", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -406,16 +429,17 @@ "ok_max_mean_abs": "" }, "sidragtop": { + "frequency": "mon", "modeling_realm": "seaIce", "standard_name": "surface_drag_coefficient_for_momentum_in_air", - "units": "1.0", + "units": "1", "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", - "cell_measures": "area: areacella", - "long_name": "Atmospheric drag coefficient", + "cell_measures": "area: areacello", + "long_name": "Atmospheric Drag Coefficient", "comment": "Atmospheric drag coefficient that is used to calculate the atmospheric momentum drag on sea ice", "dimensions": "longitude latitude time", "out_name": "sidragtop", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -423,16 +447,17 @@ "ok_max_mean_abs": "" }, "siextentn": { + "frequency": "mon", "modeling_realm": "seaIce", "standard_name": "sea_ice_extent", "units": "1e6 km2", "cell_methods": "area: time: mean", "cell_measures": "", - "long_name": "Sea ice extent North", + "long_name": "Sea-Ice Extent North", "comment": "Total area of all Northern-Hemisphere grid cells that are covered by at least 15 % areal fraction of sea ice", "dimensions": "time", "out_name": "siextentn", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -440,16 +465,17 @@ "ok_max_mean_abs": "" }, "siextents": { + "frequency": "mon", "modeling_realm": "seaIce", "standard_name": "sea_ice_extent", "units": "1e6 km2", "cell_methods": "area: time: mean", "cell_measures": "", - "long_name": "Sea ice extent South", + "long_name": "Sea-Ice Extent South", "comment": "Total area of all Southern-Hemisphere grid cells that are covered by at least 15 % areal fraction of sea ice", "dimensions": "time", "out_name": "siextents", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -457,16 +483,17 @@ "ok_max_mean_abs": "" }, "sifb": { + "frequency": "mon", "modeling_realm": "seaIce", "standard_name": "sea_ice_freeboard", "units": "m", "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", - "cell_measures": "area: areacella", - "long_name": "Sea-ice freeboard", + "cell_measures": "area: areacello", + "long_name": "Sea-Ice Freeboard", "comment": "Mean height of sea-ice surface (=snow-ice interface when snow covered) above sea level", "dimensions": "longitude latitude time", "out_name": "sifb", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -474,50 +501,53 @@ "ok_max_mean_abs": "" }, "siflcondbot": { + "frequency": "mon", "modeling_realm": "seaIce", - "standard_name": "conductive_heat_flux_at_sea_ice_bottom", + "standard_name": "basal_downward_heat_flux_in_sea_ice", "units": "W m-2", "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", - "cell_measures": "area: areacella", - "long_name": "Net conductive heat fluxes in ice at the bottom", + "cell_measures": "area: areacello", + "long_name": "Net Conductive Heat Fluxes in Ice at the Bottom", "comment": "the net heat conduction flux at the ice base", "dimensions": "longitude latitude time", "out_name": "siflcondbot", - "type": "", - "positive": "", + "type": "real", + "positive": "down", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "siflcondtop": { + "frequency": "mon", "modeling_realm": "seaIce", - "standard_name": "conductive_heat_flux_at_sea_ice_surface", + "standard_name": "surface_downward_sensible_heat_flux", "units": "W m-2", "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", - "cell_measures": "area: areacella", - "long_name": "Net conductive heat flux in ice at the surface", + "cell_measures": "area: areacello", + "long_name": "Net Conductive Heat Flux in Ice at the Surface", "comment": "the net heat conduction flux at the ice surface", "dimensions": "longitude latitude time", "out_name": "siflcondtop", - "type": "", - "positive": "", + "type": "real", + "positive": "down", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "siflfwbot": { + "frequency": "mon", "modeling_realm": "seaIce", - "standard_name": "freshwater_flux_from_ice", + "standard_name": "water_flux_into_sea_water_due_to_sea_ice_thermodynamics", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", - "cell_measures": "area: areacella", - "long_name": "Freshwater flux from sea ice", + "cell_measures": "area: areacello", + "long_name": "Freshwater Flux from Sea Ice", "comment": "Total flux of fresh water from water into sea ice divided by grid-cell area; This flux is negative during ice growth (liquid water mass decreases, hence upward flux of freshwater), positive during ice melt (liquid water mass increases, hence downward flux of freshwater)", "dimensions": "longitude latitude time", "out_name": "siflfwbot", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -525,16 +555,17 @@ "ok_max_mean_abs": "" }, "siflfwdrain": { + "frequency": "mon", "modeling_realm": "seaIce", - "standard_name": "freshwater_flux_from_ice_surface", + "standard_name": "water_flux_into_sea_water_due_to_surface_drainage", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", - "cell_measures": "area: areacella", - "long_name": "Freshwater flux from sea-ice surface", + "cell_measures": "area: areacello", + "long_name": "Freshwater Flux from Sea-Ice Surface", "comment": "Total flux of fresh water from sea-ice surface into underlying ocean. This combines both surface melt water that drains directly into the ocean and the drainage of surface melt pond. By definition, this flux is always positive.", "dimensions": "longitude latitude time", "out_name": "siflfwdrain", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -542,169 +573,161 @@ "ok_max_mean_abs": "" }, "sifllatstop": { + "frequency": "mon", "modeling_realm": "seaIce", "standard_name": "surface_upward_latent_heat_flux", "units": "W m-2", - "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", + "cell_methods": "area: time: mean where sea_ice (comment: mask=siconca)", "cell_measures": "area: areacella", - "long_name": "Net latent heat flux over sea ice", + "long_name": "Net Latent Heat Flux over Sea Ice", "comment": "the net latent heat flux over sea ice", "dimensions": "longitude latitude time", "out_name": "sifllatstop", - "type": "", - "positive": "", + "type": "real", + "positive": "up", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "sifllwdtop": { + "frequency": "mon", "modeling_realm": "seaIce", "standard_name": "surface_downwelling_longwave_flux_in_air", "units": "W m-2", - "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", + "cell_methods": "area: time: mean where sea_ice (comment: mask=siconca)", "cell_measures": "area: areacella", - "long_name": "Downwelling longwave flux over sea ice", + "long_name": "Downwelling Longwave Flux over Sea Ice", "comment": "the downwelling longwave flux over sea ice (always positive)", "dimensions": "longitude latitude time", "out_name": "sifllwdtop", - "type": "", - "positive": "", + "type": "real", + "positive": "down", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "sifllwutop": { + "frequency": "mon", "modeling_realm": "seaIce", "standard_name": "surface_upwelling_longwave_flux_in_air", "units": "W m-2", - "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", + "cell_methods": "area: time: mean where sea_ice (comment: mask=siconca)", "cell_measures": "area: areacella", - "long_name": "Upward longwave flux over sea ice", - "comment": "the upward longwave flux over sea ice (always negative)", + "long_name": "Upwelling Longwave Flux over Sea Ice", + "comment": "the upwelling longwave flux over sea ice (always negative)", "dimensions": "longitude latitude time", "out_name": "sifllwutop", - "type": "", - "positive": "", - "valid_min": "", - "valid_max": "", - "ok_min_mean_abs": "", - "ok_max_mean_abs": "" - }, - "siflsaltbot": { - "modeling_realm": "seaIce", - "standard_name": "salt_flux_from_ice", - "units": "kg m-2 s-1", - "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", - "cell_measures": "area: areacella", - "long_name": "Salt flux from sea ice", - "comment": "Total flux of salt from water into sea ice divided by grid-cell area; salt flux is upward (negative) during ice growth when salt is embedded into the ice and downward (positive) during melt when salt from sea ice is again released to the ocean", - "dimensions": "longitude latitude time", - "out_name": "siflsaltbot", - "type": "", - "positive": "", + "type": "real", + "positive": "up", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "siflsenstop": { + "frequency": "mon", "modeling_realm": "seaIce", "standard_name": "surface_upward_sensible_heat_flux", "units": "W m-2", - "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", + "cell_methods": "area: time: mean where sea_ice (comment: mask=siconca)", "cell_measures": "area: areacella", - "long_name": "Net sensible heat flux over sea ice", + "long_name": "Net Upward Sensible Heat Flux over Sea Ice", "comment": "the net sensible heat flux over sea ice", "dimensions": "longitude latitude time", "out_name": "siflsenstop", - "type": "", - "positive": "", + "type": "real", + "positive": "up", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "siflsensupbot": { + "frequency": "mon", "modeling_realm": "seaIce", - "standard_name": "ice_ocean_heat_flux", + "standard_name": "upward_sea_ice_basal_heat_flux", "units": "W m-2", "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", - "cell_measures": "area: areacella", - "long_name": "Net sensible heat flux under sea ice", + "cell_measures": "area: areacello", + "long_name": "Net Upward Sensible Heat Flux Under Sea Ice", "comment": "the net sensible heat flux under sea ice from the ocean", "dimensions": "longitude latitude time", "out_name": "siflsensupbot", - "type": "", - "positive": "", + "type": "real", + "positive": "up", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "siflswdbot": { + "frequency": "mon", "modeling_realm": "seaIce", - "standard_name": "bottom_downwelling_shortwave_flux_into_ocean", + "standard_name": "downwelling_shortwave_flux_in_sea_water_at_sea_ice_base", "units": "W m-2", "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", - "cell_measures": "area: areacella", - "long_name": "Downwelling shortwave flux under sea ice", - "comment": "the downwelling shortwave flux underneath sea ice (always positive)", + "cell_measures": "area: areacello", + "long_name": "Downwelling Shortwave Flux Under Sea Ice", + "comment": "The downwelling shortwave flux underneath sea ice (always positive)", "dimensions": "longitude latitude time", "out_name": "siflswdbot", - "type": "", - "positive": "", + "type": "real", + "positive": "down", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "siflswdtop": { + "frequency": "mon", "modeling_realm": "seaIce", "standard_name": "surface_downwelling_shortwave_flux_in_air", "units": "W m-2", - "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", + "cell_methods": "area: time: mean where sea_ice (comment: mask=siconca)", "cell_measures": "area: areacella", - "long_name": "Downwelling shortwave flux over sea ice", - "comment": "the downwelling shortwave flux over sea ice (always positive by sign convention)", + "long_name": "Downwelling Shortwave Flux over Sea Ice", + "comment": "The downwelling shortwave flux over sea ice (always positive by sign convention)", "dimensions": "longitude latitude time", "out_name": "siflswdtop", - "type": "", - "positive": "", + "type": "real", + "positive": "down", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "siflswutop": { + "frequency": "mon", "modeling_realm": "seaIce", "standard_name": "surface_upwelling_shortwave_flux_in_air", "units": "W m-2", - "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", + "cell_methods": "area: time: mean where sea_ice (comment: mask=siconca)", "cell_measures": "area: areacella", - "long_name": "Upward shortwave flux over sea ice", - "comment": "the upward shortwave flux over sea ice (always negative)", + "long_name": "Upwelling Shortwave Flux over Sea Ice", + "comment": "The upwelling shortwave flux over sea ice (always negative)", "dimensions": "longitude latitude time", "out_name": "siflswutop", - "type": "", - "positive": "", + "type": "real", + "positive": "up", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "siforcecoriolx": { + "frequency": "mon", "modeling_realm": "seaIce", - "standard_name": "coriolis_force_on_sea_ice_x", + "standard_name": "sea_ice_x_force_per_unit_area_due_to_coriolis_effect", "units": "N m-2", "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", "cell_measures": "--MODEL", - "long_name": "Coriolis force term in force balance (x-component)", + "long_name": "Coriolis Force Term in Force Balance (X-Component)", "comment": "X-component of force on sea ice caused by coriolis force", "dimensions": "longitude latitude time", "out_name": "siforcecoriolx", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -712,16 +735,17 @@ "ok_max_mean_abs": "" }, "siforcecorioly": { + "frequency": "mon", "modeling_realm": "seaIce", - "standard_name": "coriolis_force_on_sea_ice_y", + "standard_name": "sea_ice_y_force_per_unit_area_due_to_coriolis_effect", "units": "N m-2", "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", "cell_measures": "--MODEL", - "long_name": "Coriolis force term in force balance (y-component)", + "long_name": "Coriolis Force Term in Force Balance (Y-Component)", "comment": "Y-component of force on sea ice caused by coriolis force", "dimensions": "longitude latitude time", "out_name": "siforcecorioly", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -729,16 +753,17 @@ "ok_max_mean_abs": "" }, "siforceintstrx": { + "frequency": "mon", "modeling_realm": "seaIce", - "standard_name": "internal_stress_in_sea_ice_x", + "standard_name": "sea_ice_x_internal_stress", "units": "N m-2", "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", "cell_measures": "--MODEL", - "long_name": "Internal stress term in force balance (x-component)", + "long_name": "Internal Stress Term in Force Balance (X-Component)", "comment": "X-component of force on sea ice caused by internal stress (divergence of sigma)", "dimensions": "longitude latitude time", "out_name": "siforceintstrx", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -746,16 +771,17 @@ "ok_max_mean_abs": "" }, "siforceintstry": { + "frequency": "mon", "modeling_realm": "seaIce", - "standard_name": "internal_stress_in_sea_ice_y", + "standard_name": "sea_ice_y_internal_stress", "units": "N m-2", "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", "cell_measures": "--MODEL", - "long_name": "Internal stress term in force balance (y-component)", + "long_name": "Internal Stress Term in Force Balance (Y-Component)", "comment": "Y-component of force on sea ice caused by internal stress (divergence of sigma)", "dimensions": "longitude latitude time", "out_name": "siforceintstry", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -763,16 +789,17 @@ "ok_max_mean_abs": "" }, "siforcetiltx": { + "frequency": "mon", "modeling_realm": "seaIce", - "standard_name": "sea_surface_tilt_force_on_sea_ice_x", + "standard_name": "sea_ice_x_force_per_unit_area_due_to_sea_surface_tilt", "units": "N m-2", "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", "cell_measures": "--MODEL", - "long_name": "Sea-surface tilt term in force balance (x-component)", + "long_name": "Sea-Surface Tilt Term in Force Balance (X-Component)", "comment": "X-component of force on sea ice caused by sea-surface tilt", "dimensions": "longitude latitude time", "out_name": "siforcetiltx", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -780,16 +807,17 @@ "ok_max_mean_abs": "" }, "siforcetilty": { + "frequency": "mon", "modeling_realm": "seaIce", - "standard_name": "sea_surface_tilt_force_on_sea_ice_y", + "standard_name": "sea_ice_y_force_per_unit_area_due_to_sea_surface_tilt", "units": "N m-2", "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", "cell_measures": "--MODEL", - "long_name": "Sea-surface tilt term in force balance (y-component)", + "long_name": "Sea-Surface Tilt Term in Force Balance (Y-Component)", "comment": "Y-component of force on sea ice caused by sea-surface tilt", "dimensions": "longitude latitude time", "out_name": "siforcetilty", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -797,16 +825,17 @@ "ok_max_mean_abs": "" }, "sihc": { + "frequency": "mon", "modeling_realm": "seaIce", - "standard_name": "integral_of_sea_ice_temperature_wrt_depth_expressed_as_heat_content", + "standard_name": "sea_ice_temperature_expressed_as_heat_content", "units": "J m-2", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "Sea-ice heat content per unit area", + "cell_methods": "area: mean where sea time: mean", + "cell_measures": "area: areacello", + "long_name": "Sea-Ice Heat Content per Unit Area", "comment": "Heat content of all ice in grid cell divided by total grid-cell area. Water at 0 Celsius is assumed to have a heat content of 0 J. Does not include heat content of snow, but does include heat content of brine. Heat content is always negative, since both the sensible and the latent heat content of ice are less than that of water", "dimensions": "longitude latitude time", "out_name": "sihc", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -814,16 +843,17 @@ "ok_max_mean_abs": "" }, "siitdconc": { + "frequency": "mon", "modeling_realm": "seaIce", - "standard_name": "sea_ice_area_fraction_over_categories", + "standard_name": "sea_ice_area_fraction", "units": "%", "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", - "cell_measures": "area: areacella", - "long_name": "Sea-ice area fractions in thickness categories", - "comment": "Area fraction of grid cell covered by each ice-thickness category (vector with one entry for each thickness category starting from the thinnest category, netcdf file should use thickness bounds of the categories as third coordinate axis)", + "cell_measures": "area: areacello", + "long_name": "Sea-Ice Area Percentages in Thickness Categories", + "comment": "Percentage of grid cell covered by each ice-thickness category (vector with one entry for each thickness category starting from the thinnest category, netcdf file should use thickness bounds of the categories as third coordinate axis)", "dimensions": "longitude latitude iceband time", "out_name": "siitdconc", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -831,16 +861,17 @@ "ok_max_mean_abs": "" }, "siitdsnconc": { + "frequency": "mon", "modeling_realm": "seaIce", - "standard_name": "snow_area_fraction_over_categories", + "standard_name": "surface_snow_area_fraction", "units": "%", "cell_methods": "area: time: mean where sea_ice (comment: mask=siitdconc)", - "cell_measures": "area: areacella", - "long_name": "Snow area fractions in thickness categories", - "comment": "Area fraction of grid cell covered by snow in each ice-thickness category (vector with one entry for each thickness category starting from the thinnest category, netcdf file should use thickness bounds of the categories as third coordinate axis)", + "cell_measures": "area: areacello", + "long_name": "Snow Area Percentages in Ice Thickness Categories", + "comment": "Percentage of grid cell covered by snow in each ice-thickness category (vector with one entry for each thickness category starting from the thinnest category, netcdf file should use thickness bounds of the categories as third coordinate axis)", "dimensions": "longitude latitude iceband time", "out_name": "siitdsnconc", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -848,16 +879,17 @@ "ok_max_mean_abs": "" }, "siitdsnthick": { + "frequency": "mon", "modeling_realm": "seaIce", - "standard_name": "snow_thickness_over_categories", + "standard_name": "surface_snow_thickness", "units": "m", "cell_methods": "area: time: mean where sea_ice (comment: mask=siitdconc)", - "cell_measures": "area: areacella", - "long_name": "Snow thickness in thickness categories", + "cell_measures": "area: areacello", + "long_name": "Snow Thickness in Ice Thickness Categories", "comment": "Actual thickness of snow in each category (NOT volume divided by grid area), (vector with one entry for each thickness category starting from the thinnest category, netcdf file should use thickness bounds of categories as third coordinate axis)", "dimensions": "longitude latitude iceband time", "out_name": "siitdsnthick", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -865,16 +897,17 @@ "ok_max_mean_abs": "" }, "siitdthick": { + "frequency": "mon", "modeling_realm": "seaIce", - "standard_name": "sea_ice_thickness_over_categories", + "standard_name": "sea_ice_thickness", "units": "m", "cell_methods": "area: time: mean where sea_ice (comment: mask=siitdconc)", - "cell_measures": "area: areacella", - "long_name": "Sea-ice thickness in thickness categories", + "cell_measures": "area: areacello", + "long_name": "Sea-Ice Thickness in Thickness Categories", "comment": "Actual (floe) thickness of sea ice in each category (NOT volume divided by grid area), (vector with one entry for each thickness category starting from the thinnest category, netcdf file should use thickness bounds of categories as third coordinate axis)", "dimensions": "longitude latitude iceband time", "out_name": "siitdthick", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -882,16 +915,17 @@ "ok_max_mean_abs": "" }, "simass": { + "frequency": "mon", "modeling_realm": "seaIce", "standard_name": "sea_ice_amount", "units": "kg m-2", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "Sea-ice mass per area", + "cell_methods": "area: mean where sea time: mean", + "cell_measures": "area: areacello", + "long_name": "Sea-Ice Mass per Area", "comment": "Total mass of sea ice divided by grid-cell area", "dimensions": "longitude latitude time", "out_name": "simass", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -899,16 +933,17 @@ "ok_max_mean_abs": "" }, "simassacrossline": { + "frequency": "mon", "modeling_realm": "seaIce", "standard_name": "sea_ice_transport_across_line", "units": "kg s-1", "cell_methods": "time: mean", - "cell_measures": "area: areacella", - "long_name": "Sea mass area flux through straits", - "comment": "net (sum of transport in all directions) sea ice area transport through the following four passages, positive into the Arctic Ocean 1. Fram Strait = (11.5W,81.3N to (10.5E,79.6N) 2. Canadian Archipelego = (128.2W,70.6N) to (59.3W,82.1N) 3. Barents opening = (16.8E,76.5N) to (19.2E,70.2N) 4. Bering Strait = (171W,66.2N) to (166W,65N)", + "cell_measures": "", + "long_name": "Sea Mass Area Flux Through Straits", + "comment": "net (sum of transport in all directions) sea ice area transport through the following four passages, positive into the Arctic Ocean 1. Fram Strait = (11.5W,81.3N to (10.5E,79.6N) 2. Canadian Archipelago = (128.2W,70.6N) to (59.3W,82.1N) 3. Barents opening = (16.8E,76.5N) to (19.2E,70.2N) 4. Bering Strait = (171W,66.2N) to (166W,65N)", "dimensions": "siline time", "out_name": "simassacrossline", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -916,16 +951,17 @@ "ok_max_mean_abs": "" }, "simpconc": { + "frequency": "mon", "modeling_realm": "seaIce", "standard_name": "area_fraction", "units": "%", "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", - "cell_measures": "area: areacella", - "long_name": "Percentage Cover of Sea-Ice by Meltpond", - "comment": "Fraction of sea ice, by area, which is covered by melt ponds, giving equal weight to every square metre of sea ice .", + "cell_measures": "area: areacello", + "long_name": "Percentage Cover of Sea Ice by Meltpond", + "comment": "Percentage of sea ice, by area, which is covered by melt ponds, giving equal weight to every square metre of sea ice .", "dimensions": "longitude latitude time typemp", "out_name": "simpconc", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -933,16 +969,17 @@ "ok_max_mean_abs": "" }, "simpmass": { + "frequency": "mon", "modeling_realm": "seaIce", - "standard_name": "surface_liquid_water_amount", - "units": "kg m-2", + "standard_name": "sea_ice_melt_pond_thickness", + "units": "m", "cell_methods": "area: time: mean where sea_ice_melt_pond (comment: mask=simpconc)", - "cell_measures": "area: areacella", - "long_name": "Meltpond Mass per Unit Area", - "comment": "Meltpond mass per area of sea ice.", + "cell_measures": "area: areacello", + "long_name": "Meltpond Mass per Unit Area (as Depth)", + "comment": "Meltpond Depth", "dimensions": "longitude latitude time", "out_name": "simpmass", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -950,16 +987,17 @@ "ok_max_mean_abs": "" }, "simprefrozen": { + "frequency": "mon", "modeling_realm": "seaIce", - "standard_name": "melt_pond_refrozen_ice", + "standard_name": "thickness_of_ice_on_sea_ice_melt_pond", "units": "m", "cell_methods": "area: time: mean where sea_ice_melt_pond (comment: mask=simpconc)", - "cell_measures": "area: areacella", + "cell_measures": "area: areacello", "long_name": "Thickness of Refrozen Ice on Melt Pond", "comment": "Volume of refrozen ice on melt ponds divided by meltpond covered area", "dimensions": "longitude latitude time", "out_name": "simprefrozen", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -967,16 +1005,17 @@ "ok_max_mean_abs": "" }, "sipr": { + "frequency": "mon", "modeling_realm": "seaIce", "standard_name": "rainfall_flux", "units": "kg m-2 s-1", "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", - "cell_measures": "area: areacella", - "long_name": "Rainfall rate over sea ice", + "cell_measures": "area: areacello", + "long_name": "Rainfall Rate over Sea Ice", "comment": "mass of liquid precipitation falling onto sea ice divided by grid-cell area", "dimensions": "longitude latitude time", "out_name": "sipr", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -984,16 +1023,17 @@ "ok_max_mean_abs": "" }, "sirdgconc": { + "frequency": "mon", "modeling_realm": "seaIce", - "standard_name": "fraction_of_ridged_sea_ice", - "units": "1.0", + "standard_name": "area_fraction", + "units": "1", "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", - "cell_measures": "area: areacella", - "long_name": "Percentage Cover of Sea-Ice by Ridging", + "cell_measures": "area: areacello", + "long_name": "Percentage Cover of Sea Ice by Ridging", "comment": "Fraction of sea ice, by area, which is covered by sea ice ridges, giving equal weight to every square metre of sea ice .", - "dimensions": "longitude latitude time", + "dimensions": "longitude latitude time typesirdg", "out_name": "sirdgconc", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1001,16 +1041,17 @@ "ok_max_mean_abs": "" }, "sirdgthick": { + "frequency": "mon", "modeling_realm": "seaIce", - "standard_name": "thickness_of_ridged_sea_ice", + "standard_name": "sea_ice_thickness", "units": "m", - "cell_methods": "area: time: mean where sea_ice (comment: mask=sirdgconc - ridges only)", - "cell_measures": "area: areacella", - "long_name": "Ridged ice thickness", + "cell_methods": "area: time: mean where sea_ice_ridges (comment: mask=sirdgconc)", + "cell_measures": "area: areacello", + "long_name": "Ridged Ice Thickness", "comment": "Sea Ice Ridge Height (representing mean height over the ridged area)", "dimensions": "longitude latitude time", "out_name": "sirdgthick", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1018,16 +1059,17 @@ "ok_max_mean_abs": "" }, "sisali": { + "frequency": "mon", "modeling_realm": "seaIce", "standard_name": "sea_ice_salinity", "units": "0.001", "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", - "cell_measures": "area: areacella", - "long_name": "Sea ice salinity", + "cell_measures": "area: areacello", + "long_name": "Sea Ice Salinity", "comment": "Mean sea-ice salinity of all sea ice in grid cell", "dimensions": "longitude latitude time", "out_name": "sisali", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1035,16 +1077,17 @@ "ok_max_mean_abs": "" }, "sisaltmass": { + "frequency": "mon", "modeling_realm": "seaIce", - "standard_name": "sea_ice_salt_mass", + "standard_name": "sea_ice_mass_content_of_salt", "units": "kg m-2", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "Mass of salt in sea ice per area", + "cell_methods": "area: mean where sea time: mean", + "cell_measures": "area: areacello", + "long_name": "Mass of Salt in Sea Ice per Area", "comment": "Total mass of all salt in sea ice divided by grid-cell area", "dimensions": "longitude latitude time", "out_name": "sisaltmass", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1052,16 +1095,17 @@ "ok_max_mean_abs": "" }, "sishevel": { + "frequency": "monPt", "modeling_realm": "seaIce", - "standard_name": "maximum_shear_of_sea_ice_velocity", + "standard_name": "maximum_over_coordinate_rotation_of_sea_ice_horizontal_shear_strain_rate", "units": "s-1", "cell_methods": "area: mean where sea_ice (comment: mask=siconc) time: point", - "cell_measures": "area: areacella", - "long_name": "Maximum shear of sea-ice velocity field", + "cell_measures": "area: areacello", + "long_name": "Maximum Shear of Sea-Ice Velocity Field", "comment": "Maximum shear of sea-ice velocity field (second shear strain invariant)", "dimensions": "longitude latitude time1", "out_name": "sishevel", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1069,16 +1113,17 @@ "ok_max_mean_abs": "" }, "sisnconc": { + "frequency": "mon", "modeling_realm": "seaIce", "standard_name": "surface_snow_area_fraction", "units": "%", "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", - "cell_measures": "area: areacella", - "long_name": "Snow area fraction", - "comment": "Fraction of sea ice, by area, which is covered by snow, giving equal weight to every square metre of sea ice . Exclude snow that lies on land or land ice.", + "cell_measures": "area: areacello", + "long_name": "Snow Area Percentage", + "comment": "Percentage of sea ice, by area, which is covered by snow, giving equal weight to every square metre of sea ice . Exclude snow that lies on land or land ice.", "dimensions": "longitude latitude time", "out_name": "sisnconc", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1086,16 +1131,17 @@ "ok_max_mean_abs": "" }, "sisnhc": { + "frequency": "mon", "modeling_realm": "seaIce", "standard_name": "thermal_energy_content_of_surface_snow", "units": "J m-2", "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", - "cell_measures": "area: areacella", - "long_name": "Snow-heat content per unit area", + "cell_measures": "area: areacello", + "long_name": "Snow Heat Content per Unit Area", "comment": "Heat-content of all snow in grid cell divided by total grid-cell area. Snow-water equivalent at 0 Celsius is assumed to have a heat content of 0 J. Does not include heat content of sea ice.", "dimensions": "longitude latitude time", "out_name": "sisnhc", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1103,16 +1149,17 @@ "ok_max_mean_abs": "" }, "sisnmass": { + "frequency": "mon", "modeling_realm": "seaIce", "standard_name": "liquid_water_content_of_surface_snow", "units": "kg m-2", "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", - "cell_measures": "area: areacella", - "long_name": "Snow mass per area", - "comment": "Total mass of snow on sea ice divided by grid-cell area", + "cell_measures": "area: areacello", + "long_name": "Snow Mass per Area", + "comment": "Total mass of snow on sea ice divided by sea-ice area.", "dimensions": "longitude latitude time", "out_name": "sisnmass", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1120,16 +1167,17 @@ "ok_max_mean_abs": "" }, "sisnthick": { + "frequency": "mon", "modeling_realm": "seaIce", "standard_name": "surface_snow_thickness", "units": "m", "cell_methods": "area: mean where snow over sea_ice area: time: mean where sea_ice", - "cell_measures": "area: areacella", - "long_name": "Snow thickness", + "cell_measures": "area: areacello", + "long_name": "Snow Thickness", "comment": "Actual thickness of snow (snow volume divided by snow-covered area)", "dimensions": "longitude latitude time", "out_name": "sisnthick", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1137,16 +1185,17 @@ "ok_max_mean_abs": "" }, "sispeed": { + "frequency": "mon", "modeling_realm": "seaIce", "standard_name": "sea_ice_speed", "units": "m s-1", "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", - "cell_measures": "area: areacella", - "long_name": "Sea-ice speed", + "cell_measures": "area: areacello", + "long_name": "Sea-Ice Speed", "comment": "Speed of ice (i.e. mean absolute velocity) to account for back-and-forth movement of the ice", "dimensions": "longitude latitude time", "out_name": "sispeed", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1154,16 +1203,17 @@ "ok_max_mean_abs": "" }, "sistremax": { + "frequency": "monPt", "modeling_realm": "seaIce", - "standard_name": "maximum_shear_stress", + "standard_name": "maximum_over_coordinate_rotation_of_sea_ice_horizontal_shear_stress", "units": "N m-1", "cell_methods": "area: mean where sea_ice (comment: mask=siconc) time: point", - "cell_measures": "area: areacella", - "long_name": "Maximum shear stress in sea ice", + "cell_measures": "area: areacello", + "long_name": "Maximum Shear Stress in Sea Ice", "comment": "Maximum shear stress in sea ice (second stress invariant)", "dimensions": "longitude latitude time1", "out_name": "sistremax", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1171,16 +1221,17 @@ "ok_max_mean_abs": "" }, "sistresave": { + "frequency": "monPt", "modeling_realm": "seaIce", - "standard_name": "average_normal_stress", + "standard_name": "sea_ice_average_normal_horizontal_stress", "units": "N m-1", "cell_methods": "area: mean where sea_ice (comment: mask=siconc) time: point", - "cell_measures": "area: areacella", - "long_name": "Average normal stress in sea ice", + "cell_measures": "area: areacello", + "long_name": "Average Normal Stress in Sea Ice", "comment": "Average normal stress in sea ice (first stress invariant)", "dimensions": "longitude latitude time1", "out_name": "sistresave", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1188,84 +1239,89 @@ "ok_max_mean_abs": "" }, "sistrxdtop": { + "frequency": "mon", "modeling_realm": "seaIce", "standard_name": "surface_downward_x_stress", "units": "N m-2", "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", "cell_measures": "--MODEL", - "long_name": "X-component of atmospheric stress on sea ice", + "long_name": "X-Component of Atmospheric Stress on Sea Ice", "comment": "X-component of atmospheric stress on sea ice", "dimensions": "longitude latitude time", "out_name": "sistrxdtop", - "type": "", - "positive": "", + "type": "real", + "positive": "down", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "sistrxubot": { + "frequency": "mon", "modeling_realm": "seaIce", - "standard_name": "sea_ice_base_upward_x_stress", + "standard_name": "upward_x_stress_at_sea_ice_base", "units": "N m-2", "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", - "cell_measures": "area: areacella", - "long_name": "X-component of ocean stress on sea ice", + "cell_measures": "area: areacello", + "long_name": "X-Component of Ocean Stress on Sea Ice", "comment": "X-component of ocean stress on sea ice", "dimensions": "longitude latitude time", "out_name": "sistrxubot", - "type": "", - "positive": "", + "type": "real", + "positive": "up", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "sistrydtop": { + "frequency": "mon", "modeling_realm": "seaIce", "standard_name": "surface_downward_y_stress", "units": "N m-2", "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", "cell_measures": "--MODEL", - "long_name": "Y-component of atmospheric stress on sea ice", + "long_name": "Y-Component of Atmospheric Stress on Sea Ice", "comment": "Y-component of atmospheric stress on sea ice", "dimensions": "longitude latitude time", "out_name": "sistrydtop", - "type": "", - "positive": "", + "type": "real", + "positive": "down", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "sistryubot": { + "frequency": "mon", "modeling_realm": "seaIce", - "standard_name": "downward_y_stress_at_sea_ice_base", + "standard_name": "upward_y_stress_at_sea_ice_base", "units": "N m-2", "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", - "cell_measures": "area: areacella", - "long_name": "Y-component of ocean stress on sea ice", + "cell_measures": "area: areacello", + "long_name": "Y-Component of Ocean Stress on Sea Ice", "comment": "Y-component of ocean stress on sea ice", "dimensions": "longitude latitude time", "out_name": "sistryubot", - "type": "", - "positive": "", + "type": "real", + "positive": "up", "valid_min": "", "valid_max": "", "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, "sitempbot": { + "frequency": "mon", "modeling_realm": "seaIce", - "standard_name": "sea_ice_bottom_temperature", + "standard_name": "sea_ice_basal_temperature", "units": "K", "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", - "cell_measures": "area: areacella", - "long_name": "Temperature at ice-ocean interface", + "cell_measures": "area: areacello", + "long_name": "Temperature at Ice-Ocean Interface", "comment": "Report temperature at interface, NOT temperature within lowermost model layer", "dimensions": "longitude latitude time", "out_name": "sitempbot", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1273,16 +1329,17 @@ "ok_max_mean_abs": "" }, "sitempsnic": { + "frequency": "mon", "modeling_realm": "seaIce", "standard_name": "sea_ice_surface_temperature", "units": "K", "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", - "cell_measures": "area: areacella", - "long_name": "Temperature at snow-ice interface", + "cell_measures": "area: areacello", + "long_name": "Temperature at Snow-Ice Interface", "comment": "Report surface temperature of ice where snow thickness is zero", "dimensions": "longitude latitude time", "out_name": "sitempsnic", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1290,16 +1347,17 @@ "ok_max_mean_abs": "" }, "sitemptop": { + "frequency": "mon", "modeling_realm": "seaIce", "standard_name": "sea_ice_surface_temperature", "units": "K", "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", - "cell_measures": "area: areacella", - "long_name": "Surface temperature of sea ice", + "cell_measures": "area: areacello", + "long_name": "Surface Temperature of Sea Ice", "comment": "Report surface temperature of snow where snow covers the sea ice.", "dimensions": "longitude latitude time", "out_name": "sitemptop", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1307,11 +1365,12 @@ "ok_max_mean_abs": "" }, "sithick": { + "frequency": "mon", "modeling_realm": "seaIce ocean", "standard_name": "sea_ice_thickness", "units": "m", "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", - "cell_measures": "area: areacella", + "cell_measures": "area: areacello", "long_name": "Sea Ice Thickness", "comment": "Actual (floe) thickness of sea ice (NOT volume divided by grid area as was done in CMIP5)", "dimensions": "longitude latitude time", @@ -1324,16 +1383,17 @@ "ok_max_mean_abs": "" }, "sitimefrac": { + "frequency": "mon", "modeling_realm": "seaIce", - "standard_name": "sea_ice_time_fraction", - "units": "1.0", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "Fraction of time steps with sea ice", + "standard_name": "fraction_of_time_with_sea_ice_area_fraction_above_threshold", + "units": "1", + "cell_methods": "area: mean where sea time: mean", + "cell_measures": "area: areacello", + "long_name": "Fraction of Time Steps with Sea Ice", "comment": "Fraction of time steps of the averaging period during which sea ice is present (siconc >0 ) in a grid cell", "dimensions": "longitude latitude time", "out_name": "sitimefrac", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1341,16 +1401,17 @@ "ok_max_mean_abs": "" }, "siu": { + "frequency": "mon", "modeling_realm": "seaIce", "standard_name": "sea_ice_x_velocity", "units": "m s-1", "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", "cell_measures": "--MODEL", - "long_name": "X-component of sea ice velocity", + "long_name": "X-Component of Sea-Ice Velocity", "comment": "The x-velocity of ice on native model grid", "dimensions": "longitude latitude time", "out_name": "siu", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1358,16 +1419,17 @@ "ok_max_mean_abs": "" }, "siv": { + "frequency": "mon", "modeling_realm": "seaIce", "standard_name": "sea_ice_y_velocity", "units": "m s-1", "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", "cell_measures": "--MODEL", - "long_name": "Y-component of sea ice velocity", + "long_name": "Y-Component of Sea-Ice Velocity", "comment": "The y-velocity of ice on native model grid", "dimensions": "longitude latitude time", "out_name": "siv", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1375,16 +1437,17 @@ "ok_max_mean_abs": "" }, "sivol": { + "frequency": "mon", "modeling_realm": "seaIce", "standard_name": "sea_ice_thickness", "units": "m", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "Sea-ice volume per area", + "cell_methods": "area: mean where sea time: mean", + "cell_measures": "area: areacello", + "long_name": "Sea-Ice Volume per Area", "comment": "Total volume of sea ice divided by grid-cell area (this used to be called ice thickness in CMIP5)", "dimensions": "longitude latitude time", "out_name": "sivol", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1392,16 +1455,17 @@ "ok_max_mean_abs": "" }, "sivoln": { + "frequency": "mon", "modeling_realm": "seaIce", "standard_name": "sea_ice_volume", "units": "1e3 km3", "cell_methods": "area: time: mean", "cell_measures": "", - "long_name": "Sea ice volume North", + "long_name": "Sea-Ice Volume North", "comment": "total volume of sea ice in the Northern hemisphere", "dimensions": "time", "out_name": "sivoln", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1409,16 +1473,17 @@ "ok_max_mean_abs": "" }, "sivols": { + "frequency": "mon", "modeling_realm": "seaIce", "standard_name": "sea_ice_volume", "units": "1e3 km3", "cell_methods": "area: time: mean", "cell_measures": "", - "long_name": "Sea ice volume South", + "long_name": "Sea-Ice Volume South", "comment": "total volume of sea ice in the Southern hemisphere", "dimensions": "time", "out_name": "sivols", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1426,16 +1491,17 @@ "ok_max_mean_abs": "" }, "sndmassdyn": { + "frequency": "mon", "modeling_realm": "seaIce", - "standard_name": "tendency_of_snow_mass_due_to_sea_ice_dynamics", + "standard_name": "tendency_of_surface_snow_amount_due_to_sea_ice_dynamics", "units": "kg m-2 s-1", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "Snow Mass Rate of Change through Avection by Sea-ice Dynamics", - "comment": "the rate of change of snow mass through advection with sea ice divided by grid-cell area", + "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", + "cell_measures": "area: areacello", + "long_name": "Snow Mass Rate of Change Through Advection by Sea-Ice Dynamics", + "comment": "The rate of change of snow mass through advection with sea ice divided by sea-ice area", "dimensions": "longitude latitude time", "out_name": "sndmassdyn", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1443,16 +1509,17 @@ "ok_max_mean_abs": "" }, "sndmassmelt": { + "frequency": "mon", "modeling_realm": "seaIce", "standard_name": "surface_snow_melt_flux", "units": "kg m-2 s-1", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "Snow Mass Rate of Change through Melt", - "comment": "the rate of change of snow mass through melt divided by grid-cell area", + "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", + "cell_measures": "area: areacello", + "long_name": "Snow Mass Rate of Change Through Melt", + "comment": "the rate of change of snow mass through melt divided by sea-ice area", "dimensions": "longitude latitude time", "out_name": "sndmassmelt", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1460,16 +1527,17 @@ "ok_max_mean_abs": "" }, "sndmasssi": { + "frequency": "mon", "modeling_realm": "seaIce", "standard_name": "tendency_of_surface_snow_amount_due_to_conversion_of_snow_to_sea_ice", "units": "kg m-2 s-1", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "Snow Mass Rate of Change through Snow-to-Ice Conversion", - "comment": "the rate of change of snow mass due to transformation of snow to sea ice divided by grid-cell area", + "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", + "cell_measures": "area: areacello", + "long_name": "Snow Mass Rate of Change Through Snow-to-Ice Conversion", + "comment": "the rate of change of snow mass due to transformation of snow to sea ice divided by sea-ice area", "dimensions": "longitude latitude time", "out_name": "sndmasssi", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1477,16 +1545,17 @@ "ok_max_mean_abs": "" }, "sndmasssnf": { + "frequency": "mon", "modeling_realm": "seaIce", "standard_name": "snowfall_flux", "units": "kg m-2 s-1", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "snow mass change through snow fall", - "comment": "mass of solid precipitation falling onto sea ice divided by grid-cell area", + "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", + "cell_measures": "area: areacello", + "long_name": "Snow Mass Change Through Snow Fall", + "comment": "mass of solid precipitation falling onto sea ice divided by sea-ice area", "dimensions": "longitude latitude time", "out_name": "sndmasssnf", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1494,16 +1563,17 @@ "ok_max_mean_abs": "" }, "sndmasssubl": { + "frequency": "mon", "modeling_realm": "seaIce", - "standard_name": "surface_snow_sublimation_flux", + "standard_name": "tendency_of_atmosphere_mass_content_of_water_vapor_due_to_sublimation_of_surface_snow_and_ice", "units": "kg m-2 s-1", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "Snow Mass Rate of Change through Evaporation or Sublimation", - "comment": "the rate of change of snow mass through sublimation and evaporation divided by grid-cell area", + "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", + "cell_measures": "area: areacello", + "long_name": "Snow Mass Rate of Change Through Evaporation or Sublimation", + "comment": "the rate of change of snow mass through sublimation and evaporation divided by sea-ice area", "dimensions": "longitude latitude time", "out_name": "sndmasssubl", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1511,16 +1581,17 @@ "ok_max_mean_abs": "" }, "sndmasswindrif": { + "frequency": "mon", "modeling_realm": "seaIce", - "standard_name": "tendency_of_snow_mass_due_to_drifting_snow", + "standard_name": "tendency_of_surface_snow_amount_due_to_drifting_into_sea", "units": "kg m-2 s-1", - "cell_methods": "area: time: mean", - "cell_measures": "area: areacella", - "long_name": "Snow Mass Rate of Change through Wind Drift of Snow", - "comment": "the rate of change of snow mass through wind drift of snow (from sea-ice into the sea) divided by grid-cell area", + "cell_methods": "area: time: mean where sea_ice (comment: mask=siconc)", + "cell_measures": "area: areacello", + "long_name": "Snow Mass Rate of Change Through Wind Drift of Snow", + "comment": "the rate of change of snow mass through wind drift of snow (from sea-ice into the sea) divided by sea-ice area", "dimensions": "longitude latitude time", "out_name": "sndmasswindrif", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", @@ -1528,16 +1599,17 @@ "ok_max_mean_abs": "" }, "snmassacrossline": { + "frequency": "mon", "modeling_realm": "seaIce", - "standard_name": "snow_mass_transport_across_line", + "standard_name": "snow_transport_across_line_due_to_sea_ice_dynamics", "units": "kg s-1", "cell_methods": "time: mean", - "cell_measures": "area: areacella", - "long_name": "Snow mass flux through straits", - "comment": "net (sum of transport in all directions) snow mass transport through the following four passages, positive into the Arctic Ocean 1. Fram Strait = (11.5W,81.3N to (10.5E,79.6N) 2. Canadian Archipelego = (128.2W,70.6N) to (59.3W,82.1N) 3. Barents opening = (16.8E,76.5N) to (19.2E,70.2N) 4. Bering Strait = (171W,66.2N) to (166W,65N)", + "cell_measures": "", + "long_name": "Snow Mass Flux Through Straits", + "comment": "net (sum of transport in all directions) sea ice area transport through the following four passages, positive into the Arctic Ocean 1. Fram Strait = (11.5W,81.3N to (10.5E,79.6N) 2. Canadian Archipelago = (128.2W,70.6N) to (59.3W,82.1N) 3. Barents opening = (16.8E,76.5N) to (19.2E,70.2N) 4. Bering Strait = (171W,66.2N) to (166W,65N)", "dimensions": "siline time", "out_name": "snmassacrossline", - "type": "", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_coordinate.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_coordinate.json index fb408219f9..929d2bd13b 100644 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_coordinate.json +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_coordinate.json @@ -1,27 +1,5 @@ { "axis_entry": { - "alev1": { - "standard_name": "", - "units": "", - "axis": "Z", - "long_name": "lowest atmospheric model level", - "climatology": "", - "formula": "", - "must_have_bounds": "yes", - "out_name": "lev", - "positive": "", - "requested": "", - "requested_bounds": "", - "stored_direction": "", - "tolerance": "", - "type": "double", - "valid_max": "", - "valid_min": "", - "value": "", - "z_bounds_factors": "", - "z_factors": "", - "bounds_values": "" - }, "alt16": { "standard_name": "altitude", "units": "m", @@ -92,7 +70,8 @@ "value": "", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "alt40": { "standard_name": "altitude", @@ -236,7 +215,8 @@ "value": "", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "alternate_hybrid_sigma": { "standard_name": "atmosphere_hybrid_sigma_pressure_coordinate", @@ -258,7 +238,31 @@ "value": "", "z_bounds_factors": "ap: ap_bnds b: b_bnds ps: ps", "z_factors": "ap: ap b: b ps: ps", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "alevel" + }, + "alternate_hybrid_sigma_half": { + "standard_name": "atmosphere_hybrid_sigma_pressure_coordinate", + "units": "1", + "axis": "Z", + "long_name": "hybrid sigma pressure coordinate", + "climatology": "", + "formula": "p = ap + b*ps", + "must_have_bounds": "no", + "out_name": "lev", + "positive": "down", + "requested": "", + "requested_bounds": "", + "stored_direction": "decreasing", + "tolerance": "", + "type": "", + "valid_max": "1.0", + "valid_min": "0.0", + "value": "", + "z_bounds_factors": "ap: ap_bnds b: b_bnds ps: ps", + "z_factors": "ap: ap b: b ps: ps", + "bounds_values": "", + "generic_level_name": "alevhalf" }, "basin": { "standard_name": "region", @@ -284,7 +288,8 @@ "value": "", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "dbze": { "standard_name": "equivalent_reflectivity_factor", @@ -353,7 +358,8 @@ "value": "", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "depth0m": { "standard_name": "depth", @@ -375,7 +381,8 @@ "value": "0.", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "depth100m": { "standard_name": "depth", @@ -397,7 +404,8 @@ "value": "100.", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "depth2000m": { "standard_name": "depth", @@ -406,7 +414,7 @@ "long_name": "depth", "climatology": "", "formula": "", - "must_have_bounds": "no", + "must_have_bounds": "yes", "out_name": "depth", "positive": "down", "requested": "", @@ -414,12 +422,13 @@ "stored_direction": "increasing", "tolerance": "", "type": "double", - "valid_max": "2200.0", - "valid_min": "1980.0", - "value": "2000", + "valid_max": "2000.0", + "valid_min": "0.0", + "value": "1000.", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "0.0 2000.0", + "generic_level_name": "" }, "depth300m": { "standard_name": "depth", @@ -428,7 +437,7 @@ "long_name": "depth", "climatology": "", "formula": "", - "must_have_bounds": "no", + "must_have_bounds": "yes", "out_name": "depth", "positive": "down", "requested": "", @@ -436,12 +445,13 @@ "stored_direction": "increasing", "tolerance": "", "type": "double", - "valid_max": "320.0", - "valid_min": "280.0", - "value": "300", + "valid_max": "300.0", + "valid_min": "0.0", + "value": "150.", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "0.0 300.0", + "generic_level_name": "" }, "depth700m": { "standard_name": "depth", @@ -450,7 +460,7 @@ "long_name": "depth", "climatology": "", "formula": "", - "must_have_bounds": "no", + "must_have_bounds": "yes", "out_name": "depth", "positive": "down", "requested": "", @@ -458,12 +468,13 @@ "stored_direction": "increasing", "tolerance": "", "type": "double", - "valid_max": "720.0", - "valid_min": "680.0", - "value": "700", + "valid_max": "700.0", + "valid_min": "0.0", + "value": "350.", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "0.0 700.0", + "generic_level_name": "" }, "depth_coord": { "standard_name": "depth", @@ -485,7 +496,31 @@ "value": "", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "olevel" + }, + "depth_coord_half": { + "standard_name": "depth", + "units": "m", + "axis": "Z", + "long_name": "ocean depth coordinate", + "climatology": "", + "formula": "", + "must_have_bounds": "no", + "out_name": "lev", + "positive": "down", + "requested": "", + "requested_bounds": "", + "stored_direction": "increasing", + "tolerance": "", + "type": "", + "valid_max": "12000.0", + "valid_min": "0.0", + "value": "", + "z_bounds_factors": "", + "z_factors": "", + "bounds_values": "", + "generic_level_name": "olevhalf" }, "effectRadIc": { "standard_name": "", @@ -527,7 +562,8 @@ "value": "", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "effectRadLi": { "standard_name": "", @@ -569,7 +605,31 @@ "value": "", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" + }, + "gridlatitude": { + "standard_name": "grid_latitude", + "units": "degrees", + "axis": "Y", + "long_name": "Grid Latitude", + "climatology": "", + "formula": "", + "must_have_bounds": "yes", + "out_name": "rlat", + "positive": "", + "requested": "", + "requested_bounds": "", + "stored_direction": "increasing", + "tolerance": "", + "type": "double", + "valid_max": "90.0", + "valid_min": "-90.0", + "value": "", + "z_bounds_factors": "", + "z_factors": "", + "bounds_values": "", + "generic_level_name": "" }, "height100m": { "standard_name": "height", @@ -591,7 +651,8 @@ "value": "100.", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "height10m": { "standard_name": "height", @@ -613,7 +674,8 @@ "value": "10.", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "height2m": { "standard_name": "height", @@ -635,7 +697,8 @@ "value": "2.", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "hybrid_height": { "standard_name": "atmosphere_hybrid_height_coordinate", @@ -657,7 +720,31 @@ "value": "", "z_bounds_factors": "a: lev_bnds b: b_bnds orog: orog", "z_factors": "a: lev b: b orog: orog", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "alevel" + }, + "hybrid_height_half": { + "standard_name": "atmosphere_hybrid_height_coordinate", + "units": "m", + "axis": "Z", + "long_name": "hybrid height coordinate", + "climatology": "", + "formula": "z = a + b*orog", + "must_have_bounds": "no", + "out_name": "lev", + "positive": "up", + "requested": "", + "requested_bounds": "", + "stored_direction": "increasing", + "tolerance": "", + "type": "", + "valid_max": "", + "valid_min": "0.0", + "value": "", + "z_bounds_factors": "a: lev_bnds b: b_bnds orog: orog", + "z_factors": "a: lev b: b orog: orog", + "bounds_values": "", + "generic_level_name": "alevhalf" }, "iceband": { "standard_name": "sea_ice_thickness", @@ -679,32 +766,31 @@ "value": "", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, - "icesheet": { - "standard_name": "region", - "units": "", + "lambda550nm": { + "standard_name": "radiation_wavelength", + "units": "nm", "axis": "", - "long_name": "Ice Sheet", + "long_name": "Radiation Wavelength 550 nanometers", "climatology": "", "formula": "", - "must_have_bounds": "no", - "out_name": "region", + "must_have_bounds": "", + "out_name": "wavelength", "positive": "", - "requested": [ - "antarctic", - "greenland" - ], + "requested": "", "requested_bounds": "", "stored_direction": "", "tolerance": "", - "type": "character", + "type": "double", "valid_max": "", "valid_min": "", - "value": "", + "value": "550.0", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "landUse": { "standard_name": "area_type", @@ -731,13 +817,14 @@ "value": "", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "latitude": { "standard_name": "latitude", "units": "degrees_north", "axis": "Y", - "long_name": "latitude", + "long_name": "Latitude", "climatology": "", "formula": "", "must_have_bounds": "yes", @@ -753,7 +840,8 @@ "value": "", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "location": { "standard_name": "", @@ -775,13 +863,14 @@ "value": "", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "longitude": { "standard_name": "longitude", "units": "degrees_east", "axis": "X", - "long_name": "longitude", + "long_name": "Longitude", "climatology": "", "formula": "", "must_have_bounds": "yes", @@ -797,38 +886,40 @@ "value": "", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, - "misrBands": { - "standard_name": "wave_frequency", - "units": "s-1", - "axis": "", - "long_name": "MISR Spectral Frequency Band", + "natural_log_pressure": { + "standard_name": "atmosphere_ln_pressure_coordinate", + "units": "", + "axis": "Z", + "long_name": "atmosphere natural log pressure coordinate", "climatology": "", - "formula": "", + "formula": "p = p0 * exp(-lev)", "must_have_bounds": "yes", - "out_name": "spectband", - "positive": "", + "out_name": "lev", + "positive": "down", "requested": "", "requested_bounds": "", - "stored_direction": "", + "stored_direction": "decreasing", "tolerance": "", - "type": "double", - "valid_max": "", - "valid_min": "", + "type": "", + "valid_max": "20.0", + "valid_min": "-1.0", "value": "", - "z_bounds_factors": "", - "z_factors": "", - "bounds_values": "" + "z_bounds_factors": "p0: p0 lev: lev_bnds", + "z_factors": "p0: p0 lev: lev", + "bounds_values": "", + "generic_level_name": "alevel" }, - "natural_log_pressure": { + "natural_log_pressure_half": { "standard_name": "atmosphere_ln_pressure_coordinate", "units": "", "axis": "Z", "long_name": "atmosphere natural log pressure coordinate", "climatology": "", "formula": "p = p0 * exp(-lev)", - "must_have_bounds": "yes", + "must_have_bounds": "no", "out_name": "lev", "positive": "down", "requested": "", @@ -841,7 +932,8 @@ "value": "", "z_bounds_factors": "p0: p0 lev: lev_bnds", "z_factors": "p0: p0 lev: lev", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "alevhalf" }, "ocean_double_sigma": { "standard_name": "ocean_double_sigma", @@ -863,7 +955,8 @@ "value": "", "z_bounds_factors": "sigma: sigma_bnds depth: depth z1: z1 z2: z2 a: a href: href k_c: k_c", "z_factors": "sigma: sigma depth: depth z1: z1 z2: z2 a: a_coeff href: href k_c: k_c", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "olevel" }, "ocean_s": { "standard_name": "ocean_s_coordinate", @@ -885,7 +978,8 @@ "value": "", "z_bounds_factors": "s: lev_bnds eta: eta depth: depth a: a b: b depth_c: depth_c", "z_factors": "s: lev eta: eta depth: depth a: a_coeff b: b_coeff depth_c: depth_c", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "olevel" }, "ocean_sigma": { "standard_name": "ocean_sigma_coordinate", @@ -907,7 +1001,8 @@ "value": "", "z_bounds_factors": "sigma: lev_bnds eta: eta depth: depth", "z_factors": "sigma: lev eta: eta depth: depth", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "olevel" }, "ocean_sigma_z": { "standard_name": "ocean_sigma_z", @@ -929,7 +1024,8 @@ "value": "", "z_bounds_factors": "sigma: sigma_bnds eta: eta depth: depth depth_c: depth_c nsigma: nsigma zlev: zlev_bnds", "z_factors": "sigma: sigma eta: eta depth: depth depth_c: depth_c nsigma: nsigma zlev: zlev", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "olevel" }, "olayer100m": { "standard_name": "depth", @@ -938,7 +1034,7 @@ "long_name": "depth", "climatology": "", "formula": "", - "must_have_bounds": "no", + "must_have_bounds": "yes", "out_name": "depth", "positive": "down", "requested": "", @@ -951,7 +1047,31 @@ "value": "50.", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "0.0 100.0" + "bounds_values": "0.0 100.0", + "generic_level_name": "" + }, + "olevhalf": { + "standard_name": "", + "units": "", + "axis": "Z", + "long_name": "ocean model half levels", + "climatology": "", + "formula": "", + "must_have_bounds": "no", + "out_name": "lev", + "positive": "down", + "requested": "", + "requested_bounds": "", + "stored_direction": "", + "tolerance": "", + "type": "double", + "valid_max": "", + "valid_min": "", + "value": "", + "z_bounds_factors": "", + "z_factors": "", + "bounds_values": "", + "generic_level_name": "" }, "oline": { "standard_name": "region", @@ -966,19 +1086,20 @@ "requested": [ "barents_opening", "bering_strait", - "canadian_archipelago", + "windward_passage", + "davis_strait", "denmark_strait", "drake_passage", "english_channel", - "pacific_equatorial_undercurrent", "faroe_scotland_channel", "florida_bahamas_strait", "fram_strait", + "gibraltar_strait", "iceland_faroe_channel", "indonesian_throughflow", "mozambique_channel", - "taiwan_luzon_straits", - "windward_passage" + "pacific_equatorial_undercurrent", + "taiwan_luzon_straits" ], "requested_bounds": "", "stored_direction": "", @@ -989,7 +1110,8 @@ "value": "", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "p10": { "standard_name": "air_pressure", @@ -1011,7 +1133,8 @@ "value": "1000.", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "p100": { "standard_name": "air_pressure", @@ -1033,7 +1156,8 @@ "value": "10000.", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "p1000": { "standard_name": "air_pressure", @@ -1055,7 +1179,8 @@ "value": "100000.", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "p200": { "standard_name": "air_pressure", @@ -1077,7 +1202,8 @@ "value": "20000.", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "p220": { "standard_name": "air_pressure", @@ -1099,7 +1225,8 @@ "value": "22000.", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "44000.0 0.0" + "bounds_values": "44000.0 0.0", + "generic_level_name": "" }, "p500": { "standard_name": "air_pressure", @@ -1121,7 +1248,8 @@ "value": "50000.", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "p560": { "standard_name": "air_pressure", @@ -1143,7 +1271,8 @@ "value": "56000.", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "68000.0 44000.0" + "bounds_values": "68000.0 44000.0", + "generic_level_name": "" }, "p700": { "standard_name": "air_pressure", @@ -1165,7 +1294,8 @@ "value": "70000.", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "p840": { "standard_name": "air_pressure", @@ -1187,7 +1317,8 @@ "value": "84000.", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "100000.0 68000.0" + "bounds_values": "100000.0 68000.0", + "generic_level_name": "" }, "p850": { "standard_name": "air_pressure", @@ -1209,7 +1340,8 @@ "value": "85000.", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "pl700": { "standard_name": "air_pressure", @@ -1231,40 +1363,8 @@ "value": "70000.", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "85000.0 60000.0" - }, - "plev10": { - "standard_name": "air_pressure", - "units": "Pa", - "axis": "Z", - "long_name": "pressure", - "climatology": "", - "formula": "", - "must_have_bounds": "no", - "out_name": "plev", - "positive": "down", - "requested": [ - "100000.", - "85000.", - "70000.", - "50000.", - "25000.", - "15000.", - "10000.", - "7000.", - "5000.", - "1000." - ], - "requested_bounds": "", - "stored_direction": "decreasing", - "tolerance": "", - "type": "double", - "valid_max": "", - "valid_min": "", - "value": "", - "z_bounds_factors": "", - "z_factors": "", - "bounds_values": "" + "bounds_values": "85000.0 60000.0", + "generic_level_name": "" }, "plev19": { "standard_name": "air_pressure", @@ -1306,7 +1406,8 @@ "value": "", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "plev23": { "standard_name": "air_pressure", @@ -1352,7 +1453,8 @@ "value": "", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "plev27": { "standard_name": "air_pressure", @@ -1402,7 +1504,8 @@ "value": "", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "plev3": { "standard_name": "air_pressure", @@ -1428,7 +1531,8 @@ "value": "", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "plev39": { "standard_name": "air_pressure", @@ -1490,7 +1594,8 @@ "value": "", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "plev3h": { "standard_name": "air_pressure", @@ -1516,7 +1621,8 @@ "value": "", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "plev4": { "standard_name": "air_pressure", @@ -1543,7 +1649,8 @@ "value": "", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "plev7": { "standard_name": "air_pressure", @@ -1588,7 +1695,8 @@ "value": "", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "plev7c": { "standard_name": "air_pressure", @@ -1633,7 +1741,8 @@ "value": "", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "plev7h": { "standard_name": "air_pressure", @@ -1663,7 +1772,8 @@ "value": "", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "plev8": { "standard_name": "air_pressure", @@ -1694,7 +1804,8 @@ "value": "", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "rho": { "standard_name": "sea_water_potential_density", @@ -1716,11 +1827,12 @@ "value": "", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "scatratio": { "standard_name": "backscattering_ratio", - "units": "1.0", + "units": "1", "axis": "", "long_name": "lidar backscattering ratio", "climatology": "", @@ -1782,10 +1894,34 @@ "type": "double", "valid_max": "", "valid_min": "", - "value": "0.005, 0.605, 2.1, 4, 6, 8.5, 12.5, 17.5, 22.5, 27.5, 35, 45, 55, 70, 50040", + "value": "", + "z_bounds_factors": "", + "z_factors": "", + "bounds_values": "", + "generic_level_name": "" + }, + "scatter180": { + "standard_name": "scattering_angle", + "units": "degree", + "axis": "", + "long_name": "Scattering Angle", + "climatology": "", + "formula": "", + "must_have_bounds": "no", + "out_name": "scatangle", + "positive": "", + "requested": "", + "requested_bounds": "", + "stored_direction": "", + "tolerance": "", + "type": "double", + "valid_max": "", + "valid_min": "", + "value": "180.0", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "0.0 0.01 1.2 3.0 5.0 7.0 10.0 15.0 20.0 25.0 30.0 40.0 50.0 60.0 80.0 100000.0" + "bounds_values": "", + "generic_level_name": "" }, "sdepth": { "standard_name": "depth", @@ -1807,7 +1943,8 @@ "value": "", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "sdepth1": { "standard_name": "depth", @@ -1824,12 +1961,36 @@ "stored_direction": "increasing", "tolerance": "", "type": "double", - "valid_max": "0.2", + "valid_max": "0.1", "valid_min": "0.0", "value": "0.05", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "0.0 0.1" + "bounds_values": "0.0 0.1", + "generic_level_name": "" + }, + "sdepth10": { + "standard_name": "depth", + "units": "m", + "axis": "Z", + "long_name": "depth", + "climatology": "", + "formula": "", + "must_have_bounds": "yes", + "out_name": "depth", + "positive": "down", + "requested": "", + "requested_bounds": "", + "stored_direction": "increasing", + "tolerance": "", + "type": "double", + "valid_max": "1.0", + "valid_min": "0.0", + "value": "0.5", + "z_bounds_factors": "", + "z_factors": "", + "bounds_values": "0.0 1.0", + "generic_level_name": "" }, "siline": { "standard_name": "region", @@ -1842,14 +2003,10 @@ "out_name": "line", "positive": "", "requested": [ - "Fram", - "Strait,", - "Canadian", - "Archipelego,", - "Barents", - "opening,", - "Bering", - "Strait" + "fram_strait,", + "canadian_archipelego,", + "barents_opening,", + "bering_strait" ], "requested_bounds": "", "stored_direction": "", @@ -1860,7 +2017,8 @@ "value": "", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "site": { "standard_name": "", @@ -1882,7 +2040,31 @@ "value": "", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" + }, + "sithreshold": { + "standard_name": "sea_ice_area_fraction", + "units": "%", + "axis": "", + "long_name": "Sea Ice Area Fraction Threshold", + "climatology": "", + "formula": "", + "must_have_bounds": "no", + "out_name": "threshold", + "positive": "", + "requested": "", + "requested_bounds": "", + "stored_direction": "", + "tolerance": "", + "type": "double", + "valid_max": "", + "valid_min": "", + "value": "15.0", + "z_bounds_factors": "", + "z_factors": "", + "bounds_values": "", + "generic_level_name": "" }, "smooth_level": { "standard_name": "atmosphere_sleve_coordinate", @@ -1904,15 +2086,39 @@ "value": "", "z_bounds_factors": "a: a_bnds b1: b1_bnds b2: b2_bnds ztop: ztop zsurf1: zsurf1 zsurf2: zsurf2", "z_factors": "a: a b1: b1 b2: b2 ztop: ztop zsurf1: zsurf1 zsurf2: zsurf2", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "alevel" }, - "snowband": { - "standard_name": "surface_snow_thickness", + "smooth_level_half": { + "standard_name": "atmosphere_sleve_coordinate", "units": "m", - "axis": "", - "long_name": "Snow Depth Band", + "axis": "Z", + "long_name": "atmosphere smooth level vertical (SLEVE) coordinate", "climatology": "", - "formula": "", + "formula": "z = a*ztop + b1*zsurf1 + b2*zsurf2", + "must_have_bounds": "no", + "out_name": "lev", + "positive": "up", + "requested": "", + "requested_bounds": "", + "stored_direction": "increasing", + "tolerance": "", + "type": "", + "valid_max": "800000.0", + "valid_min": "-200.0", + "value": "", + "z_bounds_factors": "a: a_bnds b1: b1_bnds b2: b2_bnds ztop: ztop zsurf1: zsurf1 zsurf2: zsurf2", + "z_factors": "a: a b1: b1 b2: b2 ztop: ztop zsurf1: zsurf1 zsurf2: zsurf2", + "bounds_values": "", + "generic_level_name": "alevhalf" + }, + "snowband": { + "standard_name": "surface_snow_thickness", + "units": "m", + "axis": "", + "long_name": "Snow Depth Band", + "climatology": "", + "formula": "", "must_have_bounds": "yes", "out_name": "snowband", "positive": "", @@ -1926,29 +2132,31 @@ "value": "", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, - "snowdepth": { - "standard_name": "depth", - "units": "m", - "axis": "Z", - "long_name": "depth", + "soilpools": { + "standard_name": "", + "units": "", + "axis": "", + "long_name": "Soil Pools", "climatology": "", "formula": "", - "must_have_bounds": "yes", - "out_name": "depth", - "positive": "down", + "must_have_bounds": "no", + "out_name": "type", + "positive": "", "requested": "", "requested_bounds": "", - "stored_direction": "increasing", + "stored_direction": "", "tolerance": "", - "type": "double", - "valid_max": "200.0", - "valid_min": "0.0", + "type": "character", + "valid_max": "", + "valid_min": "", "value": "", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "spectband": { "standard_name": "sensor_band_central_radiation_wavenumber", @@ -1970,7 +2178,8 @@ "value": "", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "standard_hybrid_sigma": { "standard_name": "atmosphere_hybrid_sigma_pressure_coordinate", @@ -1992,7 +2201,31 @@ "value": "", "z_bounds_factors": "p0: p0 a: a_bnds b: b_bnds ps: ps", "z_factors": "p0: p0 a: a b: b ps: ps", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "alevel" + }, + "standard_hybrid_sigma_half": { + "standard_name": "atmosphere_hybrid_sigma_pressure_coordinate", + "units": "1", + "axis": "Z", + "long_name": "hybrid sigma pressure coordinate", + "climatology": "", + "formula": "p = a*p0 + b*ps", + "must_have_bounds": "no", + "out_name": "lev", + "positive": "down", + "requested": "", + "requested_bounds": "", + "stored_direction": "decreasing", + "tolerance": "", + "type": "", + "valid_max": "1.0", + "valid_min": "0.0", + "value": "", + "z_bounds_factors": "p0: p0 a: a_bnds b: b_bnds ps: ps", + "z_factors": "p0: p0 a: a b: b ps: ps", + "bounds_values": "", + "generic_level_name": "alevhalf" }, "standard_sigma": { "standard_name": "atmosphere_sigma_coordinate", @@ -2014,7 +2247,54 @@ "value": "", "z_bounds_factors": "ptop: ptop sigma: lev_bnds ps: ps", "z_factors": "ptop: ptop sigma: lev ps: ps", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "alevel" + }, + "standard_sigma_half": { + "standard_name": "atmosphere_sigma_coordinate", + "units": "", + "axis": "Z", + "long_name": "sigma coordinate", + "climatology": "", + "formula": "p = ptop + sigma*(ps - ptop)", + "must_have_bounds": "no", + "out_name": "lev", + "positive": "down", + "requested": "", + "requested_bounds": "", + "stored_direction": "decreasing", + "tolerance": "", + "type": "", + "valid_max": "1.0", + "valid_min": "0.0", + "value": "", + "z_bounds_factors": "ptop: ptop sigma: lev_bnds ps: ps", + "z_factors": "ptop: ptop sigma: lev ps: ps", + "bounds_values": "", + "generic_level_name": "alevhalf" + }, + "stempzero": { + "standard_name": "soil_temperature", + "units": "degC", + "axis": "Z", + "long_name": "Soil Temperature Zero", + "climatology": "", + "formula": "", + "must_have_bounds": "no", + "out_name": "stempzero", + "positive": "", + "requested": "", + "requested_bounds": "", + "stored_direction": "", + "tolerance": "", + "type": "double", + "valid_max": "", + "valid_min": "", + "value": "0.0", + "z_bounds_factors": "", + "z_factors": "", + "bounds_values": "", + "generic_level_name": "" }, "sza5": { "standard_name": "solar_zenith_angle", @@ -2042,11 +2322,12 @@ "value": "", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "tau": { "standard_name": "atmosphere_optical_thickness_due_to_cloud", - "units": "1.0", + "units": "1", "axis": "", "long_name": "cloud optical thickness", "climatology": "", @@ -2087,7 +2368,8 @@ "value": "", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "time": { "standard_name": "time", @@ -2109,7 +2391,8 @@ "value": "", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "time1": { "standard_name": "time", @@ -2131,53 +2414,56 @@ "value": "", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, - "time2": { - "standard_name": "time", - "units": "days since ?", - "axis": "T", - "long_name": "time", + "typebare": { + "standard_name": "area_type", + "units": "", + "axis": "", + "long_name": "surface type", "climatology": "", "formula": "", - "must_have_bounds": "yes", - "out_name": "time", + "must_have_bounds": "no", + "out_name": "type", "positive": "", "requested": "", "requested_bounds": "", - "stored_direction": "increasing", + "stored_direction": "", "tolerance": "", - "type": "double", + "type": "character", "valid_max": "", "valid_min": "", - "value": "", + "value": "bare_ground", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, - "time3": { - "standard_name": "time", - "units": "days since ?", - "axis": "T", - "long_name": "time", + "typeburnt": { + "standard_name": "area_type", + "units": "", + "axis": "", + "long_name": "Burnt vegetation area type", "climatology": "", "formula": "", - "must_have_bounds": "yes", - "out_name": "time", + "must_have_bounds": "no", + "out_name": "type", "positive": "", "requested": "", "requested_bounds": "", - "stored_direction": "increasing", + "stored_direction": "", "tolerance": "", - "type": "double", + "type": "character", "valid_max": "", "valid_min": "", - "value": "", + "value": "burnt_vegetation", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, - "typebare": { + "typec3crop": { "standard_name": "area_type", "units": "", "axis": "", @@ -2194,16 +2480,17 @@ "type": "character", "valid_max": "", "valid_min": "", - "value": "bare_ground", + "value": "crops_of_c3_plant_functional_types", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, - "typeburnt": { + "typec3natg": { "standard_name": "area_type", "units": "", "axis": "", - "long_name": "Burnt vegetation area type", + "long_name": "C3 Natural grass area type", "climatology": "", "formula": "", "must_have_bounds": "no", @@ -2216,10 +2503,34 @@ "type": "character", "valid_max": "", "valid_min": "", - "value": "burnt_vegetation", + "value": "natural_grasses_of_c3_plant_functional_types", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" + }, + "typec3pastures": { + "standard_name": "area_type", + "units": "", + "axis": "", + "long_name": "C3 Pastures area type", + "climatology": "", + "formula": "", + "must_have_bounds": "no", + "out_name": "type", + "positive": "", + "requested": "", + "requested_bounds": "", + "stored_direction": "", + "tolerance": "", + "type": "character", + "valid_max": "", + "valid_min": "", + "value": "pastures_of_c3_plant_functional_types", + "z_bounds_factors": "", + "z_factors": "", + "bounds_values": "", + "generic_level_name": "" }, "typec3pft": { "standard_name": "area_type", @@ -2241,7 +2552,77 @@ "value": "c3_plant_functional_types", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" + }, + "typec4crop": { + "standard_name": "area_type", + "units": "", + "axis": "", + "long_name": "surface type", + "climatology": "", + "formula": "", + "must_have_bounds": "no", + "out_name": "type", + "positive": "", + "requested": "", + "requested_bounds": "", + "stored_direction": "", + "tolerance": "", + "type": "character", + "valid_max": "", + "valid_min": "", + "value": "crops_of_c4_plant_functional_types", + "z_bounds_factors": "", + "z_factors": "", + "bounds_values": "", + "generic_level_name": "" + }, + "typec4natg": { + "standard_name": "area_type", + "units": "", + "axis": "", + "long_name": "C4 Natural grass area type", + "climatology": "", + "formula": "", + "must_have_bounds": "no", + "out_name": "type", + "positive": "", + "requested": "", + "requested_bounds": "", + "stored_direction": "", + "tolerance": "", + "type": "character", + "valid_max": "", + "valid_min": "", + "value": "natural_grasses_of_c4_plant_functional_types", + "z_bounds_factors": "", + "z_factors": "", + "bounds_values": "", + "generic_level_name": "" + }, + "typec4pastures": { + "standard_name": "area_type", + "units": "", + "axis": "", + "long_name": "C4 Pastures area type", + "climatology": "", + "formula": "", + "must_have_bounds": "no", + "out_name": "type", + "positive": "", + "requested": "", + "requested_bounds": "", + "stored_direction": "", + "tolerance": "", + "type": "character", + "valid_max": "", + "valid_min": "", + "value": "pastures_of_c4_plant_functional_types", + "z_bounds_factors": "", + "z_factors": "", + "bounds_values": "", + "generic_level_name": "" }, "typec4pft": { "standard_name": "area_type", @@ -2263,7 +2644,8 @@ "value": "c4_plant_functional_types", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "typecloud": { "standard_name": "area_type", @@ -2285,7 +2667,8 @@ "value": "cloud", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "typecrop": { "standard_name": "area_type", @@ -2307,7 +2690,8 @@ "value": "crops", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "typefis": { "standard_name": "area_type", @@ -2329,7 +2713,8 @@ "value": "floating_ice_shelf", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "typegis": { "standard_name": "area_type", @@ -2351,7 +2736,8 @@ "value": "grounded_ice_sheet", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "typeland": { "standard_name": "area_type", @@ -2373,7 +2759,8 @@ "value": "land", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "typeli": { "standard_name": "area_type", @@ -2395,7 +2782,8 @@ "value": "land_ice", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "typemp": { "standard_name": "area_type", @@ -2417,7 +2805,8 @@ "value": "sea_ice_melt_pond", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "typenatgr": { "standard_name": "area_type", @@ -2439,7 +2828,8 @@ "value": "natural_grasses", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "typenwd": { "standard_name": "area_type", @@ -2458,10 +2848,11 @@ "type": "character", "valid_max": "", "valid_min": "", - "value": "non_woody_vegetation", + "value": "herbaceous_vegetation", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "typepasture": { "standard_name": "area_type", @@ -2483,7 +2874,8 @@ "value": "pastures", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "typepdec": { "standard_name": "area_type", @@ -2505,7 +2897,8 @@ "value": "primary_deciduous_trees", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "typepever": { "standard_name": "area_type", @@ -2527,7 +2920,8 @@ "value": "primary_evergreen_trees", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "typeresidual": { "standard_name": "", @@ -2549,7 +2943,8 @@ "value": "residual", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "typesdec": { "standard_name": "area_type", @@ -2571,7 +2966,8 @@ "value": "secondary_decidous_trees", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "typesea": { "standard_name": "area_type", @@ -2593,7 +2989,8 @@ "value": "sea", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "typesever": { "standard_name": "area_type", @@ -2615,7 +3012,8 @@ "value": "secondary_evergreen_trees", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "typeshrub": { "standard_name": "area_type", @@ -2637,7 +3035,8 @@ "value": "shrubs", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "typesi": { "standard_name": "area_type", @@ -2659,7 +3058,31 @@ "value": "sea_ice", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" + }, + "typesirdg": { + "standard_name": "area_type", + "units": "", + "axis": "", + "long_name": "Sea Ice Ridge area type", + "climatology": "", + "formula": "", + "must_have_bounds": "no", + "out_name": "type", + "positive": "", + "requested": "", + "requested_bounds": "", + "stored_direction": "", + "tolerance": "", + "type": "character", + "valid_max": "", + "valid_min": "", + "value": "sea_ice_ridges", + "z_bounds_factors": "", + "z_factors": "", + "bounds_values": "", + "generic_level_name": "" }, "typetree": { "standard_name": "area_type", @@ -2681,7 +3104,8 @@ "value": "trees", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "typetreebd": { "standard_name": "area_type", @@ -2703,7 +3127,8 @@ "value": "trees", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "typetreebe": { "standard_name": "area_type", @@ -2725,13 +3150,14 @@ "value": "trees", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "typetreend": { "standard_name": "area_type", "units": "", "axis": "", - "long_name": "Tree area type (Narrowleaf Deciduous)", + "long_name": "Tree area type (Needleleaf Deciduous)", "climatology": "", "formula": "", "must_have_bounds": "no", @@ -2747,13 +3173,14 @@ "value": "trees", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "typetreene": { "standard_name": "area_type", "units": "", "axis": "", - "long_name": "Tree area type (Narrowleaf Evergreen)", + "long_name": "Tree area type (Needleleaf Evergreen)", "climatology": "", "formula": "", "must_have_bounds": "no", @@ -2769,7 +3196,8 @@ "value": "trees", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "typeveg": { "standard_name": "area_type", @@ -2791,7 +3219,8 @@ "value": "vegetation", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "typewetla": { "standard_name": "area_type", @@ -2810,16 +3239,17 @@ "type": "character", "valid_max": "", "valid_min": "", - "value": "", + "value": "wetland", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "vegtype": { "standard_name": "", "units": "", "axis": "", - "long_name": "plant functional type", + "long_name": "Vegetation or Land Cover Type", "climatology": "", "formula": "", "must_have_bounds": "no", @@ -2835,13 +3265,14 @@ "value": "", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "xant": { "standard_name": "projection_x_coordinate", "units": "km", "axis": "", - "long_name": "", + "long_name": "X-coordinate of Antarctic grid", "climatology": "", "formula": "", "must_have_bounds": "", @@ -2857,13 +3288,14 @@ "value": "", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "xgre": { "standard_name": "projection_x_coordinate", "units": "km", "axis": "", - "long_name": "", + "long_name": "X-coordinate of Greenland grid", "climatology": "", "formula": "", "must_have_bounds": "", @@ -2879,13 +3311,14 @@ "value": "", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "yant": { "standard_name": "projection_y_coordinate", "units": "km", "axis": "", - "long_name": "", + "long_name": "Y-coordinate of Antarctic grid", "climatology": "", "formula": "", "must_have_bounds": "", @@ -2901,13 +3334,14 @@ "value": "", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" }, "ygre": { "standard_name": "projection_y_coordinate", "units": "km", "axis": "", - "long_name": "", + "long_name": "Y-coordinate of Greenland grid", "climatology": "", "formula": "", "must_have_bounds": "", @@ -2923,7 +3357,54 @@ "value": "", "z_bounds_factors": "", "z_factors": "", - "bounds_values": "" + "bounds_values": "", + "generic_level_name": "" + }, + "time2": { + "standard_name": "time", + "units": "days since ?", + "axis": "T", + "long_name": "time", + "climatology": "yes", + "formula": "", + "must_have_bounds": "yes", + "out_name": "time", + "positive": "", + "requested": "", + "requested_bounds": "", + "stored_direction": "increasing", + "tolerance": "", + "type": "double", + "valid_max": "", + "valid_min": "", + "value": "", + "z_bounds_factors": "", + "z_factors": "", + "bounds_values": "", + "generic_level_name": "" + }, + "time3": { + "standard_name": "time", + "units": "days since ?", + "axis": "T", + "long_name": "time", + "climatology": "yes", + "formula": "", + "must_have_bounds": "yes", + "out_name": "time", + "positive": "", + "requested": "", + "requested_bounds": "", + "stored_direction": "increasing", + "tolerance": "", + "type": "double", + "valid_max": "", + "valid_min": "", + "value": "", + "z_bounds_factors": "", + "z_factors": "", + "bounds_values": "", + "generic_level_name": "" } } } diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_day.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_day.json index 8f19bbd382..5f5243fcc7 100644 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_day.json +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_day.json @@ -1,27 +1,28 @@ { "Header": { - "data_specs_version": "01.00.10", + "data_specs_version": "01.00.30", + "cmor_version": "3.4", "table_id": "Table day", "realm": "atmos", - "frequency": "day", - "cmor_version": "3.2", - "table_date": "10 May 2017", + "table_date": "11 March 2019", "missing_value": "1e20", + "int_missing_value": "-999", "product": "model-output", "approx_interval": "1.00000", "generic_levels": "", "mip_era": "CMIP6", - "Conventions": "CF-1.7 CMIP-6.0" + "Conventions": "CF-1.7 CMIP-6.2" }, "variable_entry": { "clt": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "cloud_area_fraction", "units": "%", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Total Cloud Fraction", - "comment": "Total cloud area fraction for the whole atmospheric column, as seen from the surface or the top of the atmosphere. Includes both large-scale and convective cloud.", + "long_name": "Total Cloud Cover Percentage", + "comment": "Total cloud area fraction (reported as a percentage) for the whole atmospheric column, as seen from the surface or the top of the atmosphere. Includes both large-scale and convective cloud.", "dimensions": "longitude latitude time", "out_name": "clt", "type": "real", @@ -32,13 +33,14 @@ "ok_max_mean_abs": "" }, "hfls": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "surface_upward_latent_heat_flux", "units": "W m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Surface Upward Latent Heat Flux", - "comment": "", + "comment": "The surface called 'surface' means the lower boundary of the atmosphere. 'Upward' indicates a vector component which is positive when directed upward (negative downward). The surface latent heat flux is the exchange of heat between the surface and the air on account of evaporation (including sublimation). In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions": "longitude latitude time", "out_name": "hfls", "type": "real", @@ -49,13 +51,14 @@ "ok_max_mean_abs": "" }, "hfss": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "surface_upward_sensible_heat_flux", "units": "W m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Surface Upward Sensible Heat Flux", - "comment": "", + "comment": "The surface sensible heat flux, also called turbulent heat flux, is the exchange of heat between the surface and the air by motion of air.", "dimensions": "longitude latitude time", "out_name": "hfss", "type": "real", @@ -66,6 +69,7 @@ "ok_max_mean_abs": "" }, "hur": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "relative_humidity", "units": "%", @@ -83,6 +87,7 @@ "ok_max_mean_abs": "" }, "hurs": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "relative_humidity", "units": "%", @@ -100,13 +105,14 @@ "ok_max_mean_abs": "" }, "hursmax": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "relative_humidity", "units": "%", "cell_methods": "area: mean time: maximum", "cell_measures": "area: areacella", - "long_name": "Surface Daily Maximum Relative Humidity", - "comment": "", + "long_name": "Daily Maximum Near-Surface Relative Humidity", + "comment": "The relative humidity with respect to liquid water for T> 0 C, and with respect to ice for T<0 C.", "dimensions": "longitude latitude time height2m", "out_name": "hursmax", "type": "real", @@ -117,13 +123,14 @@ "ok_max_mean_abs": "" }, "hursmin": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "relative_humidity", "units": "%", "cell_methods": "area: mean time: minimum", "cell_measures": "area: areacella", - "long_name": "Surface Daily Minimum Relative Humidity", - "comment": "", + "long_name": "Daily Minimum Near-Surface Relative Humidity", + "comment": "The relative humidity with respect to liquid water for T> 0 C, and with respect to ice for T<0 C.", "dimensions": "longitude latitude time height2m", "out_name": "hursmin", "type": "real", @@ -134,13 +141,14 @@ "ok_max_mean_abs": "" }, "hus": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "specific_humidity", - "units": "1.0", + "units": "1", "cell_methods": "time: mean", "cell_measures": "area: areacella", "long_name": "Specific Humidity", - "comment": "", + "comment": "Specific humidity is the mass fraction of water vapor in (moist) air.", "dimensions": "longitude latitude plev8 time", "out_name": "hus", "type": "real", @@ -151,9 +159,10 @@ "ok_max_mean_abs": "" }, "huss": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "specific_humidity", - "units": "1.0", + "units": "1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Near-Surface Specific Humidity", @@ -168,6 +177,7 @@ "ok_max_mean_abs": "" }, "mrro": { + "frequency": "day", "modeling_realm": "land", "standard_name": "runoff_flux", "units": "kg m-2 s-1", @@ -185,8 +195,9 @@ "ok_max_mean_abs": "" }, "mrso": { + "frequency": "day", "modeling_realm": "land", - "standard_name": "soil_moisture_content", + "standard_name": "mass_content_of_water_in_soil", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", @@ -202,8 +213,9 @@ "ok_max_mean_abs": "" }, "mrsos": { + "frequency": "day", "modeling_realm": "land", - "standard_name": "moisture_content_of_soil_layer", + "standard_name": "mass_content_of_water_in_soil_layer", "units": "kg m-2", "cell_methods": "area: mean where land time: mean", "cell_measures": "area: areacella", @@ -219,6 +231,7 @@ "ok_max_mean_abs": "" }, "pr": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "precipitation_flux", "units": "kg m-2 s-1", @@ -236,6 +249,7 @@ "ok_max_mean_abs": "" }, "prc": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "convective_precipitation_flux", "units": "kg m-2 s-1", @@ -253,13 +267,14 @@ "ok_max_mean_abs": "" }, "prsn": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "snowfall_flux", "units": "kg m-2 s-1", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Snowfall Flux", - "comment": "at surface; includes precipitation of all forms of water in the solid phase", + "comment": "At surface; includes precipitation of all forms of water in the solid phase", "dimensions": "longitude latitude time", "out_name": "prsn", "type": "real", @@ -270,8 +285,9 @@ "ok_max_mean_abs": "" }, "psl": { + "frequency": "day", "modeling_realm": "atmos", - "standard_name": "air_pressure_at_sea_level", + "standard_name": "air_pressure_at_mean_sea_level", "units": "Pa", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", @@ -287,13 +303,14 @@ "ok_max_mean_abs": "" }, "rlds": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "surface_downwelling_longwave_flux_in_air", "units": "W m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Surface Downwelling Longwave Radiation", - "comment": "", + "comment": "The surface called 'surface' means the lower boundary of the atmosphere. 'longwave' means longwave radiation. Downwelling radiation is radiation from above. It does not mean 'net downward'. When thought of as being incident on a surface, a radiative flux is sometimes called 'irradiance'. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called 'vector irradiance'. In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions": "longitude latitude time", "out_name": "rlds", "type": "real", @@ -303,14 +320,33 @@ "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, + "rls": { + "frequency": "day", + "modeling_realm": "atmos", + "standard_name": "surface_net_downward_longwave_flux", + "units": "W m-2", + "cell_methods": "area: time: mean", + "cell_measures": "area: areacella", + "long_name": "Net Longwave Surface Radiation", + "comment": "Net longwave surface radiation", + "dimensions": "longitude latitude time", + "out_name": "rls", + "type": "real", + "positive": "down", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, "rlus": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "surface_upwelling_longwave_flux_in_air", "units": "W m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Surface Upwelling Longwave Radiation", - "comment": "", + "comment": "The surface called 'surface' means the lower boundary of the atmosphere. 'longwave' means longwave radiation. Upwelling radiation is radiation from below. It does not mean 'net upward'. When thought of as being incident on a surface, a radiative flux is sometimes called 'irradiance'. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called 'vector irradiance'. In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions": "longitude latitude time", "out_name": "rlus", "type": "real", @@ -321,6 +357,7 @@ "ok_max_mean_abs": "" }, "rlut": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "toa_outgoing_longwave_flux", "units": "W m-2", @@ -338,13 +375,14 @@ "ok_max_mean_abs": "" }, "rsds": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "surface_downwelling_shortwave_flux_in_air", "units": "W m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Surface Downwelling Shortwave Radiation", - "comment": "surface solar irradiance for UV calculations", + "comment": "Surface solar irradiance for UV calculations.", "dimensions": "longitude latitude time", "out_name": "rsds", "type": "real", @@ -354,14 +392,33 @@ "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, + "rss": { + "frequency": "day", + "modeling_realm": "atmos", + "standard_name": "surface_net_downward_shortwave_flux", + "units": "W m-2", + "cell_methods": "area: time: mean", + "cell_measures": "area: areacella", + "long_name": "Net Shortwave Surface Radiation", + "comment": "Net downward shortwave radiation at the surface", + "dimensions": "longitude latitude time", + "out_name": "rss", + "type": "real", + "positive": "down", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, "rsus": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "surface_upwelling_shortwave_flux_in_air", "units": "W m-2", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", "long_name": "Surface Upwelling Shortwave Radiation", - "comment": "", + "comment": "The surface called 'surface' means the lower boundary of the atmosphere. 'shortwave' means shortwave radiation. Upwelling radiation is radiation from below. It does not mean 'net upward'. When thought of as being incident on a surface, a radiative flux is sometimes called 'irradiance'. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called 'vector irradiance'. In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions": "longitude latitude time", "out_name": "rsus", "type": "real", @@ -372,6 +429,7 @@ "ok_max_mean_abs": "" }, "sfcWind": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "wind_speed", "units": "m s-1", @@ -389,6 +447,7 @@ "ok_max_mean_abs": "" }, "sfcWindmax": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "wind_speed", "units": "m s-1", @@ -406,13 +465,14 @@ "ok_max_mean_abs": "" }, "snc": { + "frequency": "day", "modeling_realm": "landIce land", "standard_name": "surface_snow_area_fraction", "units": "%", "cell_methods": "area: time: mean", "cell_measures": "area: areacella", - "long_name": "Snow Area Fraction", - "comment": "Fraction of each grid cell that is occupied by snow that rests on land portion of cell.", + "long_name": "Snow Area Percentage", + "comment": "Percentage of each grid cell that is occupied by snow that rests on land portion of cell.", "dimensions": "longitude latitude time", "out_name": "snc", "type": "real", @@ -423,6 +483,7 @@ "ok_max_mean_abs": "" }, "snw": { + "frequency": "day", "modeling_realm": "landIce land", "standard_name": "surface_snow_amount", "units": "kg m-2", @@ -440,6 +501,7 @@ "ok_max_mean_abs": "" }, "ta": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "air_temperature", "units": "K", @@ -457,6 +519,7 @@ "ok_max_mean_abs": "" }, "tas": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "air_temperature", "units": "K", @@ -474,6 +537,7 @@ "ok_max_mean_abs": "" }, "tasmax": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "air_temperature", "units": "K", @@ -491,6 +555,7 @@ "ok_max_mean_abs": "" }, "tasmin": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "air_temperature", "units": "K", @@ -508,13 +573,14 @@ "ok_max_mean_abs": "" }, "tslsi": { + "frequency": "day", "modeling_realm": "land", "standard_name": "surface_temperature", "units": "K", "cell_methods": "area: time: mean (comment: over land and sea ice)", "cell_measures": "area: areacella", "long_name": "Surface Temperature Where Land or Sea Ice", - "comment": "'skin' temperature of all surfaces except open ocean.", + "comment": "Surface temperature of all surfaces except open ocean.", "dimensions": "longitude latitude time", "out_name": "tslsi", "type": "real", @@ -525,13 +591,14 @@ "ok_max_mean_abs": "" }, "ua": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "eastward_wind", "units": "m s-1", "cell_methods": "time: mean", "cell_measures": "area: areacella", "long_name": "Eastward Wind", - "comment": "", + "comment": "Zonal wind (positive in a eastward direction).", "dimensions": "longitude latitude plev8 time", "out_name": "ua", "type": "real", @@ -542,6 +609,7 @@ "ok_max_mean_abs": "" }, "uas": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "eastward_wind", "units": "m s-1", @@ -559,13 +627,14 @@ "ok_max_mean_abs": "" }, "va": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "northward_wind", "units": "m s-1", "cell_methods": "time: mean", "cell_measures": "area: areacella", "long_name": "Northward Wind", - "comment": "", + "comment": "Meridional wind (positive in a northward direction).", "dimensions": "longitude latitude plev8 time", "out_name": "va", "type": "real", @@ -576,6 +645,7 @@ "ok_max_mean_abs": "" }, "vas": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "northward_wind", "units": "m s-1", @@ -593,12 +663,13 @@ "ok_max_mean_abs": "" }, "wap": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "lagrangian_tendency_of_air_pressure", "units": "Pa s-1", "cell_methods": "time: mean", "cell_measures": "area: areacella", - "long_name": "omega (=dp/dt)", + "long_name": "Omega (=dp/dt)", "comment": "Omega (vertical velocity in pressure coordinates, positive downwards)", "dimensions": "longitude latitude plev8 time", "out_name": "wap", @@ -610,13 +681,14 @@ "ok_max_mean_abs": "" }, "zg": { + "frequency": "day", "modeling_realm": "atmos", "standard_name": "geopotential_height", "units": "m", "cell_methods": "time: mean", "cell_measures": "area: areacella", "long_name": "Geopotential Height", - "comment": "", + "comment": "Geopotential is the sum of the specific gravitational potential energy relative to the geoid and the specific centripetal potential energy. Geopotential height is the geopotential divided by the standard acceleration due to gravity. It is numerically similar to the altitude (or geometric height) and not to the quantity with standard name height, which is relative to the surface.", "dimensions": "longitude latitude plev8 time", "out_name": "zg", "type": "real", diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_formula_terms.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_formula_terms.json index 82a73c3c4e..93ec01fbe7 100644 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_formula_terms.json +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_formula_terms.json @@ -1,141 +1,255 @@ { - "variable_entry": { + "formula_entry": { "a": { "long_name": "vertical coordinate formula term: a(k)", "units": "", "dimensions": "alevel", + "out_name": "a", "type": "double" }, "ps": { "long_name": "Surface Air Pressure", "units": "Pa", "dimensions": "longitude latitude time", + "out_name": "ps", "type": "real" }, "p0": { "long_name": "vertical coordinate formula term: reference pressure", "units": "Pa", "dimensions": "", - "type": "" + "out_name": "p0", + "type": "double" }, "b": { "long_name": "vertical coordinate formula term: b(k)", "units": "", "dimensions": "alevel", + "out_name": "b", "type": "double" }, "b_bnds": { "long_name": "vertical coordinate formula term: b(k+1/2)", "units": "", "dimensions": "alevel", + "out_name": "b_bnds", "type": "double" }, "ap_bnds": { "long_name": "vertical coordinate formula term: ap(k+1/2)", "units": "Pa", "dimensions": "alevel", + "out_name": "ap_bnds", "type": "double" }, "ap": { "long_name": "vertical coordinate formula term: ap(k)", "units": "Pa", "dimensions": "alevel", + "out_name": "ap", "type": "double" }, "orog": { "long_name": "Surface Altitude", "units": "m", "dimensions": "longitude latitude", + "out_name": "orog", "type": "real" }, "ztop": { "long_name": "height of top of model", "units": "m", "dimensions": "", - "type": "" + "out_name": "ztop", + "type": "double" }, "ptop": { "long_name": "pressure at top of model", "units": "Pa", "dimensions": "", - "type": "" + "out_name": "ptop", + "type": "double" }, "a_bnds": { "long_name": "vertical coordinate formula term: a(k+1/2)", "units": "", "dimensions": "alevel", + "out_name": "a_bnds", "type": "double" }, "depth_c": { "long_name": "vertical coordinate formula term: depth_c", "units": "", "dimensions": "", + "out_name": "depth_c", "type": "double" }, "nsigma": { "long_name": "vertical coordinate formula term: nsigma", "units": "", "dimensions": "", + "out_name": "nsigma", "type": "integer" }, "href": { "long_name": "vertical coordinate formula term: href", "units": "", "dimensions": "", + "out_name": "href", "type": "double" }, "zlev": { "long_name": "vertical coordinate formula term: zlev(k)", "units": "", "dimensions": "olevel", + "out_name": "zlev", "type": "double" }, "zlev_bnds": { "long_name": "vertical coordinate formula term: zlev(k+1/2)", "units": "", "dimensions": "olevel", + "out_name": "zlev_bnds", "type": "double" }, "z1": { "long_name": "vertical coordinate formula term: z1", "units": "", "dimensions": "", + "out_name": "z1", "type": "double" }, "z2": { "long_name": "vertical coordinate formula term: z2", "units": "", "dimensions": "", + "out_name": "z2", "type": "double" }, "sigma_bnds": { "long_name": "vertical coordinate formula term: sigma(k+1/2)", "units": "", "dimensions": "olevel", + "out_name": "sigma_bnds", "type": "double" }, "depth": { "long_name": "Sea Floor Depth: formula term: thetao", "units": "m", "dimensions": "longitude latitude", + "out_name": "depth", "type": "real" }, "eta": { "long_name": "Sea Surface Height formula term: thetao", "units": "m", "dimensions": "longitude latitude time", + "out_name": "eta", "type": "real" }, "k_c": { "long_name": "vertical coordinate formula term: k_c", "units": "", "dimensions": "", + "out_name": "k_c", "type": "integer" }, "sigma": { "long_name": "vertical coordinate formula term: sigma(k)", "units": "", "dimensions": "olevel", + "out_name": "sigma", + "type": "double" + }, + "ps2": { + "long_name": "vertical coordinate formula term: ps", + "units": "Pa", + "dimensions": "longitude latitude time2", + "out_name": "ps", + "type": "real" + }, + "ps1": { + "long_name": "vertical coordinate formula term: ps", + "units": "Pa", + "dimensions": "longitude latitude time1", + "out_name": "ps", + "type": "real" + }, + "eta2": { + "long_name": "Sea Surface Height formula term: thetao", + "units": "m", + "dimensions": "longitude latitude time2", + "out_name": "eta", + "type": "real" + }, + "b_half_bnds": { + "long_name": "vertical coordinate formula term: b(k+1/2)", + "units": "", + "dimensions": "alevhalf", + "out_name": "b_bnds", + "type": "double" + }, + "ap_half": { + "long_name": "vertical coordinate formula term: ap(k)", + "units": "Pa", + "dimensions": "alevhalf", + "out_name": "ap", + "type": "double" + }, + "b2_half": { + "long_name": "vertical coordinate formula term: b2(k)", + "units": "", + "dimensions": "alevhalf", + "out_name": "b2", + "type": "double" + }, + "b1_half": { + "long_name": "vertical coordinate formula term: b1(k)", + "units": "", + "dimensions": "alevhalf", + "out_name": "b1", + "type": "double" + }, + "b2": { + "long_name": "vertical coordinate formula term: b2(k)", + "units": "", + "dimensions": "alevel", + "out_name": "b2", + "type": "double" + }, + "a_half": { + "long_name": "vertical coordinate formula term: a(k)", + "units": "", + "dimensions": "alevhalf", + "out_name": "a", + "type": "double" + }, + "ap_half_bnds": { + "long_name": "vertical coordinate formula term: ap(k+1/2)", + "units": "Pa", + "dimensions": "alevel", + "out_name": "ap_bnds", + "type": "double" + }, + "b_half": { + "long_name": "vertical coordinate formula term: b(k)", + "units": "", + "dimensions": "alevhalf", + "out_name": "b", + "type": "double" + }, + "a_half_bnds": { + "long_name": "vertical coordinate formula term: a(k+1/2)", + "units": "", + "dimensions": "alevhalf", + "out_name": "a_bnds", + "type": "double" + }, + "b1": { + "long_name": "vertical coordinate formula term: b1(k)", + "units": "", + "dimensions": "alevel", + "out_name": "b1", "type": "double" } } diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_fx.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_fx.json index 04c8ee60a4..0c63c9ffb0 100644 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_fx.json +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_fx.json @@ -1,26 +1,27 @@ { "Header": { - "data_specs_version": "01.00.10", + "data_specs_version": "01.00.30", + "cmor_version": "3.4", "table_id": "Table fx", "realm": "land", - "frequency": "fx", - "cmor_version": "3.2", - "table_date": "10 May 2017", + "table_date": "11 March 2019", "missing_value": "1e20", + "int_missing_value": "-999", "product": "model-output", "approx_interval": "0.00000", - "generic_levels": "alevel", + "generic_levels": "alevel", "mip_era": "CMIP6", - "Conventions": "CF-1.7 CMIP-6.0" + "Conventions": "CF-1.7 CMIP-6.2" }, "variable_entry": { "areacella": { + "frequency": "fx", "modeling_realm": "atmos land", "standard_name": "cell_area", "units": "m2", - "cell_methods": "area: mean", - "cell_measures": "area: areacella", - "long_name": "Atmosphere Grid-Cell Area", + "cell_methods": "area: sum", + "cell_measures": "", + "long_name": "Grid-Cell Area for Atmospheric Grid Variables", "comment": "For atmospheres with more than 1 mesh (e.g., staggered grids), report areas that apply to surface vertical fluxes of energy.", "dimensions": "longitude latitude", "out_name": "areacella", @@ -31,14 +32,33 @@ "ok_min_mean_abs": "", "ok_max_mean_abs": "" }, + "areacellr": { + "frequency": "fx", + "modeling_realm": "land", + "standard_name": "cell_area", + "units": "m2", + "cell_methods": "area: sum", + "cell_measures": "", + "long_name": "Grid-Cell Area for River Model Variables", + "comment": "For river routing model, if grid differs from the atmospheric grid.", + "dimensions": "longitude latitude", + "out_name": "areacellr", + "type": "real", + "positive": "", + "valid_min": "", + "valid_max": "", + "ok_min_mean_abs": "", + "ok_max_mean_abs": "" + }, "mrsofc": { + "frequency": "fx", "modeling_realm": "land", "standard_name": "soil_moisture_content_at_field_capacity", "units": "kg m-2", - "cell_methods": "area: mean", + "cell_methods": "area: mean where land", "cell_measures": "area: areacella", - "long_name": "Capacity of Soil to Store Water", - "comment": "'reported *where land*: divide the total water holding capacity of all the soil in the grid cell by the land area in the grid cell; reported as *missing* where the land fraction is 0.'", + "long_name": "Capacity of Soil to Store Water (Field Capacity)", + "comment": "The bulk water content retained by the soil at -33 J/kg of suction pressure, expressed as mass per unit land area; report as missing where there is no land", "dimensions": "longitude latitude", "out_name": "mrsofc", "type": "real", @@ -49,6 +69,7 @@ "ok_max_mean_abs": "" }, "orog": { + "frequency": "fx", "modeling_realm": "land", "standard_name": "surface_altitude", "units": "m", @@ -66,6 +87,7 @@ "ok_max_mean_abs": "" }, "rootd": { + "frequency": "fx", "modeling_realm": "land", "standard_name": "root_depth", "units": "m", @@ -83,14 +105,15 @@ "ok_max_mean_abs": "" }, "sftgif": { + "frequency": "fx", "modeling_realm": "land", "standard_name": "land_ice_area_fraction", "units": "%", "cell_methods": "area: mean", "cell_measures": "area: areacella", - "long_name": "Fraction of Grid Cell Covered with Glacier", - "comment": "Fraction of grid cell covered by land ice (ice sheet, ice shelf, ice cap, glacier)", - "dimensions": "longitude latitude typeli", + "long_name": "Land Ice Area Percentage", + "comment": "Percentage of grid cell covered by land ice (ice sheet, ice shelf, ice cap, glacier)", + "dimensions": "longitude latitude", "out_name": "sftgif", "type": "real", "positive": "", @@ -100,14 +123,15 @@ "ok_max_mean_abs": "" }, "sftlf": { + "frequency": "fx", "modeling_realm": "atmos", "standard_name": "land_area_fraction", "units": "%", "cell_methods": "area: mean", "cell_measures": "area: areacella", - "long_name": "Land Area Fraction", - "comment": "Please express 'X_area_fraction' as the percentage of horizontal area occupied by X.", - "dimensions": "longitude latitude typeland", + "long_name": "Percentage of the grid cell occupied by land (including lakes)", + "comment": "Percentage of horizontal area occupied by land.", + "dimensions": "longitude latitude", "out_name": "sftlf", "type": "real", "positive": "", @@ -117,16 +141,17 @@ "ok_max_mean_abs": "" }, "zfull": { + "frequency": "fx", "modeling_realm": "atmos", "standard_name": "height_above_reference_ellipsoid", "units": "m", "cell_methods": "area: mean", "cell_measures": "area: areacella", "long_name": "Altitude of Model Full-Levels", - "comment": "", + "comment": "Height of full model levels above a reference ellipsoid. A reference ellipsoid is a mathematical figure that approximates the geoid. The geoid is a surface of constant geopotential with which mean sea level would coincide if the ocean were at rest. The ellipsoid is an approximation because the geoid is an irregular shape. A number of reference ellipsoids are defined for use in the field of geodesy. To specify which reference ellipsoid is being used, a grid_mapping variable should be attached to the data variable as described in Chapter 5.6 of the CF Convention.", "dimensions": "longitude latitude alevel", "out_name": "zfull", - "type": "float", + "type": "real", "positive": "", "valid_min": "", "valid_max": "", diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_grids.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_grids.json index c6e2d179d9..7ae13a8d58 100644 --- a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_grids.json +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_grids.json @@ -1,12 +1,12 @@ { "Header": { "product": "output", - "cmor_version": "3.2", - "Conventions": "CF-1.7 CMIP-6.0", + "cmor_version": "3.4", + "Conventions": "CF-1.7 CMIP-6.2", "table_id": "Table grids", - "data_specs_version": "01.00.10", + "data_specs_version": "01.00.30", "missing_value": "1e20", - "table_date": "10 May 2017" + "table_date": "11 March 2019" }, "mapping_entry": { "sample_user_mapping": { @@ -21,7 +21,7 @@ "standard_name": "grid_latitude", "out_name": "rlat", "units": "degrees", - "type": "", + "type": "double", "axis": "Y" }, "y_deg": { @@ -29,7 +29,7 @@ "standard_name": "projection_y_coordinate", "out_name": "y", "units": "degrees", - "type": "", + "type": "double", "axis": "Y" }, "l_index": { @@ -45,7 +45,7 @@ "standard_name": "grid_longitude", "out_name": "rlon", "units": "degrees", - "type": "", + "type": "double", "axis": "X" }, "k_index": { @@ -69,7 +69,7 @@ "standard_name": "projection_x_coordinate", "out_name": "x", "units": "degrees", - "type": "", + "type": "double", "axis": "X" }, "i_index": { @@ -93,7 +93,7 @@ "standard_name": "projection_y_coordinate", "out_name": "", "units": "m", - "type": "", + "type": "double", "axis": "Y" }, "x": { @@ -101,7 +101,7 @@ "standard_name": "projection_x_coordinate", "out_name": "", "units": "m", - "type": "", + "type": "double", "axis": "X" }, "m_index": { @@ -116,15 +116,17 @@ "variable_entry": { "latitude": { "dimensions": "longitude latitude", + "type": "double", "valid_min": "-90.0", - "long_name": "", - "standard_name": "", + "long_name": "latitude", + "standard_name": "latitude", "out_name": "latitude", "units": "degrees_north", "valid_max": "90.0" }, "vertices_latitude": { "dimensions": "vertices longitude latitude", + "type": "double", "valid_min": "-90.0", "long_name": "", "standard_name": "", @@ -134,6 +136,7 @@ }, "vertices_longitude": { "dimensions": "vertices longitude latitude", + "type": "double", "valid_min": "0.0", "long_name": "", "standard_name": "", @@ -143,9 +146,10 @@ }, "longitude": { "dimensions": "longitude latitude", + "type": "double", "valid_min": "0.0", - "long_name": "", - "standard_name": "", + "long_name": "longitude", + "standard_name": "longitude", "out_name": "longitude", "units": "degrees_east", "valid_max": "360.0" diff --git a/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_input_example.json b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_input_example.json new file mode 100644 index 0000000000..08977e528d --- /dev/null +++ b/esmvaltool/cmor/tables/cmip6/Tables/CMIP6_input_example.json @@ -0,0 +1,74 @@ +{ + "#note_source_type": "explanation of what source_type is goes here", + "source_type": "AOGCM ISM AER", + + "#note_experiment_id": "CMIP6 valid experiment_ids are found in CMIP6_CV.json", + "experiment_id": "piControl-withism", + "activity_id": "ISMIP6", + "sub_experiment_id": "none", + + "realization_index": "3", + "initialization_index": "1", + "physics_index": "1", + "forcing_index": "1", + + "#note_run_variant": "Text stored in attribute variant_info (recommended, not required description of run variant)", + "run_variant": "3rd realization", + + "parent_experiment_id": "historical", + "parent_activity_id": "CMIP", + "parent_source_id": "PCMDI-test-1-0", + "parent_variant_label": "r3i1p1f1", + + "parent_time_units": "days since 1850-01-01", + "branch_method": "standard", + "branch_time_in_child": 59400.0, + "branch_time_in_parent": 59400.0, + + "#note_institution_id": "institution_id must be registered at https://github.com/WCRP-CMIP/CMIP6_CVs/issues/new ", + "institution_id": "PCMDI", + + "#note_source_id": "source_id (model name) must be registered at https://github.com/WCRP-CMIP/CMIP6_CVs/issues/new ", + "source_id": "PCMDI-test-1-0", + + "calendar": "360_day", + + "grid": "native atmosphere regular grid (3x4 latxlon)", + "grid_label": "gn", + "nominal_resolution": "10000 km", + + "license": "CMIP6 model data produced by Lawrence Livermore PCMDI is licensed under a Creative Commons Attribution ShareAlike 4.0 International License (https://creativecommons.org/licenses). Consult https://pcmdi.llnl.gov/CMIP6/TermsOfUse for terms of use governing CMIP6 output, including citation requirements and proper acknowledgment. Further information about this data, including some limitations, can be found via the further_info_url (recorded as a global attribute in this file) and at https:///pcmdi.llnl.gov/. The data producers and data providers make no warranty, either express or implied, including, but not limited to, warranties of merchantability and fitness for a particular purpose. All liabilities arising from the supply of the information (including any liability arising in negligence) are excluded to the fullest extent permitted by law.", + + "#output": "Root directory for output (can be either a relative or full path)", + "outpath": "CMIP6", + + "#note_optional": " **** The following descriptors are optional and may be set to an empty string ", + + "contact ": "Python Coder (coder@a.b.c.com)", + "history": "Output from archivcl_A1.nce/giccm_03_std_2xCO2_2256.", + "comment": "", + "references": "Model described by Koder and Tolkien (J. Geophys. Res., 2001, 576-591). Also see http://www.GICC.su/giccm/doc/index.html. The ssp245 simulation is described in Dorkey et al. '(Clim. Dyn., 2003, 323-357.)'", + + "#note_CV": " **** The following will be obtained from the CV and do not need to be defined here", + + "sub_experiment": "none", + "institution": "", + "source": "PCMDI-test 1.0 (1989)", + + "#note_CMIP6": " **** The following are set correctly for CMIP6 and should not normally need editing", + + "_control_vocabulary_file": "CMIP6_CV.json", + "_AXIS_ENTRY_FILE": "CMIP6_coordinate.json", + "_FORMULA_VAR_FILE": "CMIP6_formula_terms.json", + "_cmip6_option": "CMIP6", + + "mip_era": "CMIP6", + "parent_mip_era": "CMIP6", + + "tracking_prefix": "hdl:21.14100", + "_history_template": "%s ;rewrote data to be consistent with for variable found in table .", + + "#output_path_template": "Template for output path directory using tables keys or global attributes, these should follow the relevant data reference syntax", + "output_path_template": "<_member_id>", + "output_file_template": "
<_member_id>" + } \ No newline at end of file diff --git a/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_Aday.json b/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_Aday.json index 0f945e4327..3f5e1d7531 100644 --- a/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_Aday.json +++ b/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_Aday.json @@ -1,17 +1,17 @@ { "Header":{ - "#dataRequest_specs_version":"01.00.21", + "#dataRequest_specs_version":"01.00.29", "#mip_era":"CMIP6", "Conventions":"CF-1.7 ODS-2.1", "approx_interval":"1.00000", - "cmor_version":"3.2", + "cmor_version":"3.4", "data_specs_version":"2.1.0", "generic_levels":"", "int_missing_value":"-2147483648", "missing_value":"1e20", "product":"observations", "realm":"atmos", - "table_date":"07 March 2018", + "table_date":"11 April 2019", "table_id":"Table obs4MIPs_Aday" }, "variable_entry":{ @@ -21,7 +21,7 @@ "comment":"Total cloud area fraction for the whole atmospheric column, as seen from the surface or the top of the atmosphere. Includes both large-scale and convective cloud.", "dimensions":"longitude latitude time", "frequency":"day", - "long_name":"Total Cloud Fraction", + "long_name":"Total Cloud Cover Percentage", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"clt", @@ -35,7 +35,7 @@ "hfls":{ "cell_measures":"", "cell_methods":"area: time: mean", - "comment":"", + "comment":"The surface called 'surface' means the lower boundary of the atmosphere. 'Upward' indicates a vector component which is positive when directed upward (negative downward). The surface latent heat flux is the exchange of heat between the surface and the air on account of evaporation (including sublimation). In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions":"longitude latitude time", "frequency":"day", "long_name":"Surface Upward Latent Heat Flux", @@ -52,7 +52,7 @@ "hfss":{ "cell_measures":"", "cell_methods":"area: time: mean", - "comment":"", + "comment":"The surface sensible heat flux, also called turbulent heat flux, is the exchange of heat between the surface and the air by motion of air.", "dimensions":"longitude latitude time", "frequency":"day", "long_name":"Surface Upward Sensible Heat Flux", @@ -103,10 +103,10 @@ "hursmax":{ "cell_measures":"", "cell_methods":"area: mean time: maximum", - "comment":"", + "comment":"The relative humidity with respect to liquid water for T> 0 C, and with respect to ice for T<0 C.", "dimensions":"longitude latitude time height2m", "frequency":"day", - "long_name":"Surface Daily Maximum Relative Humidity", + "long_name":"Daily Maximum Near-Surface Relative Humidity", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"hursmax", @@ -120,10 +120,10 @@ "hursmin":{ "cell_measures":"", "cell_methods":"area: mean time: minimum", - "comment":"", + "comment":"The relative humidity with respect to liquid water for T> 0 C, and with respect to ice for T<0 C.", "dimensions":"longitude latitude time height2m", "frequency":"day", - "long_name":"Surface Daily Minimum Relative Humidity", + "long_name":"Daily Minimum Near-Surface Relative Humidity", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"hursmin", @@ -137,7 +137,7 @@ "hus":{ "cell_measures":"", "cell_methods":"time: mean", - "comment":"", + "comment":"Specific humidity is the mass fraction of water vapor in (moist) air.", "dimensions":"longitude latitude plev8 time", "frequency":"day", "long_name":"Specific Humidity", @@ -196,7 +196,7 @@ "ok_min_mean_abs":"", "out_name":"mrso", "positive":"", - "standard_name":"soil_moisture_content", + "standard_name":"mass_content_of_water_in_soil", "type":"real", "units":"kg m-2", "valid_max":"", @@ -213,7 +213,7 @@ "ok_min_mean_abs":"", "out_name":"mrsos", "positive":"", - "standard_name":"moisture_content_of_soil_layer", + "standard_name":"mass_content_of_water_in_soil_layer", "type":"real", "units":"kg m-2", "valid_max":"", @@ -256,7 +256,7 @@ "prsn":{ "cell_measures":"", "cell_methods":"area: time: mean", - "comment":"at surface; includes precipitation of all forms of water in the solid phase", + "comment":"At surface; includes precipitation of all forms of water in the solid phase", "dimensions":"longitude latitude time", "frequency":"day", "long_name":"Snowfall Flux", @@ -281,7 +281,7 @@ "ok_min_mean_abs":"", "out_name":"psl", "positive":"", - "standard_name":"air_pressure_at_sea_level", + "standard_name":"air_pressure_at_mean_sea_level", "type":"real", "units":"Pa", "valid_max":"", @@ -290,7 +290,7 @@ "rlds":{ "cell_measures":"", "cell_methods":"area: time: mean", - "comment":"", + "comment":"The surface called 'surface' means the lower boundary of the atmosphere. 'longwave' means longwave radiation. Downwelling radiation is radiation from above. It does not mean 'net downward'. When thought of as being incident on a surface, a radiative flux is sometimes called 'irradiance'. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called 'vector irradiance'. In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions":"longitude latitude time", "frequency":"day", "long_name":"Surface Downwelling Longwave Radiation", @@ -304,10 +304,27 @@ "valid_max":"", "valid_min":"" }, + "rls":{ + "cell_measures":"", + "cell_methods":"area: time: mean", + "comment":"Net longwave surface radiation", + "dimensions":"longitude latitude time", + "frequency":"day", + "long_name":"Net Longwave Surface Radiation", + "ok_max_mean_abs":"", + "ok_min_mean_abs":"", + "out_name":"rls", + "positive":"down", + "standard_name":"surface_net_downward_longwave_flux", + "type":"real", + "units":"W m-2", + "valid_max":"", + "valid_min":"" + }, "rlus":{ "cell_measures":"", "cell_methods":"area: time: mean", - "comment":"", + "comment":"The surface called 'surface' means the lower boundary of the atmosphere. 'longwave' means longwave radiation. Upwelling radiation is radiation from below. It does not mean 'net upward'. When thought of as being incident on a surface, a radiative flux is sometimes called 'irradiance'. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called 'vector irradiance'. In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions":"longitude latitude time", "frequency":"day", "long_name":"Surface Upwelling Longwave Radiation", @@ -341,7 +358,7 @@ "rsds":{ "cell_measures":"", "cell_methods":"area: time: mean", - "comment":"surface solar irradiance for UV calculations", + "comment":"Surface solar irradiance for UV calculations.", "dimensions":"longitude latitude time", "frequency":"day", "long_name":"Surface Downwelling Shortwave Radiation", @@ -355,10 +372,27 @@ "valid_max":"", "valid_min":"" }, + "rss":{ + "cell_measures":"", + "cell_methods":"area: time: mean", + "comment":"Net downward shortwave radiation at the surface", + "dimensions":"longitude latitude time", + "frequency":"day", + "long_name":"Net Shortwave Surface Radiation", + "ok_max_mean_abs":"", + "ok_min_mean_abs":"", + "out_name":"rss", + "positive":"down", + "standard_name":"surface_net_downward_shortwave_flux", + "type":"real", + "units":"W m-2", + "valid_max":"", + "valid_min":"" + }, "rsus":{ "cell_measures":"", "cell_methods":"area: time: mean", - "comment":"", + "comment":"The surface called 'surface' means the lower boundary of the atmosphere. 'shortwave' means shortwave radiation. Upwelling radiation is radiation from below. It does not mean 'net upward'. When thought of as being incident on a surface, a radiative flux is sometimes called 'irradiance'. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called 'vector irradiance'. In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions":"longitude latitude time", "frequency":"day", "long_name":"Surface Upwelling Shortwave Radiation", @@ -412,7 +446,7 @@ "comment":"Fraction of each grid cell that is occupied by snow that rests on land portion of cell.", "dimensions":"longitude latitude time", "frequency":"day", - "long_name":"Snow Area Fraction", + "long_name":"Snow Area Percentage", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"snc", @@ -528,7 +562,7 @@ "ua":{ "cell_measures":"", "cell_methods":"time: mean", - "comment":"", + "comment":"Zonal wind (positive in a eastward direction).", "dimensions":"longitude latitude plev8 time", "frequency":"day", "long_name":"Eastward Wind", @@ -562,7 +596,7 @@ "va":{ "cell_measures":"", "cell_methods":"time: mean", - "comment":"", + "comment":"Meridional wind (positive in a northward direction).", "dimensions":"longitude latitude plev8 time", "frequency":"day", "long_name":"Northward Wind", @@ -599,7 +633,7 @@ "comment":"Omega (vertical velocity in pressure coordinates, positive downwards)", "dimensions":"longitude latitude plev8 time", "frequency":"day", - "long_name":"omega (=dp/dt)", + "long_name":"Omega (=dp/dt)", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"wap", @@ -613,7 +647,7 @@ "zg":{ "cell_measures":"", "cell_methods":"time: mean", - "comment":"", + "comment":"Geopotential is the sum of the specific gravitational potential energy relative to the geoid and the specific centripetal potential energy. Geopotential height is the geopotential divided by the standard acceleration due to gravity. It is numerically similar to the altitude (or geometric height) and not to the quantity with standard name height, which is relative to the surface.", "dimensions":"longitude latitude plev8 time", "frequency":"day", "long_name":"Geopotential Height", diff --git a/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_Amon.json b/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_Amon.json index 8862bb46d7..a76a953408 100644 --- a/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_Amon.json +++ b/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_Amon.json @@ -1,17 +1,17 @@ { "Header":{ - "#dataRequest_specs_version":"01.00.21", + "#dataRequest_specs_version":"01.00.29", "#mip_era":"CMIP6", "Conventions":"CF-1.7 ODS-2.1", "approx_interval":"30.00000", - "cmor_version":"3.2", + "cmor_version":"3.4", "data_specs_version":"2.1.0", "generic_levels":"alevel alevhalf", "int_missing_value":"-2147483648", "missing_value":"1e20", "product":"observations", "realm":"atmos", - "table_date":"07 March 2018", + "table_date":"11 April 2019", "table_id":"Table obs4MIPs_Amon" }, "variable_entry":{ @@ -52,7 +52,7 @@ "cfc113global":{ "cell_measures":"", "cell_methods":"area: time: mean", - "comment":"", + "comment":"Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. The chemical formula of CFC113 is CCl2FCClF2. The IUPAC name for CFC113 is 1,1,2-trichloro-1,2,2-trifluoro-ethane.", "dimensions":"time", "frequency":"mon", "long_name":"Global Mean Mole Fraction of CFC113", @@ -69,7 +69,7 @@ "cfc11global":{ "cell_measures":"", "cell_methods":"area: time: mean", - "comment":"", + "comment":"Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. The chemical formula of CFC11 is CFCl3. The IUPAC name for CFC11 is trichloro-fluoro-methane.", "dimensions":"time", "frequency":"mon", "long_name":"Global Mean Mole Fraction of CFC11", @@ -86,7 +86,7 @@ "cfc12global":{ "cell_measures":"", "cell_methods":"area: time: mean", - "comment":"", + "comment":"Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. The chemical formula of CFC12 is CF2Cl2. The IUPAC name for CFC12 is dichloro-difluoro-methane.", "dimensions":"time", "frequency":"mon", "long_name":"Global Mean Mole Fraction of CFC12", @@ -103,7 +103,7 @@ "ch4":{ "cell_measures":"", "cell_methods":"time: mean", - "comment":"", + "comment":"Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", "dimensions":"longitude latitude plev19 time", "frequency":"mon", "long_name":"Mole Fraction of CH4", @@ -120,7 +120,7 @@ "ch4Clim":{ "cell_measures":"", "cell_methods":"area: mean time: mean within years time: mean over years", - "comment":"", + "comment":"Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", "dimensions":"longitude latitude plev19 time2", "frequency":"monC", "long_name":"Mole Fraction of CH4", @@ -174,7 +174,7 @@ "comment":"Fraction of time that convection occurs in the grid cell.", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Fraction of Time Convection Occurs", + "long_name":"Fraction of Time Convection Occurs in Cell", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"ci", @@ -191,7 +191,7 @@ "comment":"Percentage cloud cover, including both large-scale and convective cloud.", "dimensions":"longitude latitude alevel time", "frequency":"mon", - "long_name":"Cloud Area Fraction", + "long_name":"Percentage Cloud Cover", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"cl", @@ -264,7 +264,7 @@ "ok_min_mean_abs":"", "out_name":"clivi", "positive":"", - "standard_name":"atmosphere_cloud_ice_content", + "standard_name":"atmosphere_mass_content_of_cloud_ice", "type":"real", "units":"kg m-2", "valid_max":"", @@ -276,7 +276,7 @@ "comment":"Total cloud area fraction for the whole atmospheric column, as seen from the surface or the top of the atmosphere. Includes both large-scale and convective cloud.", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Total Cloud Fraction", + "long_name":"Total Cloud Cover Percentage", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"clt", @@ -417,7 +417,7 @@ "ok_min_mean_abs":"", "out_name":"clwvi", "positive":"", - "standard_name":"atmosphere_cloud_condensed_water_content", + "standard_name":"atmosphere_mass_content_of_cloud_condensed_water", "type":"real", "units":"kg m-2", "valid_max":"", @@ -426,7 +426,7 @@ "co2":{ "cell_measures":"", "cell_methods":"time: mean", - "comment":"", + "comment":"Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", "dimensions":"longitude latitude plev19 time", "frequency":"mon", "long_name":"Mole Fraction of CO2", @@ -443,7 +443,7 @@ "co2Clim":{ "cell_measures":"", "cell_methods":"area: mean time: mean within years time: mean over years", - "comment":"", + "comment":"Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", "dimensions":"longitude latitude plev19 time2", "frequency":"monC", "long_name":"Mole Fraction of CO2", @@ -494,15 +494,15 @@ "evspsbl":{ "cell_measures":"", "cell_methods":"area: time: mean", - "comment":"Evaporation at surface: flux of water into the atmosphere due to conversion of both liquid and solid phases to vapor (from underlying surface and vegetation)", + "comment":"Evaporation at surface (also known as evapotranspiration): flux of water into the atmosphere due to conversion of both liquid and solid phases to vapor (from underlying surface and vegetation)", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Evaporation", + "long_name":"Evaporation Including Sublimation and Transpiration", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"evspsbl", "positive":"", - "standard_name":"water_evaporation_flux", + "standard_name":"water_evapotranspiration_flux", "type":"real", "units":"kg m-2 s-1", "valid_max":"", @@ -562,7 +562,7 @@ "hcfc22global":{ "cell_measures":"", "cell_methods":"area: time: mean", - "comment":"", + "comment":"Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. A chemical species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for HCFC22 is CHClF2. The IUPAC name for HCFC22 is chloro-difluoro-methane.", "dimensions":"time", "frequency":"mon", "long_name":"Global Mean Mole Fraction of HCFC22", @@ -579,7 +579,7 @@ "hfls":{ "cell_measures":"", "cell_methods":"area: time: mean", - "comment":"", + "comment":"The surface called 'surface' means the lower boundary of the atmosphere. 'Upward' indicates a vector component which is positive when directed upward (negative downward). The surface latent heat flux is the exchange of heat between the surface and the air on account of evaporation (including sublimation). In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions":"longitude latitude time", "frequency":"mon", "long_name":"Surface Upward Latent Heat Flux", @@ -596,7 +596,7 @@ "hfss":{ "cell_measures":"", "cell_methods":"area: time: mean", - "comment":"", + "comment":"The surface sensible heat flux, also called turbulent heat flux, is the exchange of heat between the surface and the air by motion of air.", "dimensions":"longitude latitude time", "frequency":"mon", "long_name":"Surface Upward Sensible Heat Flux", @@ -647,7 +647,7 @@ "hus":{ "cell_measures":"", "cell_methods":"time: mean", - "comment":"", + "comment":"Specific humidity is the mass fraction of water vapor in (moist) air.", "dimensions":"longitude latitude plev19 time", "frequency":"mon", "long_name":"Specific Humidity", @@ -698,7 +698,7 @@ "n2o":{ "cell_measures":"", "cell_methods":"time: mean", - "comment":"", + "comment":"Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. The chemical formula of nitrous oxide is N2O.", "dimensions":"longitude latitude plev19 time", "frequency":"mon", "long_name":"Mole Fraction of N2O", @@ -715,7 +715,7 @@ "n2oClim":{ "cell_measures":"", "cell_methods":"area: mean time: mean within years time: mean over years", - "comment":"", + "comment":"Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y. The chemical formula of nitrous oxide is N2O.", "dimensions":"longitude latitude plev19 time2", "frequency":"monC", "long_name":"Mole Fraction of N2O", @@ -766,7 +766,7 @@ "o3":{ "cell_measures":"", "cell_methods":"time: mean", - "comment":"", + "comment":"Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", "dimensions":"longitude latitude plev19 time", "frequency":"mon", "long_name":"Mole Fraction of O3", @@ -783,7 +783,7 @@ "o3Clim":{ "cell_measures":"", "cell_methods":"area: mean time: mean within years time: mean over years", - "comment":"", + "comment":"Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.", "dimensions":"longitude latitude plev19 time2", "frequency":"monC", "long_name":"Mole Fraction of O3", @@ -885,7 +885,7 @@ "prsn":{ "cell_measures":"", "cell_methods":"area: time: mean", - "comment":"at surface; includes precipitation of all forms of water in the solid phase", + "comment":"At surface; includes precipitation of all forms of water in the solid phase", "dimensions":"longitude latitude time", "frequency":"mon", "long_name":"Snowfall Flux", @@ -910,7 +910,7 @@ "ok_min_mean_abs":"", "out_name":"prw", "positive":"", - "standard_name":"atmosphere_water_vapor_content", + "standard_name":"atmosphere_mass_content_of_water_vapor", "type":"real", "units":"kg m-2", "valid_max":"", @@ -944,7 +944,7 @@ "ok_min_mean_abs":"", "out_name":"psl", "positive":"", - "standard_name":"air_pressure_at_sea_level", + "standard_name":"air_pressure_at_mean_sea_level", "type":"real", "units":"Pa", "valid_max":"", @@ -953,7 +953,7 @@ "rlds":{ "cell_measures":"", "cell_methods":"area: time: mean", - "comment":"", + "comment":"The surface called 'surface' means the lower boundary of the atmosphere. 'longwave' means longwave radiation. Downwelling radiation is radiation from above. It does not mean 'net downward'. When thought of as being incident on a surface, a radiative flux is sometimes called 'irradiance'. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called 'vector irradiance'. In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions":"longitude latitude time", "frequency":"mon", "long_name":"Surface Downwelling Longwave Radiation", @@ -987,7 +987,7 @@ "rlus":{ "cell_measures":"", "cell_methods":"area: time: mean", - "comment":"", + "comment":"The surface called 'surface' means the lower boundary of the atmosphere. 'longwave' means longwave radiation. Upwelling radiation is radiation from below. It does not mean 'net upward'. When thought of as being incident on a surface, a radiative flux is sometimes called 'irradiance'. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called 'vector irradiance'. In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions":"longitude latitude time", "frequency":"mon", "long_name":"Surface Upwelling Longwave Radiation", @@ -1038,7 +1038,7 @@ "rsds":{ "cell_measures":"", "cell_methods":"area: time: mean", - "comment":"surface solar irradiance for UV calculations", + "comment":"Surface solar irradiance for UV calculations.", "dimensions":"longitude latitude time", "frequency":"mon", "long_name":"Surface Downwelling Shortwave Radiation", @@ -1055,7 +1055,7 @@ "rsdscs":{ "cell_measures":"", "cell_methods":"area: time: mean", - "comment":"surface solar irradiance clear sky for UV calculations", + "comment":"Surface solar irradiance clear sky for UV calculations", "dimensions":"longitude latitude time", "frequency":"mon", "long_name":"Surface Downwelling Clear-Sky Shortwave Radiation", @@ -1089,7 +1089,7 @@ "rsus":{ "cell_measures":"", "cell_methods":"area: time: mean", - "comment":"", + "comment":"The surface called 'surface' means the lower boundary of the atmosphere. 'shortwave' means shortwave radiation. Upwelling radiation is radiation from below. It does not mean 'net upward'. When thought of as being incident on a surface, a radiative flux is sometimes called 'irradiance'. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called 'vector irradiance'. In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions":"longitude latitude time", "frequency":"mon", "long_name":"Surface Upwelling Shortwave Radiation", @@ -1160,7 +1160,7 @@ "comment":"Net Downward Radiative Flux at Top of Model : I.e., at the top of that portion of the atmosphere where dynamics are explicitly treated by the model. This is reported only if it differs from the net downward radiative flux at the top of the atmosphere.", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Net Downward Flux at Top of Model", + "long_name":"Net Downward Radiative Flux at Top of Model", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"rtmt", @@ -1182,7 +1182,7 @@ "ok_min_mean_abs":"", "out_name":"sbl", "positive":"", - "standard_name":"surface_snow_and_ice_sublimation_flux", + "standard_name":"tendency_of_atmosphere_mass_content_of_water_vapor_due_to_sublimation_of_surface_snow_and_ice", "type":"real", "units":"kg m-2 s-1", "valid_max":"", @@ -1361,7 +1361,7 @@ "ua":{ "cell_measures":"", "cell_methods":"time: mean", - "comment":"", + "comment":"Zonal wind (positive in a eastward direction).", "dimensions":"longitude latitude plev19 time", "frequency":"mon", "long_name":"Eastward Wind", @@ -1395,7 +1395,7 @@ "va":{ "cell_measures":"", "cell_methods":"time: mean", - "comment":"", + "comment":"Meridional wind (positive in a northward direction).", "dimensions":"longitude latitude plev19 time", "frequency":"mon", "long_name":"Northward Wind", @@ -1432,7 +1432,7 @@ "comment":"Omega (vertical velocity in pressure coordinates, positive downwards)", "dimensions":"longitude latitude plev19 time", "frequency":"mon", - "long_name":"omega (=dp/dt)", + "long_name":"Omega (=dp/dt)", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"wap", @@ -1446,7 +1446,7 @@ "zg":{ "cell_measures":"", "cell_methods":"time: mean", - "comment":"", + "comment":"Geopotential is the sum of the specific gravitational potential energy relative to the geoid and the specific centripetal potential energy. Geopotential height is the geopotential divided by the standard acceleration due to gravity. It is numerically similar to the altitude (or geometric height) and not to the quantity with standard name height, which is relative to the surface.", "dimensions":"longitude latitude plev19 time", "frequency":"mon", "long_name":"Geopotential Height", diff --git a/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_CV.json b/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_CV.json index 5f30ba78aa..a117dff948 100644 --- a/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_CV.json +++ b/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_CV.json @@ -20,54 +20,70 @@ "yrPt":"sampled yearly, at specified time point within the time period" }, "grid_label":{ - "gm":"global mean data", - "gn":"data reported on a model's native grid", - "gna":"data reported on a native grid in the region of Antarctica", - "gng":"data reported on a native grid in the region of Greenland", - "gnz":"zonal mean data reported on a model's native latitude grid", - "gr":"regridded data reported on the data provider's preferred target grid", - "gr1":"regridded data reported on a grid other than the native grid and other than the preferred target grid", - "gr1a":"regridded data reported in the region of Antarctica on a grid other than the native grid and other than the preferred target grid", - "gr1g":"regridded data reported in the region of Greenland on a grid other than the native grid and other than the preferred target grid", - "gr1z":"regridded zonal mean data reported on a grid other than the native latitude grid and other than the preferred latitude target grid", - "gr2":"regridded data reported on a grid other than the native grid and other than the preferred target grid", - "gr2a":"regridded data reported in the region of Antarctica on a grid other than the native grid and other than the preferred target grid", - "gr2g":"regridded data reported in the region of Greenland on a grid other than the native grid and other than the preferred target grid", - "gr2z":"regridded zonal mean data reported on a grid other than the native latitude grid and other than the preferred latitude target grid", - "gr3":"regridded data reported on a grid other than the native grid and other than the preferred target grid", - "gr3a":"regridded data reported in the region of Antarctica on a grid other than the native grid and other than the preferred target grid", - "gr3g":"regridded data reported in the region of Greenland on a grid other than the native grid and other than the preferred target grid", - "gr3z":"regridded zonal mean data reported on a grid other than the native latitude grid and other than the preferred latitude target grid", - "gr4":"regridded data reported on a grid other than the native grid and other than the preferred target grid", - "gr4a":"regridded data reported in the region of Antarctica on a grid other than the native grid and other than the preferred target grid", - "gr4g":"regridded data reported in the region of Greenland on a grid other than the native grid and other than the preferred target grid", - "gr4z":"regridded zonal mean data reported on a grid other than the native latitude grid and other than the preferred latitude target grid", - "gr5":"regridded data reported on a grid other than the native grid and other than the preferred target grid", - "gr5a":"regridded data reported in the region of Antarctica on a grid other than the native grid and other than the preferred target grid", - "gr5g":"regridded data reported in the region of Greenland on a grid other than the native grid and other than the preferred target grid", - "gr5z":"regridded zonal mean data reported on a grid other than the native latitude grid and other than the preferred latitude target grid", - "gr6":"regridded data reported on a grid other than the native grid and other than the preferred target grid", - "gr6a":"regridded data reported in the region of Antarctica on a grid other than the native grid and other than the preferred target grid", - "gr6g":"regridded data reported in the region of Greenland on a grid other than the native grid and other than the preferred target grid", - "gr6z":"regridded zonal mean data reported on a grid other than the native latitude grid and other than the preferred latitude target grid", - "gr7":"regridded data reported on a grid other than the native grid and other than the preferred target grid", - "gr7a":"regridded data reported in the region of Antarctica on a grid other than the native grid and other than the preferred target grid", - "gr7g":"regridded data reported in the region of Greenland on a grid other than the native grid and other than the preferred target grid", - "gr7z":"regridded zonal mean data reported on a grid other than the native latitude grid and other than the preferred latitude target grid", - "gr8":"regridded data reported on a grid other than the native grid and other than the preferred target grid", - "gr8a":"regridded data reported in the region of Antarctica on a grid other than the native grid and other than the preferred target grid", - "gr8g":"regridded data reported in the region of Greenland on a grid other than the native grid and other than the preferred target grid", - "gr8z":"regridded zonal mean data reported on a grid other than the native latitude grid and other than the preferred latitude target grid", - "gr9":"regridded data reported on a grid other than the native grid and other than the preferred target grid", - "gr9a":"regridded data reported in the region of Antarctica on a grid other than the native grid and other than the preferred target grid", - "gr9g":"regridded data reported in the region of Greenland on a grid other than the native grid and other than the preferred target grid", - "gr9z":"regridded zonal mean data reported on a grid other than the native latitude grid and other than the preferred latitude target grid", - "gra":"regridded data in the region of Antarctica reported on the data provider's preferred target grid", - "grg":"regridded data in the region of Greenland reported on the data provider's preferred target grid", - "grz":"regridded zonal mean data reported on the data provider's preferred latitude target grid" + "grid_label":{ + "gm":"global mean data", + "gn":"data reported on a model's native grid", + "gnNH":"data reported on a native grid in the Northern Hemisphere", + "gnSH":"data reported on a native grid in the Southern Hemisphere", + "gna":"data reported on a native grid in the region of Antarctica", + "gng":"data reported on a native grid in the region of Greenland", + "gnz":"zonal mean data reported on a model's native latitude grid", + "gr":"regridded data reported on the data provider's preferred target grid", + "gr1":"regridded data reported on a grid other than the native grid and other than the preferred target grid", + "gr1a":"regridded data reported in the region of Antarctica on a grid other than the native grid and other than the preferred target grid", + "gr1g":"regridded data reported in the region of Greenland on a grid other than the native grid and other than the preferred target grid", + "gr1z":"regridded zonal mean data reported on a grid other than the native latitude grid and other than the preferred latitude target grid", + "gr2":"regridded data reported on a grid other than the native grid and other than the preferred target grid", + "gr2a":"regridded data reported in the region of Antarctica on a grid other than the native grid and other than the preferred target grid", + "gr2g":"regridded data reported in the region of Greenland on a grid other than the native grid and other than the preferred target grid", + "gr2z":"regridded zonal mean data reported on a grid other than the native latitude grid and other than the preferred latitude target grid", + "gr3":"regridded data reported on a grid other than the native grid and other than the preferred target grid", + "gr3a":"regridded data reported in the region of Antarctica on a grid other than the native grid and other than the preferred target grid", + "gr3g":"regridded data reported in the region of Greenland on a grid other than the native grid and other than the preferred target grid", + "gr3z":"regridded zonal mean data reported on a grid other than the native latitude grid and other than the preferred latitude target grid", + "gr4":"regridded data reported on a grid other than the native grid and other than the preferred target grid", + "gr4a":"regridded data reported in the region of Antarctica on a grid other than the native grid and other than the preferred target grid", + "gr4g":"regridded data reported in the region of Greenland on a grid other than the native grid and other than the preferred target grid", + "gr4z":"regridded zonal mean data reported on a grid other than the native latitude grid and other than the preferred latitude target grid", + "gr5":"regridded data reported on a grid other than the native grid and other than the preferred target grid", + "gr5a":"regridded data reported in the region of Antarctica on a grid other than the native grid and other than the preferred target grid", + "gr5g":"regridded data reported in the region of Greenland on a grid other than the native grid and other than the preferred target grid", + "gr5z":"regridded zonal mean data reported on a grid other than the native latitude grid and other than the preferred latitude target grid", + "gr6":"regridded data reported on a grid other than the native grid and other than the preferred target grid", + "gr6a":"regridded data reported in the region of Antarctica on a grid other than the native grid and other than the preferred target grid", + "gr6g":"regridded data reported in the region of Greenland on a grid other than the native grid and other than the preferred target grid", + "gr6z":"regridded zonal mean data reported on a grid other than the native latitude grid and other than the preferred latitude target grid", + "gr7":"regridded data reported on a grid other than the native grid and other than the preferred target grid", + "gr7a":"regridded data reported in the region of Antarctica on a grid other than the native grid and other than the preferred target grid", + "gr7g":"regridded data reported in the region of Greenland on a grid other than the native grid and other than the preferred target grid", + "gr7z":"regridded zonal mean data reported on a grid other than the native latitude grid and other than the preferred latitude target grid", + "gr8":"regridded data reported on a grid other than the native grid and other than the preferred target grid", + "gr8a":"regridded data reported in the region of Antarctica on a grid other than the native grid and other than the preferred target grid", + "gr8g":"regridded data reported in the region of Greenland on a grid other than the native grid and other than the preferred target grid", + "gr8z":"regridded zonal mean data reported on a grid other than the native latitude grid and other than the preferred latitude target grid", + "gr9":"regridded data reported on a grid other than the native grid and other than the preferred target grid", + "gr9a":"regridded data reported in the region of Antarctica on a grid other than the native grid and other than the preferred target grid", + "gr9g":"regridded data reported in the region of Greenland on a grid other than the native grid and other than the preferred target grid", + "gr9z":"regridded zonal mean data reported on a grid other than the native latitude grid and other than the preferred latitude target grid", + "gra":"regridded data in the region of Antarctica reported on the data provider's preferred target grid", + "grg":"regridded data in the region of Greenland reported on the data provider's preferred target grid", + "grz":"regridded zonal mean data reported on the data provider's preferred latitude target grid" + }, + "version_metadata":{ + "CV_collection_modified":"Mon Mar 25 14:32:35 2019 -0700", + "CV_collection_version":"6.2.20.1", + "author":"Paul J. Durack ", + "grid_label_CV_modified":"Fri Sep 8 18:12:00 2017 -0700", + "grid_label_CV_note":"Issue395 durack1 augment grid_label with description (#401)", + "institution_id":"PCMDI", + "previous_commit":"690451863bfd7a92a6fa13d879a9df6af32e0379", + "specs_doc":"v6.2.7 (10th September 2018; https://goo.gl/v1drZl)" + } }, "institution_id":{ + "CNES":"Centre national d'etudes spatiales", "DWD":"Deutscher Wetterdienst, Offenbach 63067, Germany", + "NASA-GSFC":"National Aeronautics and Space Administration, Goddard Space Flight Center", "NASA-JPL":"NASA's Jet Propulsion Laboratory, Pasadena, CA 91109, USA", "NOAA-NCEI":"NOAA's National Centers for Environmental Information, Asheville, NC 28801, USA", "PCMDI":"Program for Climate Model Diagnosis and Intercomparison, Lawrence Livermore National Laboratory, Livermore, CA 94550, USA", @@ -204,6 +220,27 @@ "source_type":"satellite_retrieval", "source_version_number":"1.0" }, + "AIRS-2-0":{ + "region":"global", + "source":"AIRS 2.0 (2011): Atmospheric Infrared Sounder", + "source_label":"AIRS", + "source_type":"satellite_retrieval", + "source_version_number":"2.0" + }, + "AMSRE-v7":{ + "region":"global_ocean", + "source":"AMRSE v7 v7 (2011): Sea Surface Temperature from AMSR-E onboard AQUA", + "source_label":"AMRSE v7", + "source_type":"satellite_retrieval", + "source_version_number":"v7" + }, + "AVISO-1-0":{ + "region":"global", + "source":"AVISO 1 0 1.0 (2011): Sea Surface Height Above Geoid", + "source_label":"AVISO 1 0", + "source_type":"satellite_retrieval", + "source_version_number":"1.0" + }, "Aura-MLS-v04-2":{ "region":"global", "source":"Aura-MLS v04.2 (2018): EOS Aura Microwave Limb Sounder", @@ -267,6 +304,27 @@ "source_type":"satellite_retrieval", "source_version_number":"1.3" }, + "GPCP-1DD":{ + "region":"global", + "source":"GPCP 1DD 1.3 (2013): Global Precipitation Climatology Project One Degree Daily", + "source_label":"GPCP 1DD", + "source_type":"satellite_blended", + "source_version_number":"1.3" + }, + "GPCP-SG":{ + "region":"global", + "source":"GPCP SG 2.3 (2016): Global Precipitation Climatology Project Satellite-Gauge", + "source_label":"GPCP SG", + "source_type":"satellite_blended", + "source_version_number":"2.3" + }, + "MODIS-1-0":{ + "region":"global", + "source":"MODIS 1.0 (2011): Atmospheric Infrared Sounder", + "source_label":"MODIS", + "source_type":"satellite_retrieval", + "source_version_number":"1.0" + }, "NOAA-NCEI-AVHRR-NDVI-4-0":{ "region":"global_land", "source":"NOAA-NCEI-AVHRR-NDVI 4.0 (2013): Normalized Difference Vegetation Index", @@ -295,6 +353,13 @@ "source_type":"satellite_retrieval", "source_version_number":"4.0" }, + "NOAA-NCEI-HIRS-OLR-1-2":{ + "region":"global", + "source":"NOAA NCEI HIRS OLR 1.2 (2014): HIRS Outgoing Longwave Radiation", + "source_label":"NOAA NCEI HIRS OLR", + "source_type":"satellite_retrieval", + "source_version_number":"1.2" + }, "NOAA-NCEI-LAI-4-0":{ "region":"global_land", "source":"NOAA-NCEI-LAI 4.0 (2014): AVHRR Leaf Area Index", @@ -302,6 +367,13 @@ "source_type":"satellite_retrieval", "source_version_number":"4.0" }, + "NOAA-NCEI-OISST-2-0":{ + "region":"global_ocean", + "source":"NOAA NCEI OISST 2.0 (2008): Optimal Interpolation Sea Surface Temperature", + "source_label":"NOAA NCEI OISST", + "source_type":"satellite_blended", + "source_version_number":"2.0" + }, "NOAA-NCEI-PERSIANN-1-1":{ "region":"global", "source":"NOAA-NCEI-PERSIANN 1.1 (2014): Precipitation Estimation from Remotely Sensed Information using Artificial Neural Network", @@ -309,6 +381,13 @@ "source_type":"satellite_retrieval", "source_version_number":"1.1" }, + "NOAA-NCEI-SSMI-SeaIce-2-0":{ + "region":"arctic_ocean, southern_ocean", + "source":"NOAA-NCEI-SSMI-SeaIce 2.0 (2013): SSMI Passive Microwave Sea Ice Area Fraction", + "source_label":"NOAA-NCEI-SSMI-SeaIce", + "source_type":"satellite_retrieval", + "source_version_number":"2.0" + }, "NOAA-NCEI-SeaWinds-1-2":{ "region":"global_ocean", "source":"NOAA-NCEI-SeaWinds 1.2 (2008): Blended Sea Surface Winds", @@ -329,6 +408,20 @@ "source_label":"REMSS-PRW", "source_type":"satellite_blended", "source_version_number":"6.6.0" + }, + "RSS-v7":{ + "region":"global_ocean", + "source":"RSS-v7 v7 (2011): Satellite derived fields produced by RSS", + "source_label":"RSS-v7", + "source_type":"satellite_retrieval", + "source_version_number":"v7" + }, + "TES-1-0":{ + "region":"global", + "source":"TES 1 0 1.0 (2011): Mole Fraction of O3", + "source_label":"TES 1 0", + "source_type":"satellite_retrieval", + "source_version_number":"1.0" } }, "source_type":{ diff --git a/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_Lmon.json b/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_Lmon.json index 55666ea58e..ed2fadeefe 100644 --- a/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_Lmon.json +++ b/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_Lmon.json @@ -1,17 +1,17 @@ { "Header":{ - "#dataRequest_specs_version":"01.00.21", + "#dataRequest_specs_version":"01.00.29", "#mip_era":"CMIP6", "Conventions":"CF-1.7 ODS-2.1", "approx_interval":"30.00000", - "cmor_version":"3.2", + "cmor_version":"3.4", "data_specs_version":"2.1.0", "generic_levels":"", "int_missing_value":"-2147483648", "missing_value":"1e20", "product":"observations", "realm":"land", - "table_date":"07 March 2018", + "table_date":"11 April 2019", "table_id":"Table obs4MIPs_Lmon" }, "variable_entry":{ @@ -21,7 +21,7 @@ "comment":"Percentage of entire grid cell that is covered by bare soil.", "dimensions":"longitude latitude time typebare", "frequency":"mon", - "long_name":"Bare Soil Fraction", + "long_name":"Bare Soil Percentage Area Coverage", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"baresoilFrac", @@ -35,7 +35,7 @@ "burntFractionAll":{ "cell_measures":"", "cell_methods":"area: mean where land over all_area_types time: mean", - "comment":"Percentage of grid cell burned due to all fires including natural and anthropogenic fires and those associated with anthropogenic land use change", + "comment":"Percentage of grid cell burned due to all fires including natural and anthropogenic fires and those associated with anthropogenic Land-use change", "dimensions":"longitude latitude time typeburnt", "frequency":"mon", "long_name":"Percentage of Entire Grid cell that is Covered by Burnt Vegetation (All Classes)", @@ -55,7 +55,7 @@ "comment":"Percentage of entire grid cell that is covered by C3 PFTs (including grass, crops, and trees).", "dimensions":"longitude latitude time typec3pft", "frequency":"mon", - "long_name":"Total C3 PFT Cover Fraction", + "long_name":"Percentage Cover by C3 Plant Functional Type", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"c3PftFrac", @@ -72,7 +72,7 @@ "comment":"Percentage of entire grid cell that is covered by C4 PFTs (including grass and crops).", "dimensions":"longitude latitude time typec4pft", "frequency":"mon", - "long_name":"Total C4 PFT Cover Fraction", + "long_name":"Percentage Cover by C4 Plant Functional Type", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"c4PftFrac", @@ -94,7 +94,7 @@ "ok_min_mean_abs":"", "out_name":"cCwd", "positive":"", - "standard_name":"wood_debris_carbon_content", + "standard_name":"wood_debris_mass_content_of_carbon", "type":"real", "units":"kg m-2", "valid_max":"", @@ -111,7 +111,7 @@ "ok_min_mean_abs":"", "out_name":"cLeaf", "positive":"", - "standard_name":"leaf_carbon_content", + "standard_name":"leaf_mass_content_of_carbon", "type":"real", "units":"kg m-2", "valid_max":"", @@ -120,7 +120,7 @@ "cLitter":{ "cell_measures":"", "cell_methods":"area: mean where land time: mean", - "comment":"", + "comment":"'Litter' is dead plant material in or above the soil. It is distinct from coarse wood debris. The precise distinction between 'fine' and 'coarse' is model dependent. 'Content' indicates a quantity per unit area. The sum of the quantities with standard names surface_litter_mass_content_of_carbon and subsurface_litter_mass_content_of_carbon has the standard name litter_mass_content_of_carbon.", "dimensions":"longitude latitude time", "frequency":"mon", "long_name":"Carbon Mass in Litter Pool", @@ -128,7 +128,7 @@ "ok_min_mean_abs":"", "out_name":"cLitter", "positive":"", - "standard_name":"litter_carbon_content", + "standard_name":"litter_mass_content_of_carbon", "type":"real", "units":"kg m-2", "valid_max":"", @@ -137,7 +137,7 @@ "cLitterAbove":{ "cell_measures":"", "cell_methods":"area: mean where land time: mean", - "comment":"", + "comment":"'Litter' is dead plant material in or above the soil. It is distinct from coarse wood debris. The precise distinction between 'fine' and 'coarse' is model dependent. 'Surface litter' means the part of the litter resting above the soil surface. 'Content' indicates a quantity per unit area. The sum of the quantities with standard names surface_litter_mass_content_of_carbon and subsurface_litter_mass_content_of_carbon has the standard name litter_mass_content_of_carbon.", "dimensions":"longitude latitude time", "frequency":"mon", "long_name":"Carbon Mass in Above-Ground Litter", @@ -145,7 +145,7 @@ "ok_min_mean_abs":"", "out_name":"cLitterAbove", "positive":"", - "standard_name":"surface_litter_carbon_content", + "standard_name":"surface_litter_mass_content_of_carbon", "type":"real", "units":"kg m-2", "valid_max":"", @@ -154,7 +154,7 @@ "cLitterBelow":{ "cell_measures":"", "cell_methods":"area: mean where land time: mean", - "comment":"", + "comment":"'Litter' is dead plant material in or above the soil. It is distinct from coarse wood debris. The precise distinction between 'fine' and 'coarse' is model dependent. 'subsurface litter' means the part of the litter mixed within the soil below the surface. 'Content' indicates a quantity per unit area. The sum of the quantities with standard names surface_litter_mass_content_of_carbon and subsurface_litter_mass_content_of_carbon has the standard name litter_mass_content_of_carbon.", "dimensions":"longitude latitude time", "frequency":"mon", "long_name":"Carbon Mass in Below-Ground Litter", @@ -162,7 +162,7 @@ "ok_min_mean_abs":"", "out_name":"cLitterBelow", "positive":"", - "standard_name":"subsurface_litter_carbon_content", + "standard_name":"subsurface_litter_mass_content_of_carbon", "type":"real", "units":"kg m-2", "valid_max":"", @@ -174,12 +174,12 @@ "comment":"Carbon mass per unit area in that has been removed from the environment through land use change.", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Carbon Mass in Products of Land Use Change", + "long_name":"Carbon Mass in Products of Land-Use Change", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"cProduct", "positive":"", - "standard_name":"carbon_content_of_products_of_anthropogenic_land_use_change", + "standard_name":"carbon_mass_content_of_forestry_and_agricultural_products", "type":"real", "units":"kg m-2", "valid_max":"", @@ -196,7 +196,7 @@ "ok_min_mean_abs":"", "out_name":"cRoot", "positive":"", - "standard_name":"root_carbon_content", + "standard_name":"root_mass_content_of_carbon", "type":"real", "units":"kg m-2", "valid_max":"", @@ -213,7 +213,7 @@ "ok_min_mean_abs":"", "out_name":"cSoilFast", "positive":"", - "standard_name":"fast_soil_pool_carbon_content", + "standard_name":"fast_soil_pool_mass_content_of_carbon", "type":"real", "units":"kg m-2", "valid_max":"", @@ -230,7 +230,7 @@ "ok_min_mean_abs":"", "out_name":"cSoilMedium", "positive":"", - "standard_name":"medium_soil_pool_carbon_content", + "standard_name":"medium_soil_pool_mass_content_of_carbon", "type":"real", "units":"kg m-2", "valid_max":"", @@ -247,7 +247,7 @@ "ok_min_mean_abs":"", "out_name":"cSoilSlow", "positive":"", - "standard_name":"slow_soil_pool_carbon_content", + "standard_name":"slow_soil_pool_mass_content_of_carbon", "type":"real", "units":"kg m-2", "valid_max":"", @@ -276,7 +276,7 @@ "comment":"Percentage of entire grid cell that is covered by crop.", "dimensions":"longitude latitude time typecrop", "frequency":"mon", - "long_name":"Crop Fraction", + "long_name":"Percentage Crop Cover", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"cropFrac", @@ -327,7 +327,7 @@ "comment":"CO2 emissions (expressed as a carbon mass flux per unit area) from natural fires and human ignition fires as calculated by the fire module of the dynamic vegetation model, but excluding any CO2 flux from fire included in fLuc (CO2 Flux to Atmosphere from Land Use Change).", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Carbon Mass Flux into Atmosphere due to CO2 Emission from Fire", + "long_name":"Carbon Mass Flux into Atmosphere Due to CO2 Emission from Fire Excluding Land-Use Change", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"fFire", @@ -344,7 +344,7 @@ "comment":"Carbon mass flux per unit area due to grazing on land", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Carbon Mass Flux into Atmosphere due to Grazing on Land", + "long_name":"Carbon Mass Flux into Atmosphere Due to Grazing on Land", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"fGrazing", @@ -361,7 +361,7 @@ "comment":"Carbon mass flux per unit area due to crop harvesting", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Carbon Mass Flux into Atmosphere due to Crop Harvesting", + "long_name":"Carbon Mass Flux into Atmosphere Due to Crop Harvesting", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"fHarvest", @@ -392,7 +392,7 @@ "fVegLitter":{ "cell_measures":"", "cell_methods":"area: mean where land time: mean", - "comment":"", + "comment":"In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. 'Vegetation' means any living plants e.g. trees, shrubs, grass. 'Litter' is dead plant material in or above the soil. It is distinct from coarse wood debris. The precise distinction between 'fine' and 'coarse' is model dependent. The sum of the quantities with standard names mass_flux_of_carbon_into_litter_from_vegetation_due_to_mortality and mass_flux_of_carbon_into_litter_from_vegetation_due_to_senescence is mass_flux_of_carbon_into_litter_from_vegetation.", "dimensions":"longitude latitude time", "frequency":"mon", "long_name":"Total Carbon Mass Flux from Vegetation to Litter", @@ -400,7 +400,7 @@ "ok_min_mean_abs":"", "out_name":"fVegLitter", "positive":"", - "standard_name":"litter_carbon_flux", + "standard_name":"mass_flux_of_carbon_into_litter_from_vegetation", "type":"real", "units":"kg m-2 s-1", "valid_max":"", @@ -443,10 +443,10 @@ "gpp":{ "cell_measures":"", "cell_methods":"area: mean where land time: mean", - "comment":"", + "comment":"The rate of synthesis of biomass from inorganic precursors by autotrophs ('producers') expressed as the mass of carbon which it contains. For example, photosynthesis in plants or phytoplankton. The producers also respire some of this biomass and the difference is referred to as the net primary production. ", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Carbon Mass Flux out of Atmosphere due to Gross Primary Production on Land", + "long_name":"Carbon Mass Flux out of Atmosphere Due to Gross Primary Production on Land", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"gpp", @@ -460,10 +460,10 @@ "grassFrac":{ "cell_measures":"", "cell_methods":"area: mean where land over all_area_types time: mean", - "comment":"Percentage of entire grid cell that is covered by natural grass.", + "comment":"Fraction of entire grid cell that is covered by natural grass.", "dimensions":"longitude latitude time typenatgr", "frequency":"mon", - "long_name":"Natural Grass Fraction", + "long_name":"Natural Grass Area Percentage", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"grassFrac", @@ -477,7 +477,7 @@ "lai":{ "cell_measures":"", "cell_methods":"area: mean where land time: mean", - "comment":"", + "comment":"A ratio obtained by dividing the total upper leaf surface area of vegetation by the (horizontal) surface area of the land on which it grows.", "dimensions":"longitude latitude time", "frequency":"mon", "long_name":"Leaf Area Index", @@ -494,10 +494,10 @@ "landCoverFrac":{ "cell_measures":"", "cell_methods":"area: mean where land over all_area_types time: mean", - "comment":"Percentage of grid cell area occupied by different model vegetation/land cover categories. The categories may differ from model to model, depending on each model's subgrid land cover category definitions. Categories may include natural vegetation, anthropogenic vegetation, bare soil, lakes, urban areas, glaciers, etc. Sum of all should equal the fraction of the grid-cell that is land.", + "comment":"Percentage of grid cell area occupied by different model vegetation/land cover categories. The categories may differ from model to model, depending on each model's subgrid land cover category definitions. Categories may include natural vegetation, anthropogenic vegetation, bare soil, lakes, urban areas, glaciers, etc. Sum of all should equal the percentage of the grid cell that is land.", "dimensions":"longitude latitude vegtype time", "frequency":"mon", - "long_name":"Plant Functional Type Grid Fraction", + "long_name":"Percentage of Area by Vegetation or Land-Cover Category", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"landCoverFrac", @@ -570,7 +570,7 @@ "ok_min_mean_abs":"", "out_name":"mrso", "positive":"", - "standard_name":"soil_moisture_content", + "standard_name":"mass_content_of_water_in_soil", "type":"real", "units":"kg m-2", "valid_max":"", @@ -587,7 +587,7 @@ "ok_min_mean_abs":"", "out_name":"mrsos", "positive":"", - "standard_name":"moisture_content_of_soil_layer", + "standard_name":"mass_content_of_water_in_soil_layer", "type":"real", "units":"kg m-2", "valid_max":"", @@ -599,7 +599,7 @@ "comment":"This is the net mass flux of carbon from atmosphere into land, calculated as photosynthesis MINUS the sum of plant and soil respiration, carbon fluxes from fire, harvest, grazing and land use change. Positive flux is into the land.", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Carbon Mass Flux out of Atmosphere due to Net Biospheric Production on Land", + "long_name":"Carbon Mass Flux out of Atmosphere Due to Net Biospheric Production on Land", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"nbp", @@ -630,10 +630,10 @@ "npp":{ "cell_measures":"", "cell_methods":"area: mean where land time: mean", - "comment":"", + "comment":"'Production of carbon' means the production of biomass expressed as the mass of carbon which it contains. Net primary production is the excess of gross primary production (rate of synthesis of biomass from inorganic precursors) by autotrophs ('producers'), for example, photosynthesis in plants or phytoplankton, over the rate at which the autotrophs themselves respire some of this biomass. 'Productivity' means production per unit area. The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A.", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Carbon Mass Flux out of Atmosphere due to Net Primary Production on Land", + "long_name":"Carbon Mass Flux out of Atmosphere Due to Net Primary Production on Land", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"npp", @@ -650,12 +650,12 @@ "comment":"This is the rate of carbon uptake by leaves due to NPP", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Carbon Mass Flux due to NPP Allocation to Leaf", + "long_name":"Carbon Mass Flux Due to NPP Allocation to Leaf", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"nppLeaf", "positive":"down", - "standard_name":"net_primary_productivity_of_carbon_accumulated_in_leaves", + "standard_name":"net_primary_productivity_of_biomass_expressed_as_carbon_accumulated_in_leaves", "type":"real", "units":"kg m-2 s-1", "valid_max":"", @@ -667,12 +667,12 @@ "comment":"This is the rate of carbon uptake by roots due to NPP", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Carbon Mass Flux due to NPP Allocation to Roots", + "long_name":"Carbon Mass Flux Due to NPP Allocation to Roots", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"nppRoot", "positive":"down", - "standard_name":"net_primary_productivity_of_carbon_accumulated_in_roots", + "standard_name":"net_primary_productivity_of_biomass_expressed_as_carbon_accumulated_in_roots", "type":"real", "units":"kg m-2 s-1", "valid_max":"", @@ -684,12 +684,12 @@ "comment":"This is the rate of carbon uptake by wood due to NPP", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Carbon Mass Flux due to NPP Allocation to Wood", + "long_name":"Carbon Mass Flux Due to NPP Allocation to Wood", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"nppWood", "positive":"down", - "standard_name":"net_primary_productivity_of_carbon_accumulated_in_wood", + "standard_name":"net_primary_productivity_of_biomass_expressed_as_carbon_accumulated_in_wood", "type":"real", "units":"kg m-2 s-1", "valid_max":"", @@ -701,7 +701,7 @@ "comment":"Percentage of entire grid cell that is covered by anthropogenic pasture.", "dimensions":"longitude latitude time typepasture", "frequency":"mon", - "long_name":"Anthropogenic Pasture Fraction", + "long_name":"Percentage of Land Which Is Anthropogenic Pasture", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"pastureFrac", @@ -732,15 +732,15 @@ "rGrowth":{ "cell_measures":"", "cell_methods":"area: mean where land time: mean", - "comment":"", + "comment":"Growth respiration is defined as the additional carbon cost for the synthesis of new growth.", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Carbon Mass Flux into Atmosphere due to Growth Autotrophic Respiration on Land", + "long_name":"Carbon Mass Flux into Atmosphere Due to Growth Autotrophic Respiration on Land", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"rGrowth", "positive":"up", - "standard_name":"surface_upward_carbon_mass_flux_due_to_plant_respiration_for_biomass_growth", + "standard_name":"surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_for_biomass_growth", "type":"real", "units":"kg m-2 s-1", "valid_max":"", @@ -749,15 +749,15 @@ "rMaint":{ "cell_measures":"", "cell_methods":"area: mean where land time: mean", - "comment":"", + "comment":"Maintenance respiration is defined as the carbon cost to support the metabolic activity of existing live tissue.", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Carbon Mass Flux into Atmosphere due to Maintenance Autotrophic Respiration on Land", + "long_name":"Carbon Mass Flux into Atmosphere Due to Maintenance Autotrophic Respiration on Land", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"rMaint", "positive":"up", - "standard_name":"surface_upward_carbon_mass_flux_due_to_plant_respiration_for_biomass_maintenance", + "standard_name":"surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration_for_biomass_maintenance", "type":"real", "units":"kg m-2 s-1", "valid_max":"", @@ -769,12 +769,12 @@ "comment":"Carbon mass flux per unit area into atmosphere due to autotrophic respiration on land (respiration by producers) [see rh for heterotrophic production]", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Carbon Mass Flux into Atmosphere due to Autotrophic (Plant) Respiration on Land", + "long_name":"Carbon Mass Flux into Atmosphere Due to Autotrophic (Plant) Respiration on Land", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"ra", "positive":"up", - "standard_name":"plant_respiration_carbon_flux", + "standard_name":"surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_plant_respiration", "type":"real", "units":"kg m-2 s-1", "valid_max":"", @@ -786,7 +786,7 @@ "comment":"Percentage of entire grid cell that is land and is covered by neither vegetation nor bare-soil (e.g., urban, ice, lakes, etc.)", "dimensions":"longitude latitude time typeresidual", "frequency":"mon", - "long_name":"Fraction of Grid Cell that is Land but Neither Vegetation-Covered nor Bare Soil", + "long_name":"Percentage of Grid Cell That Is Land but neither Vegetation Covered nor Bare Soil", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"residualFrac", @@ -803,12 +803,12 @@ "comment":"Carbon mass flux per unit area into atmosphere due to heterotrophic respiration on land (respiration by consumers)", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Carbon Mass Flux into Atmosphere due to Heterotrophic Respiration on Land", + "long_name":"Carbon Mass Flux into Atmosphere Due to Heterotrophic Respiration on Land", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"rh", "positive":"up", - "standard_name":"heterotrophic_respiration_carbon_flux", + "standard_name":"surface_upward_mass_flux_of_carbon_dioxide_expressed_as_carbon_due_to_heterotrophic_respiration", "type":"real", "units":"kg m-2 s-1", "valid_max":"", @@ -820,7 +820,7 @@ "comment":"Percentage of entire grid cell that is covered by shrub.", "dimensions":"longitude latitude time typeshrub", "frequency":"mon", - "long_name":"Shrub Fraction", + "long_name":"Percentage Cover by Shrub", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"shrubFrac", @@ -854,7 +854,7 @@ "comment":"Percentage of entire grid cell that is covered by trees.", "dimensions":"longitude latitude time typetree", "frequency":"mon", - "long_name":"Tree Cover Fraction", + "long_name":"Tree Cover Percentage", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"treeFrac", @@ -871,7 +871,7 @@ "comment":"Percentage of the entire grid cell that is covered by total primary deciduous trees.", "dimensions":"longitude latitude time typepdec", "frequency":"mon", - "long_name":"Total Primary Deciduous Tree Fraction", + "long_name":"Percentage Cover by Primary Deciduous Tree", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"treeFracPrimDec", @@ -888,7 +888,7 @@ "comment":"Percentage of entire grid cell that is covered by primary evergreen trees.", "dimensions":"longitude latitude time typepever", "frequency":"mon", - "long_name":"Total Primary Evergreen Tree Cover Fraction", + "long_name":"Percentage Cover by Primary Evergreen Trees", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"treeFracPrimEver", @@ -905,7 +905,7 @@ "comment":"Percentage of entire grid cell that is covered by secondary deciduous trees.", "dimensions":"longitude latitude time typesdec", "frequency":"mon", - "long_name":"Total Secondary Deciduous Tree Cover Fraction", + "long_name":"Percentage Cover by Secondary Deciduous Trees", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"treeFracSecDec", @@ -922,7 +922,7 @@ "comment":"Percentage of entire grid cell that is covered by secondary evergreen trees.", "dimensions":"longitude latitude time typesever", "frequency":"mon", - "long_name":"Total Secondary Evergreen Tree Cover Fraction", + "long_name":"Percentage Cover by Secondary Evergreen Trees", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"treeFracSecEver", diff --git a/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_Omon.json b/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_Omon.json index 2c5306fcb9..80f3e9e034 100644 --- a/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_Omon.json +++ b/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_Omon.json @@ -1,17 +1,17 @@ { "Header":{ - "#dataRequest_specs_version":"01.00.21", + "#dataRequest_specs_version":"01.00.29", "#mip_era":"CMIP6", "Conventions":"CF-1.7 ODS-2.1", "approx_interval":"30.00000", - "cmor_version":"3.2", + "cmor_version":"3.4", "data_specs_version":"2.1.0", "generic_levels":"olevel", "int_missing_value":"-2147483648", "missing_value":"1e20", "product":"observations", "realm":"ocean", - "table_date":"07 March 2018", + "table_date":"11 April 2019", "table_id":"Table obs4MIPs_Omon" }, "variable_entry":{ @@ -49,6 +49,23 @@ "valid_max":"", "valid_min":"" }, + "aragos":{ + "cell_measures":"", + "cell_methods":"area: mean where sea time: mean", + "comment":"sum of particulate aragonite components (e.g. Phytoplankton, Detrital, etc.)", + "dimensions":"longitude latitude time", + "frequency":"mon", + "long_name":"Surface Aragonite Concentration", + "ok_max_mean_abs":"", + "ok_min_mean_abs":"", + "out_name":"aragos", + "positive":"", + "standard_name":"mole_concentration_of_aragonite_expressed_as_carbon_in_sea_water", + "type":"real", + "units":"mol m-3", + "valid_max":"", + "valid_min":"" + }, "bacc":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", @@ -66,6 +83,23 @@ "valid_max":"", "valid_min":"" }, + "baccos":{ + "cell_measures":"", + "cell_methods":"area: mean where sea time: mean", + "comment":"Sum of bacterial carbon component concentrations", + "dimensions":"longitude latitude time", + "frequency":"mon", + "long_name":"Surface Bacterial Carbon Concentration", + "ok_max_mean_abs":"", + "ok_min_mean_abs":"", + "out_name":"baccos", + "positive":"", + "standard_name":"mole_concentration_of_bacteria_expressed_as_carbon_in_sea_water", + "type":"real", + "units":"mol m-3", + "valid_max":"", + "valid_min":"" + }, "bfe":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", @@ -87,9 +121,9 @@ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", "comment":"sum of particulate organic iron component concentrations", - "dimensions":"longitude latitude time depth0m", + "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Surface Mole Concentration of Particulate Organic Matter expressed as Iron in sea water", + "long_name":"Surface Mole Concentration of Particulate Organic Matter Expressed as Iron in Sea Water", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"bfeos", @@ -106,7 +140,7 @@ "comment":"Sea water conservative temperature (this should be contributed only for models using conservative temperature as prognostic field)", "dimensions":"longitude latitude olevel time", "frequency":"mon", - "long_name":"Sea Water Convervative Temperature", + "long_name":"Sea Water Conservative Temperature", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"bigthetao", @@ -140,7 +174,7 @@ "comment":"Sum of particulate silica component concentrations", "dimensions":"longitude latitude olevel time", "frequency":"mon", - "long_name":"Mole Concentration of Particulate Organic Matter expressed as silicon in sea water", + "long_name":"Mole Concentration of Particulate Organic Matter Expressed as Silicon in sea water", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"bsi", @@ -155,9 +189,9 @@ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", "comment":"sum of particulate silica component concentrations", - "dimensions":"longitude latitude time depth0m", + "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Surface Mole Concentration of Particulate Organic Matter expressed as Silicon in sea water", + "long_name":"Surface Mole Concentration of Particulate Organic Matter Expressed as Silicon in Sea Water", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"bsios", @@ -185,13 +219,30 @@ "valid_max":"", "valid_min":"" }, + "calcos":{ + "cell_measures":"", + "cell_methods":"area: mean where sea time: mean", + "comment":"sum of particulate calcite component concentrations (e.g. Phytoplankton, Detrital, etc.)", + "dimensions":"longitude latitude time", + "frequency":"mon", + "long_name":"Surface Calcite Concentration", + "ok_max_mean_abs":"", + "ok_min_mean_abs":"", + "out_name":"calcos", + "positive":"", + "standard_name":"mole_concentration_of_calcite_expressed_as_carbon_in_sea_water", + "type":"real", + "units":"mol m-3", + "valid_max":"", + "valid_min":"" + }, "cfc11":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"Mole concentration means number of moles per unit volume, also called 'molarity', and is used in the construction 'mole_concentration_of_X_in_Y', where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula of CFC11 is CFCl3. The IUPAC name for CFC11 is trichloro-fluoro-methane.", "dimensions":"longitude latitude olevel time", "frequency":"mon", - "long_name":"Moles Per Unit Mass of CFC-11 in sea water", + "long_name":"Mole Concentration of CFC11 in Sea Water", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"cfc11", @@ -205,10 +256,10 @@ "cfc12":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"Mole concentration means number of moles per unit volume, also called 'molarity', and is used in the construction 'mole_concentration_of_X_in_Y', where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula for CFC12 is CF2Cl2. The IUPAC name for CFC12 is dichloro-difluoro-methane.", "dimensions":"longitude latitude olevel time", "frequency":"mon", - "long_name":"Moles Per Unit Mass of CFC-12 in sea water", + "long_name":"Mole Concentration of CFC12 in Sea water", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"cfc12", @@ -225,7 +276,7 @@ "comment":"Sum of chlorophyll from all phytoplankton group concentrations. In most models this is equal to chldiat+chlmisc, that is the sum of Diatom Chlorophyll Mass Concentration and Other Phytoplankton Chlorophyll Mass Concentration", "dimensions":"longitude latitude olevel time", "frequency":"mon", - "long_name":"Mass Concentration of Total Chlorophyll in sea water", + "long_name":"Mass Concentration of Total Phytoplankton expressed as Chlorophyll in Sea Water", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"chl", @@ -242,7 +293,7 @@ "comment":"chlorophyll concentration from the calcite-producing phytoplankton component alone", "dimensions":"longitude latitude olevel time", "frequency":"mon", - "long_name":"Mass Concentration of Calcareous Phytoplankton expressed as Chlorophyll in sea water", + "long_name":"Mass Concentration of Calcareous Phytoplankton Expressed as Chlorophyll in Sea Water", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"chlcalc", @@ -257,9 +308,9 @@ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", "comment":"chlorophyll concentration from the calcite-producing phytoplankton component alone", - "dimensions":"longitude latitude time depth0m", + "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Surface Mass Concentration of Calcareous Phytoplankton expressed as Chlorophyll in sea water", + "long_name":"Surface Mass Concentration of Calcareous Phytoplankton Expressed as Chlorophyll in Sea Water", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"chlcalcos", @@ -276,7 +327,7 @@ "comment":"Chlorophyll from diatom phytoplankton component concentration alone", "dimensions":"longitude latitude olevel time", "frequency":"mon", - "long_name":"Mass Concentration of Diatom expressed as Chlorophyll in sea water", + "long_name":"Mass Concentration of Diatoms expressed as Chlorophyll in Sea Water", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"chldiat", @@ -291,9 +342,9 @@ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", "comment":"chlorophyll from diatom phytoplankton component concentration alone", - "dimensions":"longitude latitude time depth0m", + "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Surface Mass Concentration of Diatoms expressed as Chlorophyll in sea water", + "long_name":"Surface Mass Concentration of Diatoms Expressed as Chlorophyll in Sea Water", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"chldiatos", @@ -310,7 +361,7 @@ "comment":"Chlorophyll concentration from the diazotrophic phytoplankton component alone", "dimensions":"longitude latitude olevel time", "frequency":"mon", - "long_name":"Mass Concentration of Diazotrophs expressed as Chlorophyll in sea water", + "long_name":"Mass Concentration of Diazotrophs Expressed as Chlorophyll in Sea Water", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"chldiaz", @@ -325,9 +376,9 @@ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", "comment":"chlorophyll concentration from the diazotrophic phytoplankton component alone", - "dimensions":"longitude latitude time depth0m", + "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Surface Mass Concentration of Diazotrophs expressed as Chlorophyll in sea water", + "long_name":"Surface Mass Concentration of Diazotrophs Expressed as Chlorophyll in Sea Water", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"chldiazos", @@ -344,7 +395,7 @@ "comment":"Chlorophyll from additional phytoplankton component concentrations alone", "dimensions":"longitude latitude olevel time", "frequency":"mon", - "long_name":"Mass Concentration of Other Phytoplankton expressed as Chlorophyll in sea water", + "long_name":"Mass Concentration of Other Phytoplankton expressed as Chlorophyll in Sea Water", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"chlmisc", @@ -359,9 +410,9 @@ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", "comment":"chlorophyll from additional phytoplankton component concentrations alone", - "dimensions":"longitude latitude time depth0m", + "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Surface Mass Concentration of Other Phytoplankton expressed as Chlorophyll in sea water", + "long_name":"Surface Mass Concentration of Other Phytoplankton Expressed as Chlorophyll in Sea Water", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"chlmiscos", @@ -376,9 +427,9 @@ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", "comment":"Sum of chlorophyll from all phytoplankton group concentrations at the sea surface. In most models this is equal to chldiat+chlmisc, that is the sum of 'Diatom Chlorophyll Mass Concentration' plus 'Other Phytoplankton Chlorophyll Mass Concentration'", - "dimensions":"longitude latitude time depth0m", + "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Surface Mass Concentration of Total Phytoplankton expressed as Chlorophyll in sea water", + "long_name":"Surface Mass Concentration of Total Phytoplankton expressed as Chlorophyll in Sea Water", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"chlos", @@ -395,7 +446,7 @@ "comment":"chlorophyll concentration from the picophytoplankton (<2 um) component alone", "dimensions":"longitude latitude olevel time", "frequency":"mon", - "long_name":"Mass Concentration of Picophytoplankton expressed as Chlorophyll in sea water", + "long_name":"Mass Concentration of Picophytoplankton Expressed as Chlorophyll in Sea Water", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"chlpico", @@ -410,9 +461,9 @@ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", "comment":"chlorophyll concentration from the picophytoplankton (<2 um) component alone", - "dimensions":"longitude latitude time depth0m", + "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Surface Mass Concentration of Picophytoplankton expressed as Chlorophyll in sea water", + "long_name":"Surface Mass Concentration of Picophytoplankton Expressed as Chlorophyll in Sea Water", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"chlpicoos", @@ -426,10 +477,10 @@ "co3":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"Mole concentration (number of moles per unit volume: molarity) of the carbonate anion (CO3).", "dimensions":"longitude latitude olevel time", "frequency":"mon", - "long_name":"Carbonate ion Concentration", + "long_name":"Carbonate Ion Concentration", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"co3", @@ -443,10 +494,10 @@ "co3abio":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"Mole concentration (number of moles per unit volume: molarity) of the abiotic-analogue carbonate anion (CO3). An abiotic analogue is used to simulate the effect on a modelled variable when biological effects on ocean carbon concentration and alkalinity are ignored. ", "dimensions":"longitude latitude olevel time", "frequency":"mon", - "long_name":"Abiotic Carbonate ion Concentration", + "long_name":"Abiotic Carbonate Ion Concentration", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"co3abio", @@ -457,13 +508,30 @@ "valid_max":"", "valid_min":"" }, + "co3abioos":{ + "cell_measures":"", + "cell_methods":"area: mean where sea time: mean", + "comment":"Near surface mole concentration (number of moles per unit volume: molarity) of the abiotic-analogue carbonate anion (CO3). An abiotic analogue is used to simulate the effect on a modelled variable when biological effects on ocean carbon concentration and alkalinity are ignored. ", + "dimensions":"longitude latitude time", + "frequency":"mon", + "long_name":"Surface Abiotic Carbonate Ion Concentration", + "ok_max_mean_abs":"", + "ok_min_mean_abs":"", + "out_name":"co3abioos", + "positive":"", + "standard_name":"mole_concentration_of_carbonate_abiotic_analogue_expressed_as_carbon_in_sea_water", + "type":"real", + "units":"mol m-3", + "valid_max":"", + "valid_min":"" + }, "co3nat":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"Surface mole concentration (number of moles per unit volume: molarity) of the natural-analogue carbonate anion (CO3). A natural analogue is used to simulate the effect on a modelled variable of imposing preindustrial atmospheric carbon dioxide concentrations, even when the model as a whole may be subjected to varying forcings. ", "dimensions":"longitude latitude olevel time", "frequency":"mon", - "long_name":"Natural Carbonate ion Concentration", + "long_name":"Natural Carbonate Ion Concentration", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"co3nat", @@ -474,13 +542,47 @@ "valid_max":"", "valid_min":"" }, + "co3natos":{ + "cell_measures":"", + "cell_methods":"area: mean where sea time: mean", + "comment":"Near surface mole concentration (number of moles per unit volume: molarity) of the natural-analogue carbonate anion (CO3). A natural analogue is used to simulate the effect on a modelled variable of imposing preindustrial atmospheric carbon dioxide concentrations, even when the model as a whole may be subjected to varying forcings. ", + "dimensions":"longitude latitude time", + "frequency":"mon", + "long_name":"Surface Natural Carbonate Ion Concentration", + "ok_max_mean_abs":"", + "ok_min_mean_abs":"", + "out_name":"co3natos", + "positive":"", + "standard_name":"mole_concentration_of_carbonate_natural_analogue_expressed_as_carbon_in_sea_water", + "type":"real", + "units":"mol m-3", + "valid_max":"", + "valid_min":"" + }, + "co3os":{ + "cell_measures":"", + "cell_methods":"area: mean where sea time: mean", + "comment":"Near surface mole concentration (number of moles per unit volume: molarity) of the carbonate anion (CO3).", + "dimensions":"longitude latitude time", + "frequency":"mon", + "long_name":"Surface Carbonate Ion Concentration", + "ok_max_mean_abs":"", + "ok_min_mean_abs":"", + "out_name":"co3os", + "positive":"", + "standard_name":"mole_concentration_of_carbonate_expressed_as_carbon_in_sea_water", + "type":"real", + "units":"mol m-3", + "valid_max":"", + "valid_min":"" + }, "co3satarag":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"Mole concentration (number of moles per unit volume: molarity) of the carbonate anion (CO3) for sea water in equilibrium with pure Aragonite. Aragonite (CaCO3) is a mineral that is a polymorph of calcium carbonate.", "dimensions":"longitude latitude olevel time", "frequency":"mon", - "long_name":"Carbonate ion Concentration for sea water in equilibrium with pure Aragonite", + "long_name":"Mole Concentration of Carbonate Ion in Equilibrium with Pure Aragonite in Sea Water", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"co3satarag", @@ -491,13 +593,30 @@ "valid_max":"", "valid_min":"" }, + "co3sataragos":{ + "cell_measures":"", + "cell_methods":"area: mean where sea time: mean", + "comment":"Near surface mole concentration (number of moles per unit volume: molarity) of the carbonate anion (CO3) for sea water in equilibrium with pure Aragonite. Aragonite (CaCO3) is a mineral that is a polymorph of calcium carbonate.", + "dimensions":"longitude latitude time", + "frequency":"mon", + "long_name":"Surface Mole Concentration of Carbonate Ion in Equilibrium with Pure Aragonite in Sea Water", + "ok_max_mean_abs":"", + "ok_min_mean_abs":"", + "out_name":"co3sataragos", + "positive":"", + "standard_name":"mole_concentration_of_carbonate_expressed_as_carbon_at_equilibrium_with_pure_aragonite_in_sea_water", + "type":"real", + "units":"mol m-3", + "valid_max":"", + "valid_min":"" + }, "co3satcalc":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"Mole concentration (number of moles per unit volume: molarity) of the carbonate anion (CO3) for sea water in equilibrium with pure calcite. Aragonite (CaCO3) is a mineral that is a polymorph of calcium carbonate.", "dimensions":"longitude latitude olevel time", "frequency":"mon", - "long_name":"Carbonate ion Concentration for sea water in equilibrium with pure Calcite", + "long_name":"Mole Concentration of Carbonate Ion in Equilibrium with Pure Calcite in Sea Water", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"co3satcalc", @@ -508,6 +627,23 @@ "valid_max":"", "valid_min":"" }, + "co3satcalcos":{ + "cell_measures":"", + "cell_methods":"area: mean where sea time: mean", + "comment":"Near surface mole concentration (number of moles per unit volume: molarity) of the carbonate anion (CO3) for sea water in equilibrium with pure calcite. Aragonite (CaCO3) is a mineral that is a polymorph of calcium carbonate.", + "dimensions":"longitude latitude time", + "frequency":"mon", + "long_name":"Surface Mole Concentration of Carbonate Ion in Equilibrium with Pure Calcite in Sea Water", + "ok_max_mean_abs":"", + "ok_min_mean_abs":"", + "out_name":"co3satcalcos", + "positive":"", + "standard_name":"mole_concentration_of_carbonate_expressed_as_carbon_at_equilibrium_with_pure_calcite_in_sea_water", + "type":"real", + "units":"mol m-3", + "valid_max":"", + "valid_min":"" + }, "detoc":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", @@ -525,13 +661,30 @@ "valid_max":"", "valid_min":"" }, + "detocos":{ + "cell_measures":"", + "cell_methods":"area: mean where sea time: mean", + "comment":"sum of detrital organic carbon component concentrations", + "dimensions":"longitude latitude time", + "frequency":"mon", + "long_name":"Surface Detrital Organic Carbon Concentration", + "ok_max_mean_abs":"", + "ok_min_mean_abs":"", + "out_name":"detocos", + "positive":"", + "standard_name":"mole_concentration_of_organic_detritus_expressed_as_carbon_in_sea_water", + "type":"real", + "units":"mol m-3", + "valid_max":"", + "valid_min":"" + }, "dfe":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", "comment":"Dissolved iron in sea water, including both Fe2+ and Fe3+ ions (but not particulate detrital iron)", "dimensions":"longitude latitude olevel time", "frequency":"mon", - "long_name":"Mole Concentration of Dissolved Iron in sea water", + "long_name":"Dissolved Iron Concentration", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"dfe", @@ -546,7 +699,7 @@ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", "comment":"dissolved iron in sea water is meant to include both Fe2+ and Fe3+ ions (but not, e.g., particulate detrital iron)", - "dimensions":"longitude latitude time depth0m", + "dimensions":"longitude latitude time", "frequency":"mon", "long_name":"Surface Dissolved Iron Concentration", "ok_max_mean_abs":"", @@ -562,15 +715,15 @@ "dissi13c":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"Dissolved inorganic 14carbon (CO3+HCO3+H2CO3) concentration", + "comment":"Dissolved inorganic carbon-13 (CO3+HCO3+H2CO3) concentration", "dimensions":"longitude latitude olevel time", "frequency":"mon", - "long_name":"Dissolved Inorganic 13Carbon Concentration", + "long_name":"Dissolved Inorganic Carbon-13 Concentration", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"dissi13c", "positive":"", - "standard_name":"mole_concentration_of_dissolved_inorganic_carbon13_in_sea_water", + "standard_name":"mole_concentration_of_dissolved_inorganic_13C_in_sea_water", "type":"real", "units":"mol m-3", "valid_max":"", @@ -579,15 +732,15 @@ "dissi13cos":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"Dissolved inorganic 14carbon (CO3+HCO3+H2CO3) concentration", - "dimensions":"longitude latitude time depth0m", + "comment":"Near surface dissolved inorganic carbon-13 (CO3+HCO3+H2CO3) concentration", + "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Surface Dissolved Inorganic 13Carbon Concentration", + "long_name":"Surface Dissolved Inorganic Carbon-13 Concentration", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"dissi13cos", "positive":"", - "standard_name":"mole_concentration_of_dissolved_inorganic_carbon13_in_sea_water", + "standard_name":"mole_concentration_of_dissolved_inorganic_13C_in_sea_water", "type":"real", "units":"mol m-3", "valid_max":"", @@ -596,15 +749,15 @@ "dissi14cabio":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"Abiotic Dissolved inorganic 14carbon (CO3+HCO3+H2CO3) concentration", + "comment":"Abiotic Dissolved inorganic carbon-14 (CO3+HCO3+H2CO3) concentration", "dimensions":"longitude latitude olevel time", "frequency":"mon", - "long_name":"Abiotic Dissolved Inorganic 14Carbon Concentration", + "long_name":"Abiotic Dissolved Inorganic Carbon-14 Concentration", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"dissi14cabio", "positive":"", - "standard_name":"mole_concentration_of_dissolved_inorganic_carbon14_in_sea_water", + "standard_name":"mole_concentration_of_dissolved_inorganic_14C_in_sea_water", "type":"real", "units":"mol m-3", "valid_max":"", @@ -613,15 +766,15 @@ "dissi14cabioos":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"Abiotic Dissolved inorganic 14carbon (CO3+HCO3+H2CO3) concentration", - "dimensions":"longitude latitude time depth0m", + "comment":"Abiotic Dissolved inorganic carbon-14 (CO3+HCO3+H2CO3) concentration", + "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Surface Abiotic Dissolved Inorganic 14Carbon Concentration", + "long_name":"Surface Abiotic Dissolved Inorganic Carbon-14 Concentration", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"dissi14cabioos", "positive":"", - "standard_name":"mole_concentration_of_dissolved_inorganic_carbon14_in_sea_water", + "standard_name":"mole_concentration_of_dissolved_inorganic_14C_in_sea_water", "type":"real", "units":"mol m-3", "valid_max":"", @@ -665,7 +818,7 @@ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", "comment":"Abiotic Dissolved inorganic carbon (CO3+HCO3+H2CO3) concentration", - "dimensions":"longitude latitude time depth0m", + "dimensions":"longitude latitude time", "frequency":"mon", "long_name":"Surface Abiotic Dissolved Inorganic Carbon Concentration", "ok_max_mean_abs":"", @@ -699,7 +852,7 @@ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", "comment":"Dissolved inorganic carbon (CO3+HCO3+H2CO3) concentration at preindustrial atmospheric xCO2", - "dimensions":"longitude latitude time depth0m", + "dimensions":"longitude latitude time", "frequency":"mon", "long_name":"Surface Natural Dissolved Inorganic Carbon Concentration", "ok_max_mean_abs":"", @@ -712,6 +865,23 @@ "valid_max":"", "valid_min":"" }, + "dissicos":{ + "cell_measures":"", + "cell_methods":"area: mean where sea time: mean", + "comment":"Dissolved inorganic carbon (CO3+HCO3+H2CO3) concentration", + "dimensions":"longitude latitude time", + "frequency":"mon", + "long_name":"Surface Dissolved Inorganic Carbon Concentration", + "ok_max_mean_abs":"", + "ok_min_mean_abs":"", + "out_name":"dissicos", + "positive":"", + "standard_name":"mole_concentration_of_dissolved_inorganic_carbon_in_sea_water", + "type":"real", + "units":"mol m-3", + "valid_max":"", + "valid_min":"" + }, "dissoc":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", @@ -729,13 +899,30 @@ "valid_max":"", "valid_min":"" }, + "dissocos":{ + "cell_measures":"", + "cell_methods":"area: mean where sea time: mean", + "comment":"Sum of dissolved carbon component concentrations explicitly represented (i.e. not ~40 uM refractory unless explicit)", + "dimensions":"longitude latitude time", + "frequency":"mon", + "long_name":"Surface Dissolved Organic Carbon Concentration", + "ok_max_mean_abs":"", + "ok_min_mean_abs":"", + "out_name":"dissocos", + "positive":"", + "standard_name":"mole_concentration_of_dissolved_organic_carbon_in_sea_water", + "type":"real", + "units":"mol m-3", + "valid_max":"", + "valid_min":"" + }, "dmso":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", "comment":"Mole concentration of dimethyl sulphide in water", "dimensions":"longitude latitude olevel time", "frequency":"mon", - "long_name":"Mole Concentration of Dimethyl Sulphide in sea water", + "long_name":"Mole Concentration of Dimethyl Sulphide in Sea Water", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"dmso", @@ -749,10 +936,10 @@ "dmsos":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", - "dimensions":"longitude latitude time depth0m", + "comment":"Mole concentration of dimethyl sulphide in water in the near surface layer", + "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Surface Mole Concentration of Dimethyl Sulphide in sea water", + "long_name":"Surface Mole Concentration of Dimethyl Sulphide in Sea Water", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"dmsos", @@ -766,10 +953,10 @@ "dpco2":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"Difference in partial pressure of carbon dioxide between sea water and air. The partial pressure of a dissolved gas in sea water is the partial pressure in air with which it would be in equilibrium. ", "dimensions":"longitude latitude time depth0m", "frequency":"mon", - "long_name":"Delta PCO2", + "long_name":"Delta CO2 Partial Pressure", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"dpco2", @@ -783,10 +970,10 @@ "dpco2abio":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"Difference in partial pressure of abiotic-analogue carbon dioxide between sea water and air. The partial pressure of a dissolved gas in sea water is the partial pressure in air with which it would be in equilibrium. An abiotic analogue is used to simulate the effect on a modelled variable when biological effects on ocean carbon concentration and alkalinity are ignored.", "dimensions":"longitude latitude time depth0m", "frequency":"mon", - "long_name":"Abiotic Delta PCO2", + "long_name":"Abiotic Delta Pco Partial Pressure", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"dpco2abio", @@ -800,10 +987,10 @@ "dpco2nat":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"Difference in partial pressure of natural-analogue carbon dioxide between sea water and air. The partial pressure of a dissolved gas in sea water is the partial pressure in air with which it would be in equilibrium. A natural analogue is used to simulate the effect on a modelled variable of imposing preindustrial atmospheric carbon dioxide concentrations, even when the model as a whole may be subjected to varying forcings. ", "dimensions":"longitude latitude time depth0m", "frequency":"mon", - "long_name":"Natural Delta PCO2", + "long_name":"Natural Delta CO2 Partial Pressure ", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"dpco2nat", @@ -817,10 +1004,10 @@ "dpo2":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"The partial pressure of a dissolved gas in sea water is the partial pressure in air with which it would be in equilibrium. The partial pressure of a gaseous constituent of air is the pressure which it alone would exert with unchanged temperature and number of moles per unit volume. The surface called 'surface' means the lower boundary of the atmosphere.", "dimensions":"longitude latitude time depth0m", "frequency":"mon", - "long_name":"Delta PO2", + "long_name":"Delta O2 Partial Pressure", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"dpo2", @@ -834,7 +1021,7 @@ "eparag100":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. 'Sinking' is the gravitational settling of particulate matter suspended in a liquid. A sinking flux is positive downwards and is calculated relative to the movement of the surrounding fluid. Aragonite is a mineral that is a polymorph of calcium carbonate. The chemical formula of aragonite is CaCO3. Standard names also exist for calcite, another polymorph of calcium carbonate.", "dimensions":"longitude latitude time depth100m", "frequency":"mon", "long_name":"Downward Flux of Aragonite", @@ -851,10 +1038,10 @@ "epc100":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. 'Sinking' is the gravitational settling of particulate matter suspended in a liquid. A sinking flux is positive downwards and is calculated relative to the movement of the surrounding fluid.", "dimensions":"longitude latitude time depth100m", "frequency":"mon", - "long_name":"Downward Flux of Particle Organic Carbon", + "long_name":"Downward Flux of Particulate Organic Carbon", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"epc100", @@ -868,7 +1055,7 @@ "epcalc100":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"The phrase 'expressed_as' is used in the construction A_expressed_as_B, where B is a chemical constituent of A. It means that the quantity indicated by the standard name is calculated solely with respect to the B contained in A, neglecting all other chemical constituents of A. In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. 'Sinking' is the gravitational settling of particulate matter suspended in a liquid. A sinking flux is positive downwards and is calculated relative to the movement of the surrounding fluid. Calcite is a mineral that is a polymorph of calcium carbonate. The chemical formula of calcite is CaCO3. Standard names also exist for aragonite, another polymorph of calcium carbonate.", "dimensions":"longitude latitude time depth100m", "frequency":"mon", "long_name":"Downward Flux of Calcite", @@ -885,7 +1072,7 @@ "epfe100":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. 'Sinking' is the gravitational settling of particulate matter suspended in a liquid. A sinking flux is positive downwards and is calculated relative to the movement of the surrounding fluid.", "dimensions":"longitude latitude time depth100m", "frequency":"mon", "long_name":"Downward Flux of Particulate Iron", @@ -902,7 +1089,7 @@ "epn100":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. 'Sinking' is the gravitational settling of particulate matter suspended in a liquid. A sinking flux is positive downwards and is calculated relative to the movement of the surrounding fluid.", "dimensions":"longitude latitude time depth100m", "frequency":"mon", "long_name":"Downward Flux of Particulate Nitrogen", @@ -919,7 +1106,7 @@ "epp100":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. 'Sinking' is the gravitational settling of particulate matter suspended in a liquid. A sinking flux is positive downwards and is calculated relative to the movement of the surrounding fluid.", "dimensions":"longitude latitude time depth100m", "frequency":"mon", "long_name":"Downward Flux of Particulate Phosphorus", @@ -936,10 +1123,10 @@ "epsi100":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. 'Sinking' is the gravitational settling of particulate matter suspended in a liquid. A sinking flux is positive downwards and is calculated relative to the movement of the surrounding fluid.", "dimensions":"longitude latitude time depth100m", "frequency":"mon", - "long_name":"Downward Flux of Particulate Silica", + "long_name":"Downward Flux of Particulate Silicon", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"epsi100", @@ -961,7 +1148,7 @@ "ok_min_mean_abs":"", "out_name":"evs", "positive":"", - "standard_name":"water_evaporation_flux", + "standard_name":"water_evapotranspiration_flux", "type":"real", "units":"kg m-2 s-1", "valid_max":"", @@ -973,7 +1160,7 @@ "comment":"Downward flux of particulate organic carbon", "dimensions":"longitude latitude olevel time", "frequency":"mon", - "long_name":"Sinking Particulate Organic Carbon Flux", + "long_name":"Downward Flux of Particulate Organic Carbon", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"expc", @@ -990,7 +1177,7 @@ "comment":"vertical integral of net biological terms in time rate of change of alkalinity", "dimensions":"longitude latitude time olayer100m", "frequency":"mon", - "long_name":"Rate of Change of Biological Alkalinity due to Biological Activity", + "long_name":"Rate of Change of Biological Alkalinity Due to Biological Activity", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"fbddtalk", @@ -1007,7 +1194,7 @@ "comment":"vertical integral of net biological terms in time rate of change of dissolved inorganic carbon", "dimensions":"longitude latitude time olayer100m", "frequency":"mon", - "long_name":"Rate of Change of Dissolved Inorganic Carbon due to Biological Activity", + "long_name":"Rate of Change of Dissolved Inorganic Carbon Due to Biological Activity", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"fbddtdic", @@ -1024,7 +1211,7 @@ "comment":"vertical integral of net biological terms in time rate of change of dissolved inorganic iron", "dimensions":"longitude latitude time olayer100m", "frequency":"mon", - "long_name":"Rate of Change of Dissolved Inorganic Iron due to Biological Activity", + "long_name":"Rate of Change of Dissolved Inorganic Iron Due to Biological Activity", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"fbddtdife", @@ -1041,7 +1228,7 @@ "comment":"vertical integral of net biological terms in time rate of change of nitrogen nutrients (e.g. NO3+NH4)", "dimensions":"longitude latitude time olayer100m", "frequency":"mon", - "long_name":"Rate of Change of Dissolved Inorganic Nitrogen due to Biological Activity", + "long_name":"Rate of Change of Dissolved Inorganic Nitrogen Due to Biological Activity", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"fbddtdin", @@ -1106,7 +1293,7 @@ "fddtdic":{ "cell_measures":"", "cell_methods":"area: mean where sea depth: sum where sea (top 100m only) time: mean", - "comment":"", + "comment":"'Content' indicates a quantity per unit area. 'tendency_of_X' means derivative of X with respect to time. 'Dissolved inorganic carbon' describes a family of chemical species in solution, including carbon dioxide, carbonic acid and the carbonate and bicarbonate anions. 'Dissolved inorganic carbon' is the term used in standard names for all species belonging to the family that are represented within a given model. The list of individual species that are included in a quantity having a group chemical standard name can vary between models. Where possible, the data variable should be accompanied by a complete description of the species represented, for example, by using a comment attribute.", "dimensions":"longitude latitude time olayer100m", "frequency":"mon", "long_name":"Rate of Change of Net Dissolved Inorganic Carbon", @@ -1160,7 +1347,7 @@ "comment":"vertical integral of net time rate of change of phosphate", "dimensions":"longitude latitude time olayer100m", "frequency":"mon", - "long_name":"Rate of Change of Net Dissolved Inorganic Phosphate", + "long_name":"Rate of Change of Net Dissolved Inorganic Phosphorus", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"fddtdip", @@ -1191,15 +1378,15 @@ "fg13co2":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"Gas exchange flux of carbon-13 as CO2 (positive into ocean)", "dimensions":"longitude latitude time depth0m", "frequency":"mon", - "long_name":"Surface Downward Flux of Abiotic 13CO2", + "long_name":"Surface Downward Flux of 13CO2", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"fg13co2", "positive":"down", - "standard_name":"surface_downward_mass_flux_of_carbon13_dioxide_abiotic_analogue_expressed_as_carbon13", + "standard_name":"surface_downward_mass_flux_of_13C_dioxide_abiotic_analogue_expressed_as_13C", "type":"real", "units":"kg m-2 s-1", "valid_max":"", @@ -1216,7 +1403,7 @@ "ok_min_mean_abs":"", "out_name":"fg14co2abio", "positive":"down", - "standard_name":"surface_downward_mass_flux_of_carbon14_dioxide_abiotic_analogue_expressed_as_carbon", + "standard_name":"surface_downward_mass_flux_of_14C_dioxide_abiotic_analogue_expressed_as_carbon", "type":"real", "units":"kg m-2 s-1", "valid_max":"", @@ -1228,14 +1415,14 @@ "comment":"gas exchange flux of CFC11", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Surface Downward CFC11 flux", + "long_name":"Surface Downward CFC11 Flux", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"fgcfc11", "positive":"down", "standard_name":"surface_downward_mole_flux_of_cfc11", "type":"real", - "units":"mol sec-1 m-2", + "units":"mol m-2 s-1", "valid_max":"", "valid_min":"" }, @@ -1245,14 +1432,14 @@ "comment":"gas exchange flux of CFC12", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Surface Downward CFC12 flux", + "long_name":"Surface Downward CFC12 Flux", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"fgcfc12", "positive":"down", "standard_name":"surface_downward_mole_flux_of_cfc12", "type":"real", - "units":"mol sec-1 m-2", + "units":"mol m-2 s-1", "valid_max":"", "valid_min":"" }, @@ -1347,14 +1534,14 @@ "comment":"gas exchange flux of SF6", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Surface Downward SF6 flux", + "long_name":"Surface Downward SF6 Flux", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"fgsf6", "positive":"down", "standard_name":"surface_downward_mole_flux_of_sulfur_hexafluoride", "type":"real", - "units":"mol sec-1 m-2", + "units":"mol m-2 s-1", "valid_max":"", "valid_min":"" }, @@ -1364,7 +1551,7 @@ "comment":"computed as the iceberg melt water flux into the ocean divided by the area of the ocean portion of the grid cell.", "dimensions":"longitude latitude olevel time", "frequency":"mon", - "long_name":"Water Flux into Sea Water From Icebergs", + "long_name":"Water Flux into Sea Water from Icebergs", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"ficeberg", @@ -1381,7 +1568,7 @@ "comment":"computed as the iceberg melt water flux into the ocean divided by the area of the ocean portion of the grid cell.", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Water Flux into Sea Water From Icebergs", + "long_name":"Water Flux into Sea Water from Icebergs", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"ficeberg", @@ -1395,7 +1582,7 @@ "frfe":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"'Content' indicates a quantity per unit area. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. 'tendency_of_X' means derivative of X with respect to time.", "dimensions":"longitude latitude time", "frequency":"mon", "long_name":"Iron Loss to Sediments", @@ -1403,7 +1590,7 @@ "ok_min_mean_abs":"", "out_name":"frfe", "positive":"", - "standard_name":"tendency_of_ocean_mole_content_of_iron_due_to_sedimentation", + "standard_name":"minus_tendency_of_ocean_mole_content_of_iron_due_to_sedimentation", "type":"real", "units":"mol m-2 s-1", "valid_max":"", @@ -1420,7 +1607,7 @@ "ok_min_mean_abs":"", "out_name":"fric", "positive":"", - "standard_name":"tendency_of_ocean_mole_content_of_inorganic_carbon_due_to_sedimentation", + "standard_name":"minus_tendency_of_ocean_mole_content_of_inorganic_carbon_due_to_sedimentation", "type":"real", "units":"mol m-2 s-1", "valid_max":"", @@ -1432,7 +1619,7 @@ "comment":"computed as the river flux of water into the ocean divided by the area of the ocean portion of the grid cell.", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Water Flux into Sea Water From Rivers", + "long_name":"Water Flux into Sea Water from Rivers", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"friver", @@ -1446,15 +1633,15 @@ "frn":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"'Content' indicates a quantity per unit area. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. 'Denitrification' is the conversion of nitrate into gaseous compounds such as nitric oxide, nitrous oxide and molecular nitrogen which are then emitted to the atmosphere. 'Sedimentation' is the sinking of particulate matter to the floor of a body of water. 'tendency_of_X' means derivative of X with respect to time.", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Nitrogen Loss to Sediments and through Denitrification", + "long_name":"Nitrogen Loss to Sediments and Through Denitrification", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"frn", "positive":"", - "standard_name":"tendency_of_ocean_mole_content_of_elemental_nitrogen_due_to_denitrification_and_sedimentation", + "standard_name":"minus_tendency_of_ocean_mole_content_of_elemental_nitrogen_due_to_denitrification_and_sedimentation", "type":"real", "units":"mol m-2 s-1", "valid_max":"", @@ -1471,7 +1658,7 @@ "ok_min_mean_abs":"", "out_name":"froc", "positive":"", - "standard_name":"tendency_of_ocean_mole_content_of_organic_carbon_due_to_sedimentation", + "standard_name":"minus_tendency_of_ocean_mole_content_of_organic_carbon_due_to_sedimentation", "type":"real", "units":"mol m-2 s-1", "valid_max":"", @@ -1500,7 +1687,7 @@ "comment":"computed as the sea ice thermodynamic water flux into the ocean divided by the area of the ocean portion of the grid cell.", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Water Flux into Sea Water due to Sea Ice Thermodynamics", + "long_name":"Water Flux into Sea Water Due to Sea Ice Thermodynamics", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"fsitherm", @@ -1514,7 +1701,7 @@ "fsn":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"Flux of nitrogen into the ocean due to deposition (sum of dry and wet deposition), fixation (the production of ammonia from nitrogen gas by diazotrophs) and runoff (liquid water which drains from land).", "dimensions":"longitude latitude time depth0m", "frequency":"mon", "long_name":"Surface Downward Net Flux of Nitrogen", @@ -1531,7 +1718,7 @@ "graz":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"Total grazing of phytoplankton by zooplankton defined as tendency of moles of carbon per cubic metre.", "dimensions":"longitude latitude olevel time", "frequency":"mon", "long_name":"Total Grazing of Phytoplankton by Zooplankton", @@ -1547,7 +1734,7 @@ }, "hfbasin":{ "cell_measures":"", - "cell_methods":"longitude: mean (basin) time: mean", + "cell_methods":"longitude: sum (comment: basin sum [along zig-zag grid path]) depth: sum time: mean", "comment":"Contains contributions from all physical processes affecting the northward heat transport, including resolved advection, parameterized advection, lateral diffusion, etc. Diagnosed here as a function of latitude and basin. Use Celsius for temperature scale.", "dimensions":"latitude basin time", "frequency":"mon", @@ -1564,11 +1751,11 @@ }, "hfbasinpadv":{ "cell_measures":"", - "cell_methods":"longitude: mean (basin) time: mean", + "cell_methods":"longitude: sum (comment: basin sum [along zig-zag grid path]) depth: sum time: mean", "comment":"Contributions to heat transport from parameterized eddy-induced advective transport due to any subgrid advective process. Diagnosed here as a function of latitude and basin. Use Celsius for temperature scale.", "dimensions":"latitude basin time", "frequency":"mon", - "long_name":"northward ocean heat transport due to parameterized eddy advection", + "long_name":"Northward Ocean Heat Transport Due to Parameterized Eddy Advection", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"hfbasinpadv", @@ -1581,11 +1768,11 @@ }, "hfbasinpmadv":{ "cell_measures":"", - "cell_methods":"longitude: mean (basin) time: mean", + "cell_methods":"longitude: sum (comment: basin sum [along zig-zag grid path]) depth: sum time: mean", "comment":"Contributions to heat transport from parameterized mesoscale eddy-induced advective transport. Diagnosed here as a function of latitude and basin. Use Celsius for temperature scale.", "dimensions":"latitude basin time", "frequency":"mon", - "long_name":"northward ocean heat transport due to parameterized mesoscale advection", + "long_name":"Northward Ocean Heat Transport Due to Parameterized Mesoscale Advection", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"hfbasinpmadv", @@ -1598,11 +1785,11 @@ }, "hfbasinpmdiff":{ "cell_measures":"", - "cell_methods":"longitude: mean (basin) time: mean", + "cell_methods":"longitude: sum (comment: basin sum [along zig-zag grid path]) depth: sum time: mean", "comment":"Contributions to heat transport from parameterized mesoscale eddy-induced diffusive transport (i.e., neutral diffusion). Diagnosed here as a function of latitude and basin.", "dimensions":"latitude basin time", "frequency":"mon", - "long_name":"northward ocean heat transport due to parameterized mesoscale diffusion", + "long_name":"Northward Ocean Heat Transport Due to Parameterized Mesoscale Diffusion", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"hfbasinpmdiff", @@ -1615,11 +1802,11 @@ }, "hfbasinpsmadv":{ "cell_measures":"", - "cell_methods":"longitude: mean (basin) time: mean", + "cell_methods":"longitude: sum (comment: basin sum [along zig-zag grid path]) depth: sum time: mean", "comment":"Contributions to heat transport from parameterized mesoscale eddy-induced advective transport. Diagnosed here as a function of latitude and basin. Use Celsius for temperature scale.", "dimensions":"latitude basin time", "frequency":"mon", - "long_name":"northward ocean heat transport due to parameterized submesoscale advection", + "long_name":"Northward Ocean Heat Transport Due to Parameterized Submesoscale Advection", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"hfbasinpsmadv", @@ -1633,7 +1820,7 @@ "hfcorr":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"Flux correction is also called 'flux adjustment'. A positive flux correction is downward i.e. added to the ocean. In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions":"longitude latitude time", "frequency":"mon", "long_name":"Heat Flux Correction", @@ -1670,7 +1857,7 @@ "comment":"This is defined as 'where ice_free_sea over sea'", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Temperature Flux due to Evaporation Expressed as Heat Flux Out of Sea Water", + "long_name":"Temperature Flux Due to Evaporation Expressed as Heat Flux out of Sea Water", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"hfevapds", @@ -1684,7 +1871,7 @@ "hfgeou":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"Upward geothermal heat flux per unit area on the sea floor", "dimensions":"longitude latitude time", "frequency":"mon", "long_name":"Upward Geothermal Heat Flux at Sea Floor", @@ -1701,10 +1888,10 @@ "hfibthermds":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. ' Iceberg thermodynamics' refers to the addition or subtraction of mass due to surface and basal fluxes, i.e., due to melting, sublimation and fusion.", "dimensions":"longitude latitude olevel time", "frequency":"mon", - "long_name":"Heat Flux into Sea Water due to Iceberg Thermodynamics", + "long_name":"Heat Flux into Sea Water Due to Iceberg Thermodynamics", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"hfibthermds", @@ -1718,10 +1905,10 @@ "hfibthermds2d":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. ' Iceberg thermodynamics' refers to the addition or subtraction of mass due to surface and basal fluxes, i.e., due to melting, sublimation and fusion.", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Heat Flux into Sea Water due to Iceberg Thermodynamics", + "long_name":"Heat Flux into Sea Water Due to Iceberg Thermodynamics", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"hfibthermds", @@ -1755,7 +1942,7 @@ "comment":"This is defined as 'where ice_free_sea over sea'; i.e., the total flux (considered here) entering the ice-free portion of the grid cell divided by the area of the ocean portion of the grid cell. All such heat fluxes are computed based on Celsius scale.", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Temperature Flux due to Rainfall Expressed as Heat Flux into Sea Water", + "long_name":"Temperature Flux Due to Rainfall Expressed as Heat Flux into Sea Water", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"hfrainds", @@ -1769,10 +1956,10 @@ "hfrunoffds":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"Heat flux associated with liquid water which drains from land. It is calculated relative to the heat that would be transported by runoff water entering the sea at zero degrees Celsius. ", "dimensions":"longitude latitude olevel time", "frequency":"mon", - "long_name":"Temperature Flux due to Runoff Expressed as Heat Flux into Sea Water", + "long_name":"Temperature Flux Due to Runoff Expressed as Heat Flux into Sea Water", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"hfrunoffds", @@ -1786,10 +1973,10 @@ "hfrunoffds2d":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"Heat flux associated with liquid water which drains from land. It is calculated relative to the heat that would be transported by runoff water entering the sea at zero degrees Celsius. ", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Temperature Flux due to Runoff Expressed as Heat Flux into Sea Water", + "long_name":"Temperature Flux Due to Runoff Expressed as Heat Flux into Sea Water", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"hfrunoffds", @@ -1803,10 +1990,10 @@ "hfsifrazil":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. 'Frazil' consists of needle like crystals of ice, typically between three and four millimeters in diameter, which form as sea water begins to freeze. Salt is expelled during the freezing process and frazil ice consists of nearly pure fresh water.", "dimensions":"longitude latitude olevel time", "frequency":"mon", - "long_name":"Heat Flux into Sea Water due to Frazil Ice Formation", + "long_name":"Heat Flux into Sea Water Due to Frazil Ice Formation", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"hfsifrazil", @@ -1820,10 +2007,10 @@ "hfsifrazil2d":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. 'Frazil' consists of needle like crystals of ice, typically between three and four millimeters in diameter, which form as sea water begins to freeze. Salt is expelled during the freezing process and frazil ice consists of nearly pure fresh water.", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Heat Flux into Sea Water due to Frazil Ice Formation", + "long_name":"Heat Flux into Sea Water Due to Frazil Ice Formation", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"hfsifrazil", @@ -1837,10 +2024,10 @@ "hfsnthermds":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. 'Snow thermodynamics' refers to the addition or subtraction of mass due to surface and basal fluxes, i.e., due to melting, sublimation and fusion.", "dimensions":"longitude latitude olevel time", "frequency":"mon", - "long_name":"Heat Flux into Sea Water due to Snow Thermodynamics", + "long_name":"Heat Flux into Sea Water Due to Snow Thermodynamics", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"hfsnthermds", @@ -1854,10 +2041,10 @@ "hfsnthermds2d":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. The specification of a physical process by the phrase due_to_process means that the quantity named is a single term in a sum of terms which together compose the general quantity named by omitting the phrase. 'Snow thermodynamics' refers to the addition or subtraction of mass due to surface and basal fluxes, i.e., due to melting, sublimation and fusion.", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Heat Flux into Sea Water due to Snow Thermodynamics", + "long_name":"Heat Flux into Sea Water Due to Snow Thermodynamics", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"hfsnthermds", @@ -1871,7 +2058,7 @@ "hfsso":{ "cell_measures":"", "cell_methods":"area: mean where ice_free_sea over sea time: mean", - "comment":"This is defined as 'where ice_free_sea over sea'", + "comment":"Upward sensible heat flux over sea ice free sea. The surface sensible heat flux, also called turbulent heat flux, is the exchange of heat between the surface and the air by motion of air.", "dimensions":"longitude latitude time", "frequency":"mon", "long_name":"Surface Downward Sensible Heat Flux", @@ -1921,11 +2108,11 @@ }, "htovgyre":{ "cell_measures":"", - "cell_methods":"longitude: mean time: mean", + "cell_methods":"longitude: sum (comment: basin sum [along zig-zag grid path]) depth: sum time: mean", "comment":"From all advective mass transport processes, resolved and parameterized.", "dimensions":"latitude basin time", "frequency":"mon", - "long_name":"Northward Ocean Heat Transport due to Gyre", + "long_name":"Northward Ocean Heat Transport Due to Gyre", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"htovgyre", @@ -1938,11 +2125,11 @@ }, "htovovrt":{ "cell_measures":"", - "cell_methods":"longitude: mean time: mean", + "cell_methods":"longitude: sum (comment: basin sum [along zig-zag grid path]) depth: sum time: mean", "comment":"From all advective mass transport processes, resolved and parameterized.", "dimensions":"latitude basin time", "frequency":"mon", - "long_name":"Northward Ocean Heat Transport due to Overturning", + "long_name":"Northward Ocean Heat Transport Due to Overturning", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"htovovrt", @@ -1959,7 +2146,7 @@ "comment":"Inorganic Carbon supply to ocean through runoff (separate from gas exchange)", "dimensions":"longitude latitude time depth0m", "frequency":"mon", - "long_name":"Flux of Inorganic Carbon Into Ocean Surface by Runoff", + "long_name":"Flux of Inorganic Carbon into Ocean Surface by Runoff", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"icfriver", @@ -1972,7 +2159,7 @@ }, "intdic":{ "cell_measures":"", - "cell_methods":"area: mean where sea time: mean", + "cell_methods":"area: mean where sea depth: sum where sea time: mean", "comment":"Vertically integrated DIC", "dimensions":"longitude latitude time", "frequency":"mon", @@ -1989,7 +2176,7 @@ }, "intdoc":{ "cell_measures":"", - "cell_methods":"area: mean where sea time: mean", + "cell_methods":"area: mean where sea depth: sum where sea time: mean", "comment":"Vertically integrated DOC (explicit pools only)", "dimensions":"longitude latitude time", "frequency":"mon", @@ -2006,7 +2193,7 @@ }, "intparag":{ "cell_measures":"", - "cell_methods":"area: mean where sea time: mean", + "cell_methods":"area: mean where sea depth: sum where sea time: mean", "comment":"Vertically integrated aragonite production", "dimensions":"longitude latitude time", "frequency":"mon", @@ -2023,7 +2210,7 @@ }, "intpbfe":{ "cell_measures":"", - "cell_methods":"area: mean where sea time: mean", + "cell_methods":"area: mean where sea depth: sum where sea time: mean", "comment":"Vertically integrated biogenic iron production", "dimensions":"longitude latitude time", "frequency":"mon", @@ -2040,7 +2227,7 @@ }, "intpbn":{ "cell_measures":"", - "cell_methods":"area: mean where sea time: mean", + "cell_methods":"area: mean where sea depth: sum where sea time: mean", "comment":"Vertically integrated biogenic nitrogen production", "dimensions":"longitude latitude time", "frequency":"mon", @@ -2057,7 +2244,7 @@ }, "intpbp":{ "cell_measures":"", - "cell_methods":"area: mean where sea time: mean", + "cell_methods":"area: mean where sea depth: sum where sea time: mean", "comment":"Vertically integrated biogenic phosphorus production", "dimensions":"longitude latitude time", "frequency":"mon", @@ -2074,11 +2261,11 @@ }, "intpbsi":{ "cell_measures":"", - "cell_methods":"area: mean where sea time: mean", + "cell_methods":"area: mean where sea depth: sum where sea time: mean", "comment":"Vertically integrated biogenic silica production", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Silica Production", + "long_name":"Silicon Production", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"intpbsi", @@ -2091,7 +2278,7 @@ }, "intpcalcite":{ "cell_measures":"", - "cell_methods":"area: mean where sea time: mean", + "cell_methods":"area: mean where sea depth: sum where sea time: mean", "comment":"Vertically integrated calcite production", "dimensions":"longitude latitude time", "frequency":"mon", @@ -2108,7 +2295,7 @@ }, "intpn2":{ "cell_measures":"", - "cell_methods":"area: mean where sea time: mean", + "cell_methods":"area: mean where sea depth: sum where sea time: mean", "comment":"Vertically integrated nitrogen fixation", "dimensions":"longitude latitude time", "frequency":"mon", @@ -2125,7 +2312,7 @@ }, "intpoc":{ "cell_measures":"", - "cell_methods":"area: mean where sea time: mean", + "cell_methods":"area: mean where sea depth: sum where sea time: mean", "comment":"Vertically integrated POC", "dimensions":"longitude latitude time", "frequency":"mon", @@ -2142,7 +2329,7 @@ }, "intpp":{ "cell_measures":"", - "cell_methods":"area: mean where sea time: mean", + "cell_methods":"area: mean where sea depth: sum where sea time: mean", "comment":"Vertically integrated total primary (organic carbon) production by phytoplankton. This should equal the sum of intpdiat+intpphymisc, but those individual components may be unavailable in some models.", "dimensions":"longitude latitude time", "frequency":"mon", @@ -2159,8 +2346,8 @@ }, "intppcalc":{ "cell_measures":"", - "cell_methods":"area: mean where sea time: mean", - "comment":"", + "cell_methods":"area: mean where sea depth: sum where sea time: mean", + "comment":"Vertically integrated primary (organic carbon) production by the calcareous phytoplankton component alone", "dimensions":"longitude latitude time", "frequency":"mon", "long_name":"Net Primary Mole Productivity of Carbon by Calcareous Phytoplankton", @@ -2176,7 +2363,7 @@ }, "intppdiat":{ "cell_measures":"", - "cell_methods":"area: mean where sea time: mean", + "cell_methods":"area: mean where sea depth: sum where sea time: mean", "comment":"Vertically integrated primary (organic carbon) production by the diatom phytoplankton component alone", "dimensions":"longitude latitude time", "frequency":"mon", @@ -2193,8 +2380,8 @@ }, "intppdiaz":{ "cell_measures":"", - "cell_methods":"area: mean where sea time: mean", - "comment":"", + "cell_methods":"area: mean where sea depth: sum where sea time: mean", + "comment":"Vertically integrated primary (organic carbon) production by the diazotrophs alone", "dimensions":"longitude latitude time", "frequency":"mon", "long_name":"Net Primary Mole Productivity of Carbon by Diazotrophs", @@ -2210,7 +2397,7 @@ }, "intppmisc":{ "cell_measures":"", - "cell_methods":"area: mean where sea time: mean", + "cell_methods":"area: mean where sea depth: sum where sea time: mean", "comment":"Vertically integrated total primary (organic carbon) production by other phytoplankton components alone", "dimensions":"longitude latitude time", "frequency":"mon", @@ -2227,7 +2414,7 @@ }, "intppnitrate":{ "cell_measures":"", - "cell_methods":"area: mean where sea time: mean", + "cell_methods":"area: mean where sea depth: sum where sea time: mean", "comment":"Vertically integrated primary (organic carbon) production by phytoplankton based on nitrate uptake alone", "dimensions":"longitude latitude time", "frequency":"mon", @@ -2244,8 +2431,8 @@ }, "intpppico":{ "cell_measures":"", - "cell_methods":"area: mean where sea time: mean", - "comment":"", + "cell_methods":"area: mean where sea depth: sum where sea time: mean", + "comment":"Vertically integrated primary (organic carbon) production by the picophytoplankton component alone", "dimensions":"longitude latitude time", "frequency":"mon", "long_name":"Net Primary Mole Productivity of Carbon by Picophytoplankton", @@ -2262,10 +2449,10 @@ "limfecalc":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"'Calcareous phytoplankton' are phytoplankton that produce calcite. Calcite is a mineral that is a polymorph of calcium carbonate. The chemical formula of calcite is CaCO3. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. 'Iron growth limitation' means the ratio of the growth rate of a species population in the environment (where there is a finite availability of iron) to the theoretical growth rate if there were no such limit on iron availability.", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Iron limitation of Calcareous Phytoplankton", + "long_name":"Iron Limitation of Calcareous Phytoplankton", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"limfecalc", @@ -2279,10 +2466,10 @@ "limfediat":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"Diatoms are phytoplankton with an external skeleton made of silica. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. 'Iron growth limitation' means the ratio of the growth rate of a species population in the environment (where there is a finite availability of iron) to the theoretical growth rate if there were no such limit on iron availability.", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Iron limitation of Diatoms", + "long_name":"Iron Limitation of Diatoms", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"limfediat", @@ -2296,10 +2483,10 @@ "limfediaz":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"In ocean modelling, diazotrophs are phytoplankton of the phylum cyanobacteria distinct from other phytoplankton groups in their ability to fix nitrogen gas in addition to nitrate and ammonium. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. 'Iron growth limitation' means the ratio of the growth rate of a species population in the environment (where there is a finite availability of iron) to the theoretical growth rate if there were no such limit on iron availability.", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Iron limitation of Diazotrophs", + "long_name":"Iron Limitation of Diazotrophs", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"limfediaz", @@ -2313,7 +2500,7 @@ "limfemisc":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. 'Miscellaneous phytoplankton' are all those phytoplankton that are not diatoms, diazotrophs, calcareous phytoplankton, picophytoplankton or other separately named components of the phytoplankton population. 'Iron growth limitation' means the ratio of the growth rate of a species population in the environment (where there is a finite availability of iron) to the theoretical growth rate if there were no such limit on iron availability.", "dimensions":"longitude latitude time", "frequency":"mon", "long_name":"Iron Limitation of Other Phytoplankton", @@ -2330,10 +2517,10 @@ "limfepico":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"Picophytoplankton are phytoplankton of less than 2 micrometers in size. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. 'Iron growth limitation' means the ratio of the growth rate of a species population in the environment (where there is a finite availability of iron) to the theoretical growth rate if there were no such limit on iron availability.", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Iron limitation of Picophytoplankton", + "long_name":"Iron Limitation of Picophytoplankton", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"limfepico", @@ -2347,10 +2534,10 @@ "limirrcalc":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"Growth limitation of calcareous phytoplankton due to solar irradiance. 'Growth limitation due to solar irradiance' means the ratio of the growth rate of a species population in the environment (where the amount of sunlight reaching a location may be limited) to the theoretical growth rate if there were no such limit on solar irradiance.", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Irradiance limitation of Calcareous Phytoplankton", + "long_name":"Irradiance Limitation of Calcareous Phytoplankton", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"limirrcalc", @@ -2364,10 +2551,10 @@ "limirrdiat":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"Growth limitation of diatoms due to solar irradiance. 'Growth limitation due to solar irradiance' means the ratio of the growth rate of a species population in the environment (where the amount of sunlight reaching a location may be limited) to the theoretical growth rate if there were no such limit on solar irradiance.", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Irradiance limitation of Diatoms", + "long_name":"Irradiance Limitation of Diatoms", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"limirrdiat", @@ -2381,10 +2568,10 @@ "limirrdiaz":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"Growth limitation of diazotrophs due to solar irradiance. 'Growth limitation due to solar irradiance' means the ratio of the growth rate of a species population in the environment (where the amount of sunlight reaching a location may be limited) to the theoretical growth rate if there were no such limit on solar irradiance.", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Irradiance limitation of Diazotrophs", + "long_name":"Irradiance Limitation of Diazotrophs", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"limirrdiaz", @@ -2398,7 +2585,7 @@ "limirrmisc":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"Growth limitation of miscellaneous phytoplankton due to solar irradiance. 'Growth limitation due to solar irradiance' means the ratio of the growth rate of a species population in the environment (where the amount of sunlight reaching a location may be limited) to the theoretical growth rate if there were no such limit on solar irradiance.", "dimensions":"longitude latitude time", "frequency":"mon", "long_name":"Irradiance Limitation of Other Phytoplankton", @@ -2415,10 +2602,10 @@ "limirrpico":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"Growth limitation of picophytoplankton due to solar irradiance. 'Growth limitation due to solar irradiance' means the ratio of the growth rate of a species population in the environment (where the amount of sunlight reaching a location may be limited) to the theoretical growth rate if there were no such limit on solar irradiance.", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Irradiance limitation of Picophytoplankton", + "long_name":"Irradiance Limitation of Picophytoplankton", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"limirrpico", @@ -2432,10 +2619,10 @@ "limncalc":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"'Calcareous phytoplankton' are phytoplankton that produce calcite. Calcite is a mineral that is a polymorph of calcium carbonate. The chemical formula of calcite is CaCO3. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. 'Nitrogen growth limitation' means the ratio of the growth rate of a species population in the environment (where there is a finite availability of nitrogen) to the theoretical growth rate if there were no such limit on nitrogen availability.", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Nitrogen limitation of Calcareous Phytoplankton", + "long_name":"Nitrogen Limitation of Calcareous Phytoplankton", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"limncalc", @@ -2449,10 +2636,10 @@ "limndiat":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"Diatoms are phytoplankton with an external skeleton made of silica. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. 'Nitrogen growth limitation' means the ratio of the growth rate of a species population in the environment (where there is a finite availability of nitrogen) to the theoretical growth rate if there were no such limit on nitrogen availability.", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Nitrogen limitation of Diatoms", + "long_name":"Nitrogen Limitation of Diatoms", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"limndiat", @@ -2466,10 +2653,10 @@ "limndiaz":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"In ocean modelling, diazotrophs are phytoplankton of the phylum cyanobacteria distinct from other phytoplankton groups in their ability to fix nitrogen gas in addition to nitrate and ammonium. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. 'Nitrogen growth limitation' means the ratio of the growth rate of a species population in the environment (where there is a finite availability of nitrogen) to the theoretical growth rate if there were no such limit on nitrogen availability.", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Nitrogen limitation of Diazotrophs", + "long_name":"Nitrogen Limitation of Diazotrophs", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"limndiaz", @@ -2483,7 +2670,7 @@ "limnmisc":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. 'Miscellaneous phytoplankton' are all those phytoplankton that are not diatoms, diazotrophs, calcareous phytoplankton, picophytoplankton or other separately named components of the phytoplankton population. 'Nitrogen growth limitation' means the ratio of the growth rate of a species population in the environment (where there is a finite availability of nitrogen) to the theoretical growth rate if there were no such limit on nitrogen availability.", "dimensions":"longitude latitude time", "frequency":"mon", "long_name":"Nitrogen Limitation of Other Phytoplankton", @@ -2500,10 +2687,10 @@ "limnpico":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"Picophytoplankton are phytoplankton of less than 2 micrometers in size. Phytoplankton are algae that grow where there is sufficient light to support photosynthesis. 'Nitrogen growth limitation' means the ratio of the growth rate of a species population in the environment (where there is a finite availability of nitrogen) to the theoretical growth rate if there were no such limit on nitrogen availability.", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Nitrogen limitation of Picophytoplankton", + "long_name":"Nitrogen Limitation of Picophytoplankton", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"limnpico", @@ -2520,7 +2707,7 @@ "comment":"Tracer grid-cell mass per unit area used for computing tracer budgets. For Boussinesq models with static ocean grid cell thickness, masscello = rhozero*thickcello, where thickcello is static cell thickness and rhozero is constant Boussinesq reference density. More generally, masscello is time dependent and reported as part of Omon.", "dimensions":"longitude latitude olevel time", "frequency":"mon", - "long_name":"Sea Water Mass Per Unit Area", + "long_name":"Ocean Grid-Cell Mass per Area", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"masscello", @@ -2551,7 +2738,7 @@ "mfo":{ "cell_measures":"", "cell_methods":"time: mean", - "comment":"", + "comment":"Transport across_line means that which crosses a particular line on the Earth's surface; formally this means the integral along the line of the normal component of the transport.", "dimensions":"oline time", "frequency":"mon", "long_name":"Sea Water Transport", @@ -2619,7 +2806,7 @@ "mlotstsq":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"The phrase 'square_of_X' means X*X. The ocean mixed layer is the upper part of the ocean, regarded as being well-mixed. The base of the mixed layer defined by 'temperature', 'sigma', 'sigma_theta', 'sigma_t' or vertical diffusivity is the level at which the quantity indicated differs from its surface value by a certain amount. A coordinate variable or scalar coordinate variable with standard name sea_water_sigma_t_difference can be used to specify the sigma_t criterion that determines the layer thickness. Sigma-t of sea water is the density of water at atmospheric pressure (i.e. the surface) having the same temperature and salinity, minus 1000 kg m-3. 'Thickness' means the vertical extent of a layer.", "dimensions":"longitude latitude time", "frequency":"mon", "long_name":"Square of Ocean Mixed Layer Thickness Defined by Sigma T", @@ -2652,7 +2839,7 @@ }, "msftmrho":{ "cell_measures":"", - "cell_methods":"longitude: mean (comment: basin mean[ along zig-zag grid path]) time: mean", + "cell_methods":"longitude: sum (comment: basin sum [along zig-zag grid path]) depth: sum time: mean", "comment":"Overturning mass streamfunction arising from all advective mass transport processes, resolved and parameterized.", "dimensions":"latitude rho basin time", "frequency":"mon", @@ -2669,11 +2856,11 @@ }, "msftmrhompa":{ "cell_measures":"", - "cell_methods":"longitude: mean (comment: basin mean[ along zig-zag grid path]) time: mean", + "cell_methods":"longitude: sum (comment: basin sum [along zig-zag grid path]) depth: sum time: mean", "comment":"CMIP5 called this 'due to Bolus Advection'. Name change respects the more general physics of the mesoscale parameterizations.", "dimensions":"latitude rho basin time", "frequency":"mon", - "long_name":"ocean meridional overturning mass streamfunction due to parameterized mesoscale advection", + "long_name":"Ocean Meridional Overturning Mass Streamfunction Due to Parameterized Mesoscale Advection", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"msftmrhompa", @@ -2686,7 +2873,7 @@ }, "msftmz":{ "cell_measures":"", - "cell_methods":"longitude: mean (comment: basin mean[ along zig-zag grid path]) time: mean", + "cell_methods":"longitude: sum (comment: basin sum [along zig-zag grid path]) depth: sum time: mean", "comment":"Overturning mass streamfunction arising from all advective mass transport processes, resolved and parameterized.", "dimensions":"latitude olevel basin time", "frequency":"mon", @@ -2703,11 +2890,11 @@ }, "msftmzmpa":{ "cell_measures":"", - "cell_methods":"longitude: mean (comment: basin mean[ along zig-zag grid path]) time: mean", + "cell_methods":"longitude: sum (comment: basin sum [along zig-zag grid path]) depth: sum time: mean", "comment":"CMIP5 called this 'due to Bolus Advection'. Name change respects the more general physics of the mesoscale parameterizations.", "dimensions":"latitude olevel basin time", "frequency":"mon", - "long_name":"ocean meridional overturning mass streamfunction due to parameterized mesoscale advection", + "long_name":"Ocean Meridional Overturning Mass Streamfunction Due to Parameterized Mesoscale Advection", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"msftmzmpa", @@ -2720,11 +2907,11 @@ }, "msftmzsmpa":{ "cell_measures":"", - "cell_methods":"longitude: mean (comment: basin mean[ along zig-zag grid path]) time: mean", + "cell_methods":"longitude: sum (comment: basin sum [along zig-zag grid path]) depth: sum time: mean", "comment":"Report only if there is a submesoscale eddy parameterization.", "dimensions":"latitude olevel basin time", "frequency":"mon", - "long_name":"ocean meridional overturning mass streamfunction due to parameterized submesoscale advection", + "long_name":"Ocean Meridional Overturning Mass Streamfunction Due to Parameterized Submesoscale Advection", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"msftmzsmpa", @@ -2739,7 +2926,7 @@ "cell_measures":"", "cell_methods":"time: mean grid_longitude: mean", "comment":"Overturning mass streamfunction arising from all advective mass transport processes, resolved and parameterized.", - "dimensions":"latitude rho basin time", + "dimensions":"gridlatitude rho basin time", "frequency":"mon", "long_name":"Ocean Y Overturning Mass Streamfunction", "ok_max_mean_abs":"", @@ -2756,9 +2943,9 @@ "cell_measures":"", "cell_methods":"time: mean grid_longitude: mean", "comment":"CMIP5 called this 'due to Bolus Advection'. Name change respects the more general physics of the mesoscale parameterizations.", - "dimensions":"latitude rho basin time", + "dimensions":"gridlatitude rho basin time", "frequency":"mon", - "long_name":"ocean Y overturning mass streamfunction due to parameterized mesoscale advection", + "long_name":"Ocean Y Overturning Mass Streamfunction Due to Parameterized Mesoscale Advection", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"msftyrhompa", @@ -2773,7 +2960,7 @@ "cell_measures":"", "cell_methods":"time: mean grid_longitude: mean", "comment":"Overturning mass streamfunction arising from all advective mass transport processes, resolved and parameterized.", - "dimensions":"latitude olevel basin time", + "dimensions":"gridlatitude olevel basin time", "frequency":"mon", "long_name":"Ocean Y Overturning Mass Streamfunction", "ok_max_mean_abs":"", @@ -2790,9 +2977,9 @@ "cell_measures":"", "cell_methods":"time: mean grid_longitude: mean", "comment":"CMIP5 called this 'due to Bolus Advection'. Name change respects the more general physics of the mesoscale parameterizations.", - "dimensions":"latitude olevel basin time", + "dimensions":"gridlatitude olevel basin time", "frequency":"mon", - "long_name":"ocean Y overturning mass streamfunction due to parameterized mesoscale advection", + "long_name":"Ocean Y Overturning Mass Streamfunction Due to Parameterized Mesoscale Advection", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"msftyzmpa", @@ -2805,11 +2992,11 @@ }, "msftyzsmpa":{ "cell_measures":"", - "cell_methods":"longitude: mean (comment: basin mean[ along zig-zag grid path]) time: mean", + "cell_methods":"longitude: sum (comment: basin sum [along zig-zag grid path]) depth: sum time: mean", "comment":"Report only if there is a submesoscale eddy parameterization.", "dimensions":"latitude olevel basin time", "frequency":"mon", - "long_name":"ocean Y overturning mass streamfunction due to parameterized submesoscale advection", + "long_name":"Ocean Y Overturning Mass Streamfunction Due to Parameterized Submesoscale Advection", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"msftyzsmpa", @@ -2823,7 +3010,7 @@ "nh4":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"Mole concentration means moles (amount of substance) per unit volume and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y.", "dimensions":"longitude latitude olevel time", "frequency":"mon", "long_name":"Dissolved Ammonium Concentration", @@ -2837,10 +3024,27 @@ "valid_max":"", "valid_min":"" }, + "nh4os":{ + "cell_measures":"", + "cell_methods":"area: mean where sea time: mean", + "comment":"Mole concentration means moles (amount of substance) per unit volume and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y.", + "dimensions":"longitude latitude time", + "frequency":"mon", + "long_name":"Surface Dissolved Ammonium Concentration", + "ok_max_mean_abs":"", + "ok_min_mean_abs":"", + "out_name":"nh4os", + "positive":"", + "standard_name":"mole_concentration_of_ammonium_in_sea_water", + "type":"real", + "units":"mol m-3", + "valid_max":"", + "valid_min":"" + }, "no3":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"Mole concentration means moles (amount of substance) per unit volume and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y.", "dimensions":"longitude latitude olevel time", "frequency":"mon", "long_name":"Dissolved Nitrate Concentration", @@ -2857,8 +3061,8 @@ "no3os":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", - "dimensions":"longitude latitude time depth0m", + "comment":"Mole concentration means moles (amount of substance) per unit volume and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y.", + "dimensions":"longitude latitude time", "frequency":"mon", "long_name":"Surface Dissolved Nitrate Concentration", "ok_max_mean_abs":"", @@ -2874,7 +3078,7 @@ "o2":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"'Mole concentration' means number of moles per unit volume, also called 'molarity', and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'.", "dimensions":"longitude latitude olevel time", "frequency":"mon", "long_name":"Dissolved Oxygen Concentration", @@ -2891,7 +3095,7 @@ "o2min":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"'Mole concentration' means number of moles per unit volume, also called 'molarity', and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The concentration of any chemical species, whether particulate or dissolved, may vary with depth in the ocean. A depth profile may go through one or more local minima in concentration. The mole_concentration_of_molecular_oxygen_in_sea_water_at_shallowest_local_minimum_in_vertical_profile is the mole concentration of oxygen at the local minimum in the concentration profile that occurs closest to the sea surface.", "dimensions":"longitude latitude time", "frequency":"mon", "long_name":"Oxygen Minimum Concentration", @@ -2908,8 +3112,8 @@ "o2os":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", - "dimensions":"longitude latitude time depth0m", + "comment":"'Mole concentration' means number of moles per unit volume, also called 'molarity', and is used in the construction mole_concentration_of_X_in_Y, where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'.", + "dimensions":"longitude latitude time", "frequency":"mon", "long_name":"Surface Dissolved Oxygen Concentration", "ok_max_mean_abs":"", @@ -2925,7 +3129,7 @@ "o2sat":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"'Mole concentration at saturation' means the mole concentration in a saturated solution. Mole concentration means number of moles per unit volume, also called 'molarity', and is used in the construction 'mole_concentration_of_X_in_Y', where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'.", "dimensions":"longitude latitude olevel time", "frequency":"mon", "long_name":"Dissolved Oxygen Concentration at Saturation", @@ -2942,8 +3146,8 @@ "o2satos":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", - "dimensions":"longitude latitude time depth0m", + "comment":"'Mole concentration at saturation' means the mole concentration in a saturated solution. Mole concentration means number of moles per unit volume, also called 'molarity', and is used in the construction 'mole_concentration_of_X_in_Y', where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'.", + "dimensions":"longitude latitude time", "frequency":"mon", "long_name":"Surface Dissolved Oxygen Concentration at Saturation", "ok_max_mean_abs":"", @@ -2959,7 +3163,7 @@ "obvfsq":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"The phrase 'square_of_X' means X*X. Frequency is the number of oscillations of a wave per unit time. Brunt-Vaisala frequency is also sometimes called 'buoyancy frequency' and is a measure of the vertical stratification of the medium.", "dimensions":"longitude latitude olevel time", "frequency":"mon", "long_name":"Square of Brunt Vaisala Frequency in Sea Water", @@ -2979,7 +3183,7 @@ "comment":"Organic Carbon supply to ocean through runoff (separate from gas exchange)", "dimensions":"longitude latitude time depth0m", "frequency":"mon", - "long_name":"Flux of Organic Carbon Into Ocean Surface by Runoff", + "long_name":"Flux of Organic Carbon into Ocean Surface by Runoff", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"ocfriver", @@ -2990,30 +3194,13 @@ "valid_max":"", "valid_min":"" }, - "pbfe":{ - "cell_measures":"", - "cell_methods":"area: mean where sea time: mean", - "comment":"", - "dimensions":"longitude latitude time depth0m", - "frequency":"mon", - "long_name":"Biogenic Iron Production", - "ok_max_mean_abs":"", - "ok_min_mean_abs":"", - "out_name":"pbfe", - "positive":"", - "standard_name":"tendency_of_mole_concentration_of_iron_in_sea_water_due_to_biological_production", - "type":"real", - "units":"mol m-3 s-1", - "valid_max":"", - "valid_min":"" - }, "pbo":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"'Sea water pressure' is the pressure that exists in the medium of sea water. It includes the pressure due to overlying sea water, sea ice, air and any other medium that may be present.", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Sea Water Pressure at Sea floor", + "long_name":"Sea Water Pressure at Sea Floor", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"pbo", @@ -3024,23 +3211,6 @@ "valid_max":"", "valid_min":"" }, - "pbsi":{ - "cell_measures":"", - "cell_methods":"area: mean where sea time: mean", - "comment":"", - "dimensions":"longitude latitude time depth0m", - "frequency":"mon", - "long_name":"Biogenic Silica Production", - "ok_max_mean_abs":"", - "ok_min_mean_abs":"", - "out_name":"pbsi", - "positive":"", - "standard_name":"tendency_of_mole_concentration_of_silicon_in_sea_water_due_to_biological_production", - "type":"real", - "units":"mol m-3 s-1", - "valid_max":"", - "valid_min":"" - }, "ph":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", @@ -3079,7 +3249,7 @@ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", "comment":"negative log10 of hydrogen ion concentration with the concentration expressed as mol H kg-1.", - "dimensions":"longitude latitude time depth0m", + "dimensions":"longitude latitude time", "frequency":"mon", "long_name":"Surface Abiotic pH", "ok_max_mean_abs":"", @@ -3113,7 +3283,7 @@ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", "comment":"negative log10 of hydrogen ion concentration with the concentration expressed as mol H kg-1.", - "dimensions":"longitude latitude time depth0m", + "dimensions":"longitude latitude time", "frequency":"mon", "long_name":"Surface Natural pH", "ok_max_mean_abs":"", @@ -3126,6 +3296,23 @@ "valid_max":"", "valid_min":"" }, + "phos":{ + "cell_measures":"", + "cell_methods":"area: mean where sea time: mean", + "comment":"negative log10 of hydrogen ion concentration with the concentration expressed as mol H kg-1.", + "dimensions":"longitude latitude time", + "frequency":"mon", + "long_name":"Surface pH", + "ok_max_mean_abs":"", + "ok_min_mean_abs":"", + "out_name":"phos", + "positive":"", + "standard_name":"sea_water_ph_reported_on_total_scale", + "type":"real", + "units":"1", + "valid_max":"", + "valid_min":"" + }, "phyc":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", @@ -3149,7 +3336,7 @@ "comment":"carbon concentration from calcareous (calcite-producing) phytoplankton component alone", "dimensions":"longitude latitude olevel time", "frequency":"mon", - "long_name":"Mole Concentration of Calcareous Phytoplankton expressed as Carbon in sea water", + "long_name":"Mole Concentration of Calcareous Phytoplankton Expressed as Carbon in Sea Water", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"phycalc", @@ -3160,13 +3347,30 @@ "valid_max":"", "valid_min":"" }, + "phycalcos":{ + "cell_measures":"", + "cell_methods":"area: mean where sea time: mean", + "comment":"carbon concentration from calcareous (calcite-producing) phytoplankton component alone", + "dimensions":"longitude latitude time", + "frequency":"mon", + "long_name":"Surface Mole Concentration of Calcareous Phytoplankton Expressed as Carbon in Sea Water", + "ok_max_mean_abs":"", + "ok_min_mean_abs":"", + "out_name":"phycalcos", + "positive":"", + "standard_name":"mole_concentration_of_calcareous_phytoplankton_expressed_as_carbon_in_sea_water", + "type":"real", + "units":"mol m-3", + "valid_max":"", + "valid_min":"" + }, "phycos":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", "comment":"sum of phytoplankton organic carbon component concentrations at the sea surface", - "dimensions":"longitude latitude time depth0m", + "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Surface Phytoplankton Carbon Concentration", + "long_name":"Sea Surface Phytoplankton Carbon Concentration", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"phycos", @@ -3183,7 +3387,7 @@ "comment":"carbon from the diatom phytoplankton component concentration alone", "dimensions":"longitude latitude olevel time", "frequency":"mon", - "long_name":"Mole Concentration of Diatoms expressed as Carbon in sea water", + "long_name":"Mole Concentration of Diatoms Expressed as Carbon in Sea Water", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"phydiat", @@ -3194,13 +3398,30 @@ "valid_max":"", "valid_min":"" }, + "phydiatos":{ + "cell_measures":"", + "cell_methods":"area: mean where sea time: mean", + "comment":"carbon from the diatom phytoplankton component concentration alone", + "dimensions":"longitude latitude time", + "frequency":"mon", + "long_name":"Surface Mole Concentration of Diatoms Expressed as Carbon in Sea Water", + "ok_max_mean_abs":"", + "ok_min_mean_abs":"", + "out_name":"phydiatos", + "positive":"", + "standard_name":"mole_concentration_of_diatoms_expressed_as_carbon_in_sea_water", + "type":"real", + "units":"mol m-3", + "valid_max":"", + "valid_min":"" + }, "phydiaz":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", "comment":"carbon concentration from the diazotrophic phytoplankton component alone", "dimensions":"longitude latitude olevel time", "frequency":"mon", - "long_name":"Mole Concentration of Diazotrophs Expressed as Carbon in sea water", + "long_name":"Mole Concentration of Diazotrophs Expressed as Carbon in Sea Water", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"phydiaz", @@ -3211,6 +3432,23 @@ "valid_max":"", "valid_min":"" }, + "phydiazos":{ + "cell_measures":"", + "cell_methods":"area: mean where sea time: mean", + "comment":"carbon concentration from the diazotrophic phytoplankton component alone", + "dimensions":"longitude latitude time", + "frequency":"mon", + "long_name":"Surface Mole Concentration of Diazotrophs Expressed as Carbon in Sea Water", + "ok_max_mean_abs":"", + "ok_min_mean_abs":"", + "out_name":"phydiazos", + "positive":"", + "standard_name":"mole_concentration_of_diazotrophs_expressed_as_carbon_in_sea_water", + "type":"real", + "units":"mol m-3", + "valid_max":"", + "valid_min":"" + }, "phyfe":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", @@ -3232,9 +3470,9 @@ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", "comment":"sum of phytoplankton iron component concentrations", - "dimensions":"longitude latitude time depth0m", + "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Surface Mole Concentration of Total Phytoplankton expressed as Iron in Sea Water", + "long_name":"Surface Mole Concentration of Total Phytoplankton Expressed as Iron in Sea Water", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"phyfeos", @@ -3251,7 +3489,7 @@ "comment":"carbon concentration from additional phytoplankton component alone", "dimensions":"longitude latitude olevel time", "frequency":"mon", - "long_name":"Mole Concentration of Miscellaneous Phytoplankton expressed as Carbon in sea water", + "long_name":"Mole Concentration of Miscellaneous Phytoplankton Expressed as Carbon in Sea Water", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"phymisc", @@ -3262,6 +3500,23 @@ "valid_max":"", "valid_min":"" }, + "phymiscos":{ + "cell_measures":"", + "cell_methods":"area: mean where sea time: mean", + "comment":"carbon concentration from additional phytoplankton component alone", + "dimensions":"longitude latitude time", + "frequency":"mon", + "long_name":"Surface Mole Concentration of Miscellaneous Phytoplankton Expressed as Carbon in Sea Water", + "ok_max_mean_abs":"", + "ok_min_mean_abs":"", + "out_name":"phymiscos", + "positive":"", + "standard_name":"mole_concentration_of_miscellaneous_phytoplankton_expressed_as_carbon_in_sea_water", + "type":"real", + "units":"mol m-3", + "valid_max":"", + "valid_min":"" + }, "phyn":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", @@ -3283,9 +3538,9 @@ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", "comment":"sum of phytoplankton nitrogen component concentrations", - "dimensions":"longitude latitude time depth0m", + "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Surface Mole Concentration of Phytoplankton Nitrogen in sea water", + "long_name":"Surface Mole Concentration of Phytoplankton Nitrogen in Sea Water", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"phynos", @@ -3319,7 +3574,7 @@ "comment":"carbon concentration from the picophytoplankton (<2 um) component alone", "dimensions":"longitude latitude olevel time", "frequency":"mon", - "long_name":"Mole Concentration of Picophytoplankton expressed as Carbon in sea water", + "long_name":"Mole Concentration of Picophytoplankton Expressed as Carbon in Sea Water", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"phypico", @@ -3330,13 +3585,30 @@ "valid_max":"", "valid_min":"" }, + "phypicoos":{ + "cell_measures":"", + "cell_methods":"area: mean where sea time: mean", + "comment":"carbon concentration from the picophytoplankton (<2 um) component alone", + "dimensions":"longitude latitude time", + "frequency":"mon", + "long_name":"Surface Mole Concentration of Picophytoplankton Expressed as Carbon in Sea Water", + "ok_max_mean_abs":"", + "ok_min_mean_abs":"", + "out_name":"phypicoos", + "positive":"", + "standard_name":"mole_concentration_of_picophytoplankton_expressed_as_carbon_in_sea_water", + "type":"real", + "units":"mol m-3", + "valid_max":"", + "valid_min":"" + }, "phypos":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", "comment":"sum of phytoplankton phosphorus components", - "dimensions":"longitude latitude time depth0m", + "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Surface Mole Concentration of Total Phytoplankton expressed as Phosphorus in sea water", + "long_name":"Surface Mole Concentration of Total Phytoplankton Expressed as Phosphorus in Sea Water", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"phypos", @@ -3368,9 +3640,9 @@ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", "comment":"sum of phytoplankton silica component concentrations", - "dimensions":"longitude latitude time depth0m", + "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Surface Mole Concentration of Total Phytoplankton expressed as Silicon in sea water", + "long_name":"Surface Mole Concentration of Total Phytoplankton Expressed as Silicon in Sea Water", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"physios", @@ -3381,33 +3653,33 @@ "valid_max":"", "valid_min":"" }, - "pnitrate":{ + "po4":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"Primary (organic carbon) production by phytoplankton due to nitrate uptake alone", - "dimensions":"longitude latitude time depth0m", + "comment":"Mole concentration means number of moles per unit volume, also called 'molarity', and is used in the construction 'mole_concentration_of_X_in_Y', where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. 'Dissolved inorganic phosphorus' means the sum of all inorganic phosphorus in solution (including phosphate, hydrogen phosphate, dihydrogen phosphate, and phosphoric acid).", + "dimensions":"longitude latitude olevel time", "frequency":"mon", - "long_name":"Primary Carbon Production by Phytoplankton due to Nitrate Uptake Alone", + "long_name":"Total Dissolved Inorganic Phosphorus Concentration", "ok_max_mean_abs":"", "ok_min_mean_abs":"", - "out_name":"pnitrate", + "out_name":"po4", "positive":"", - "standard_name":"tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_nitrate_utilization", + "standard_name":"mole_concentration_of_dissolved_inorganic_phosphorus_in_sea_water", "type":"real", - "units":"mol m-3 s-1", + "units":"mol m-3", "valid_max":"", "valid_min":"" }, - "po4":{ + "po4os":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", - "dimensions":"longitude latitude olevel time", + "comment":"Mole concentration means number of moles per unit volume, also called 'molarity', and is used in the construction 'mole_concentration_of_X_in_Y', where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. 'Dissolved inorganic phosphorus' means the sum of all inorganic phosphorus in solution (including phosphate, hydrogen phosphate, dihydrogen phosphate, and phosphoric acid).", + "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Total Dissolved Inorganic Phosphorus Concentration", + "long_name":"Surface Total Dissolved Inorganic Phosphorus Concentration", "ok_max_mean_abs":"", "ok_min_mean_abs":"", - "out_name":"po4", + "out_name":"po4os", "positive":"", "standard_name":"mole_concentration_of_dissolved_inorganic_phosphorus_in_sea_water", "type":"real", @@ -3436,9 +3708,9 @@ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", "comment":"sum of particulate organic nitrogen component concentrations", - "dimensions":"longitude latitude time depth0m", + "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Surface Mole Concentration of Particulate Organic Matter expressed as Nitrogen in sea water", + "long_name":"Surface Mole Concentration of Particulate Organic Matter Expressed as Nitrogen in Sea Water", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"ponos", @@ -3470,9 +3742,9 @@ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", "comment":"sum of particulate organic phosphorus component concentrations", - "dimensions":"longitude latitude time depth0m", + "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Surface Mole Concentration of Particulate Organic Matter expressed as Phosphorus in sea water", + "long_name":"Surface Mole Concentration of Particulate Organic Matter Expressed as Phosphorus in Sea Water", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"popos", @@ -3489,7 +3761,7 @@ "comment":"total primary (organic carbon) production by phytoplankton", "dimensions":"longitude latitude olevel time", "frequency":"mon", - "long_name":"Primary Carbon Production by Total Phytoplankton", + "long_name":"Primary Carbon Production by Phytoplankton", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"pp", @@ -3500,10 +3772,27 @@ "valid_max":"", "valid_min":"" }, + "ppos":{ + "cell_measures":"", + "cell_methods":"area: mean where sea time: mean", + "comment":"total primary (organic carbon) production by phytoplankton", + "dimensions":"longitude latitude time depth0m", + "frequency":"mon", + "long_name":"Primary Carbon Production by Phytoplankton", + "ok_max_mean_abs":"", + "ok_min_mean_abs":"", + "out_name":"ppos", + "positive":"", + "standard_name":"tendency_of_mole_concentration_of_particulate_organic_matter_expressed_as_carbon_in_sea_water_due_to_net_primary_production", + "type":"real", + "units":"mol m-3 s-1", + "valid_max":"", + "valid_min":"" + }, "prra":{ "cell_measures":"", "cell_methods":"area: mean where ice_free_sea over sea time: mean", - "comment":"", + "comment":"In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics.", "dimensions":"longitude latitude time", "frequency":"mon", "long_name":"Rainfall Flux where Ice Free Ocean over Sea", @@ -3520,7 +3809,7 @@ "prsn":{ "cell_measures":"", "cell_methods":"area: mean where ice_free_sea over sea time: mean", - "comment":"at surface; includes precipitation of all forms of water in the solid phase", + "comment":"At surface; includes precipitation of all forms of water in the solid phase", "dimensions":"longitude latitude time", "frequency":"mon", "long_name":"Snowfall Flux where Ice Free Ocean over Sea", @@ -3537,7 +3826,7 @@ "pso":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"The surface called 'surface' means the lower boundary of the atmosphere. 'Sea water pressure' is the pressure that exists in the medium of sea water. It includes the pressure due to overlying sea water, sea ice, air and any other medium that may be present.", "dimensions":"longitude latitude time", "frequency":"mon", "long_name":"Sea Water Pressure at Sea Water Surface", @@ -3571,7 +3860,7 @@ "rsdo":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"Downwelling radiation is radiation from above. It does not mean 'net downward'. When thought of as being incident on a surface, a radiative flux is sometimes called 'irradiance'. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called 'vector irradiance'. In accordance with common usage in geophysical disciplines, 'flux' implies per unit area, called 'flux density' in physics. 'shortwave' means shortwave radiation.", "dimensions":"longitude latitude olevel time", "frequency":"mon", "long_name":"Downwelling Shortwave Radiation in Sea Water", @@ -3605,10 +3894,10 @@ "sf6":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"Mole concentration means number of moles per unit volume, also called 'molarity', and is used in the construction 'mole_concentration_of_X_in_Y', where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. The chemical formula of sulfur hexafluoride is SF6.", "dimensions":"longitude latitude olevel time", "frequency":"mon", - "long_name":"Moles Per Unit Mass of SF6 in sea water", + "long_name":"Mole Concentration of SF6 in sea water", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sf6", @@ -3656,7 +3945,7 @@ "si":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"Mole concentration means number of moles per unit volume, also called 'molarity', and is used in the construction 'mole_concentration_of_X_in_Y', where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. 'Dissolved inorganic silicon' means the sum of all inorganic silicon in solution (including silicic acid and its first dissociated anion SiO(OH)3-).", "dimensions":"longitude latitude olevel time", "frequency":"mon", "long_name":"Total Dissolved Inorganic Silicon Concentration", @@ -3673,8 +3962,8 @@ "sios":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", - "dimensions":"longitude latitude time depth0m", + "comment":"Mole concentration means number of moles per unit volume, also called 'molarity', and is used in the construction 'mole_concentration_of_X_in_Y', where X is a material constituent of Y. A chemical or biological species denoted by X may be described by a single term such as 'nitrogen' or a phrase such as 'nox_expressed_as_nitrogen'. 'Dissolved inorganic silicon' means the sum of all inorganic silicon in solution (including silicic acid and its first dissociated anion SiO(OH)3-).", + "dimensions":"longitude latitude time", "frequency":"mon", "long_name":"Surface Total Dissolved Inorganic Silicon Concentration", "ok_max_mean_abs":"", @@ -3689,11 +3978,11 @@ }, "sltovgyre":{ "cell_measures":"", - "cell_methods":"longitude: mean time: mean", + "cell_methods":"longitude: sum (comment: basin sum [along zig-zag grid path]) depth: sum time: mean", "comment":"From all advective mass transport processes, resolved and parameterized.", "dimensions":"latitude basin time", "frequency":"mon", - "long_name":"Northward Ocean Salt Transport due to Gyre", + "long_name":"Northward Ocean Salt Transport Due to Gyre", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sltovgyre", @@ -3706,11 +3995,11 @@ }, "sltovovrt":{ "cell_measures":"", - "cell_methods":"longitude: mean time: mean", + "cell_methods":"longitude: sum (comment: basin sum [along zig-zag grid path]) depth: sum time: mean", "comment":"From all advective mass transport processes, resolved and parameterized.", "dimensions":"latitude basin time", "frequency":"mon", - "long_name":"Northward Ocean Salt Transport due to Overturning", + "long_name":"Northward Ocean Salt Transport Due to Overturning", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sltovovrt", @@ -3724,7 +4013,7 @@ "so":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"Sea water salinity is the salt content of sea water, often on the Practical Salinity Scale of 1978. However, the unqualified term 'salinity' is generic and does not necessarily imply any particular method of calculation. The units of salinity are dimensionless and the units attribute should normally be given as 1e-3 or 0.001 i.e. parts per thousand. ", "dimensions":"longitude latitude olevel time", "frequency":"mon", "long_name":"Sea Water Salinity", @@ -3744,7 +4033,7 @@ "comment":"Model prognostic salinity at bottom-most model grid cell", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"sea water salinity at sea floor", + "long_name":"Sea Water Salinity at Sea Floor", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sob", @@ -3758,7 +4047,7 @@ "soga":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"Sea water salinity is the salt content of sea water, often on the Practical Salinity Scale of 1978. However, the unqualified term 'salinity' is generic and does not necessarily imply any particular method of calculation. The units of salinity are dimensionless and the units attribute should normally be given as 1e-3 or 0.001 i.e. parts per thousand. ", "dimensions":"time", "frequency":"mon", "long_name":"Global Mean Sea Water Salinity", @@ -3775,7 +4064,7 @@ "sos":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"Sea water salinity is the salt content of sea water, often on the Practical Salinity Scale of 1978. However, the unqualified term 'salinity' is generic and does not necessarily imply any particular method of calculation. The units of salinity are dimensionless and the units attribute should normally be given as 1e-3 or 0.001 i.e. parts per thousand. ", "dimensions":"longitude latitude time", "frequency":"mon", "long_name":"Sea Surface Salinity", @@ -3792,7 +4081,7 @@ "sosga":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"Sea water salinity is the salt content of sea water, often on the Practical Salinity Scale of 1978. However, the unqualified term 'salinity' is generic and does not necessarily imply any particular method of calculation. The units of salinity are dimensionless and the units attribute should normally be given as 1e-3 or 0.001 i.e. parts per thousand. ", "dimensions":"time", "frequency":"mon", "long_name":"Global Average Sea Surface Salinity", @@ -3809,7 +4098,7 @@ "sossq":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"Sea water salinity is the salt content of sea water, often on the Practical Salinity Scale of 1978. However, the unqualified term 'salinity' is generic and does not necessarily imply any particular method of calculation. The units of salinity are dimensionless and the units attribute should normally be given as 1e-3 or 0.001 i.e. parts per thousand. ", "dimensions":"longitude latitude time", "frequency":"mon", "long_name":"Square of Sea Surface Salinity", @@ -3826,7 +4115,7 @@ "spco2":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"The surface called 'surface' means the lower boundary of the atmosphere. The partial pressure of a dissolved gas in sea water is the partial pressure in air with which it would be in equilibrium. The partial pressure of a gaseous constituent of air is the pressure which it alone would exert with unchanged temperature and number of moles per unit volume. The chemical formula for carbon dioxide is CO2.", "dimensions":"longitude latitude time depth0m", "frequency":"mon", "long_name":"Surface Aqueous Partial Pressure of CO2", @@ -3843,7 +4132,7 @@ "spco2abio":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"The surface called 'surface' means the lower boundary of the atmosphere. The chemical formula for carbon dioxide is CO2. In ocean biogeochemistry models, an 'abiotic analogue' is used to simulate the effect on a modelled variable when biological effects on ocean carbon concentration and alkalinity are ignored. The partial pressure of a gaseous constituent of air is the pressure which it alone would exert with unchanged temperature and number of moles per unit volume. The partial pressure of a dissolved gas in sea water is the partial pressure in air with which it would be in equilibrium. The partial pressure difference between sea water and air is positive when the partial pressure of the dissolved gas in sea water is greater than the partial pressure in air.", "dimensions":"longitude latitude time depth0m", "frequency":"mon", "long_name":"Abiotic Surface Aqueous Partial Pressure of CO2", @@ -3851,7 +4140,7 @@ "ok_min_mean_abs":"", "out_name":"spco2abio", "positive":"", - "standard_name":"surface_partial_pressure_of_carbon_dioxide_abiotic_analogue_in_sea_water", + "standard_name":"surface_carbon_dioxide_abiotic_analogue_partial_pressure_difference_between_sea_water_and_air", "type":"real", "units":"Pa", "valid_max":"", @@ -3860,7 +4149,7 @@ "spco2nat":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"The surface called 'surface' means the lower boundary of the atmosphere. The chemical formula for carbon dioxide is CO2. In ocean biogeochemistry models, a 'natural analogue' is used to simulate the effect on a modelled variable of imposing preindustrial atmospheric carbon dioxide concentrations, even when the model as a whole may be subjected to varying forcings. The partial pressure of a gaseous constituent of air is the pressure which it alone would exert with unchanged temperature and number of moles per unit volume. The partial pressure of a dissolved gas in sea water is the partial pressure in air with which it would be in equilibrium. The partial pressure difference between sea water and air is positive when the partial pressure of the dissolved gas in sea water is greater than the partial pressure in air.", "dimensions":"longitude latitude time depth0m", "frequency":"mon", "long_name":"Natural Surface Aqueous Partial Pressure of CO2", @@ -3868,7 +4157,7 @@ "ok_min_mean_abs":"", "out_name":"spco2nat", "positive":"", - "standard_name":"surface_partial_pressure_of_carbon_dioxide_natural_analogue_in_sea_water", + "standard_name":"surface_carbon_dioxide_natural_analogue_partial_pressure_difference_between_sea_water_and_air", "type":"real", "units":"Pa", "valid_max":"", @@ -3912,7 +4201,7 @@ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", "comment":"total alkalinity equivalent concentration (including carbonate, borate, phosphorus, silicon, and nitrogen components) at preindustrial atmospheric xCO2", - "dimensions":"longitude latitude time depth0m", + "dimensions":"longitude latitude time", "frequency":"mon", "long_name":"Surface Natural Total Alkalinity", "ok_max_mean_abs":"", @@ -3925,6 +4214,23 @@ "valid_max":"", "valid_min":"" }, + "talkos":{ + "cell_measures":"", + "cell_methods":"area: mean where sea time: mean", + "comment":"total alkalinity equivalent concentration (including carbonate, borate, phosphorus, silicon, and nitrogen components)", + "dimensions":"longitude latitude time", + "frequency":"mon", + "long_name":"Surface Total Alkalinity", + "ok_max_mean_abs":"", + "ok_min_mean_abs":"", + "out_name":"talkos", + "positive":"", + "standard_name":"sea_water_alkalinity_expressed_as_mole_equivalent", + "type":"real", + "units":"mol m-3", + "valid_max":"", + "valid_min":"" + }, "tauucorr":{ "cell_measures":"", "cell_methods":"time: mean", @@ -4030,7 +4336,7 @@ "thkcello":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", - "comment":"", + "comment":"'Thickness' means the vertical extent of a layer. 'Cell' refers to a model grid-cell.", "dimensions":"longitude latitude olevel time", "frequency":"mon", "long_name":"Ocean Model Cell Thickness", @@ -4166,7 +4472,7 @@ "vo":{ "cell_measures":"", "cell_methods":"time: mean", - "comment":"Prognostic x-ward velocity component resolved by the model.", + "comment":"Prognostic y-ward velocity component resolved by the model.", "dimensions":"longitude latitude olevel time", "frequency":"mon", "long_name":"Sea Water Y Velocity", @@ -4185,7 +4491,7 @@ "cell_methods":"area: mean where sea time: mean", "comment":"grid-cell volume ca. 2000.", "dimensions":"longitude latitude olevel time", - "frequency":"fx", + "frequency":"mon", "long_name":"Ocean Grid-Cell Volume", "ok_max_mean_abs":"", "ok_min_mean_abs":"", @@ -4254,7 +4560,7 @@ "comment":"zero for models using real water fluxes.", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Virtual Salt Flux into Sea Water due to Evaporation", + "long_name":"Virtual Salt Flux into Sea Water Due to Evaporation", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"vsfevap", @@ -4271,7 +4577,7 @@ "comment":"zero for models using real water fluxes.", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Virtual Salt Flux into Sea Water due to Rainfall", + "long_name":"Virtual Salt Flux into Sea Water Due to Rainfall", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"vsfpr", @@ -4288,7 +4594,7 @@ "comment":"zero for models using real water fluxes.", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Virtual Salt Flux into Sea Water From Rivers", + "long_name":"Virtual Salt Flux into Sea Water from Rivers", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"vsfriver", @@ -4305,7 +4611,7 @@ "comment":"This variable measures the virtual salt flux into sea water due to the melting of sea ice. It is set to zero in models which receive a real water flux.", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Virtual Salt Flux into Sea Water due to Sea Ice Thermodynamics", + "long_name":"Virtual Salt Flux into Sea Water Due to Sea Ice Thermodynamics", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"vsfsit", @@ -4387,10 +4693,10 @@ "wo":{ "cell_measures":"", "cell_methods":"time: mean", - "comment":"", + "comment":"A velocity is a vector quantity. 'Upward' indicates a vector component which is positive when directed upward (negative downward).", "dimensions":"longitude latitude olevel time", "frequency":"mon", - "long_name":"Sea Water Z Velocity", + "long_name":"Sea Water Vertical Velocity", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"wo", @@ -4422,7 +4728,7 @@ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", "comment":"Depth below geoid", - "dimensions":"longitude latitude olevel time", + "dimensions":"longitude latitude olevhalf time", "frequency":"mon", "long_name":"Depth Below Geoid of Interfaces Between Ocean Layers", "ok_max_mean_abs":"", @@ -4441,7 +4747,7 @@ "comment":"carbon concentration from mesozooplankton (20-200 um) component alone", "dimensions":"longitude latitude olevel time", "frequency":"mon", - "long_name":"Mole Concentration of Mesozooplankton expressed as Carbon in sea water", + "long_name":"Mole Concentration of Mesozooplankton Expressed as Carbon in Sea Water", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"zmeso", @@ -4452,13 +4758,30 @@ "valid_max":"", "valid_min":"" }, + "zmesoos":{ + "cell_measures":"", + "cell_methods":"area: mean where sea time: mean", + "comment":"carbon concentration from mesozooplankton (20-200 um) component alone", + "dimensions":"longitude latitude time", + "frequency":"mon", + "long_name":"Surface Mole Concentration of Mesozooplankton Expressed as Carbon in Sea Water", + "ok_max_mean_abs":"", + "ok_min_mean_abs":"", + "out_name":"zmesoos", + "positive":"", + "standard_name":"mole_concentration_of_mesozooplankton_expressed_as_carbon_in_sea_water", + "type":"real", + "units":"mol m-3", + "valid_max":"", + "valid_min":"" + }, "zmicro":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", "comment":"carbon concentration from the microzooplankton (<20 um) component alone", "dimensions":"longitude latitude olevel time", "frequency":"mon", - "long_name":"Mole Concentration of Microzooplankton expressed as Carbon in sea water", + "long_name":"Mole Concentration of Microzooplankton Expressed as Carbon in Sea Water", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"zmicro", @@ -4469,13 +4792,30 @@ "valid_max":"", "valid_min":"" }, + "zmicroos":{ + "cell_measures":"", + "cell_methods":"area: mean where sea time: mean", + "comment":"carbon concentration from the microzooplankton (<20 um) component alone", + "dimensions":"longitude latitude time", + "frequency":"mon", + "long_name":"Surface Mole Concentration of Microzooplankton Expressed as Carbon in Sea Water", + "ok_max_mean_abs":"", + "ok_min_mean_abs":"", + "out_name":"zmicroos", + "positive":"", + "standard_name":"mole_concentration_of_microzooplankton_expressed_as_carbon_in_sea_water", + "type":"real", + "units":"mol m-3", + "valid_max":"", + "valid_min":"" + }, "zmisc":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", "comment":"carbon from additional zooplankton component concentrations alone (e.g. Micro, meso). Since the models all have different numbers of components, this variable has been included to provide a check for intercomparison between models since some phytoplankton groups are supersets.", "dimensions":"longitude latitude olevel time", "frequency":"mon", - "long_name":"Mole Concetration of Other Zooplankton expressed as Carbon in sea water", + "long_name":"Mole Concentration of Other Zooplankton Expressed as Carbon in Sea Water", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"zmisc", @@ -4486,6 +4826,23 @@ "valid_max":"", "valid_min":"" }, + "zmiscos":{ + "cell_measures":"", + "cell_methods":"area: mean where sea time: mean", + "comment":"carbon from additional zooplankton component concentrations alone (e.g. Micro, meso). Since the models all have different numbers of components, this variable has been included to provide a check for intercomparison between models since some phytoplankton groups are supersets.", + "dimensions":"longitude latitude time", + "frequency":"mon", + "long_name":"Surface Mole Concentration of Other Zooplankton Expressed as Carbon in Sea Water", + "ok_max_mean_abs":"", + "ok_min_mean_abs":"", + "out_name":"zmiscos", + "positive":"", + "standard_name":"mole_concentration_of_miscellaneous_zooplankton_expressed_as_carbon_in_sea_water", + "type":"real", + "units":"mol m-3", + "valid_max":"", + "valid_min":"" + }, "zo2min":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", @@ -4520,6 +4877,23 @@ "valid_max":"", "valid_min":"" }, + "zoocos":{ + "cell_measures":"", + "cell_methods":"area: mean where sea time: mean", + "comment":"sum of zooplankton carbon component concentrations", + "dimensions":"longitude latitude time", + "frequency":"mon", + "long_name":"Surface Zooplankton Carbon Concentration", + "ok_max_mean_abs":"", + "ok_min_mean_abs":"", + "out_name":"zoocos", + "positive":"", + "standard_name":"mole_concentration_of_zooplankton_expressed_as_carbon_in_sea_water", + "type":"real", + "units":"mol m-3", + "valid_max":"", + "valid_min":"" + }, "zos":{ "cell_measures":"", "cell_methods":"area: mean where sea time: mean", diff --git a/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_SImon.json b/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_SImon.json index bd5e3733a2..43ccac6ecd 100644 --- a/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_SImon.json +++ b/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_SImon.json @@ -1,27 +1,27 @@ { "Header":{ - "#dataRequest_specs_version":"01.00.21", + "#dataRequest_specs_version":"01.00.29", "#mip_era":"CMIP6", "Conventions":"CF-1.7 ODS-2.1", "approx_interval":"30.00000", - "cmor_version":"3.2", + "cmor_version":"3.4", "data_specs_version":"2.1.0", "generic_levels":"", "int_missing_value":"-2147483648", "missing_value":"1e20", "product":"observations", "realm":"seaIce", - "table_date":"07 March 2018", + "table_date":"11 April 2019", "table_id":"Table obs4MIPs_SImon" }, "variable_entry":{ "sfdsi":{ "cell_measures":"", - "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc or siconca)", + "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc)", "comment":"This field is physical, and it arises since sea ice has a nonzero salt content, so it exchanges salt with the liquid ocean upon melting and freezing.", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Salt flux from sea ice", + "long_name":"Downward Sea Ice Basal Salt Flux", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sfdsi", @@ -34,11 +34,11 @@ }, "siage":{ "cell_measures":"", - "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc or siconca)", + "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc)", "comment":"Age of sea ice", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Age of sea ice", + "long_name":"Age of Sea Ice", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"siage", @@ -55,7 +55,7 @@ "comment":"net (sum of transport in all directions) sea ice area transport through the following four passages, positive into the Arctic Ocean 1. Fram Strait = (11.5W,81.3N to (10.5E,79.6N) 2. Canadian Archipelago = (128.2W,70.6N) to (59.3W,82.1N) 3. Barents opening = (16.8E,76.5N) to (19.2E,70.2N) 4. Bering Strait = (171W,66.2N) to (166W,65N)", "dimensions":"siline time", "frequency":"mon", - "long_name":"Sea ice area flux through straits", + "long_name":"Sea-Ice Area Flux Through Straits", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"siareaacrossline", @@ -72,7 +72,7 @@ "comment":"total area of sea ice in the Northern hemisphere", "dimensions":"time", "frequency":"mon", - "long_name":"Sea ice area North", + "long_name":"Sea-Ice Area North", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"siarean", @@ -89,7 +89,7 @@ "comment":"total area of sea ice in the Southern hemisphere", "dimensions":"time", "frequency":"mon", - "long_name":"Sea ice area South", + "long_name":"Sea-Ice Area South", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"siareas", @@ -102,11 +102,11 @@ }, "sicompstren":{ "cell_measures":"", - "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc or siconca)", - "comment":"Computed strength of the ice pack, defined as the energy (J m-2) dissipated per unit area removed from the ice pack under compression, and assumed proportional to the change in potential energy caused by ridging. For Hibler-type models, this is P (= P*hexp(-C(1-A)))", + "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc)", + "comment":"Computed strength of the ice pack, defined as the energy (J m-2) dissipated per unit area removed from the ice pack under compression, and assumed proportional to the change in potential energy caused by ridging. For Hibler-type models, this is P (= P*h exp(-C(1-A)) where P* is compressive strength, h ice thickness, A compactness and C strength reduction constant).", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Compressive sea ice strength", + "long_name":"Compressive Sea Ice Strength", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sicompstren", @@ -123,7 +123,7 @@ "comment":"Area fraction of grid cell covered by sea ice", "dimensions":"longitude latitude time typesi", "frequency":"mon", - "long_name":"Sea Ice Area Fraction (Ocean Grid)", + "long_name":"Sea-ice Area Percentage (Ocean Grid)", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"siconc", @@ -140,7 +140,7 @@ "comment":"Area fraction of grid cell covered by sea ice", "dimensions":"longitude latitude time typesi", "frequency":"mon", - "long_name":"Sea Ice Area Fraction (Atmospheric Grid)", + "long_name":"Sea-ice Area Percentage (Atmospheric Grid)", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"siconca", @@ -153,11 +153,11 @@ }, "sidconcdyn":{ "cell_measures":"", - "cell_methods":"area: time: mean", + "cell_methods":"area: mean where sea time: mean", "comment":"Total change in sea-ice area fraction through dynamics-related processes (advection, divergence...)", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"sea-ice area fraction change from dynamics", + "long_name":"Sea-ice Area Percentage Tendency Due to Dynamics", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sidconcdyn", @@ -170,11 +170,11 @@ }, "sidconcth":{ "cell_measures":"", - "cell_methods":"area: time: mean", + "cell_methods":"area: mean where sea time: mean", "comment":"Total change in sea-ice area fraction through thermodynamic processes", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"sea-ice area fraction change from thermodynamics", + "long_name":"Sea-ice Area Percentage Tendency Due to Thermodynamics", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sidconcth", @@ -191,7 +191,7 @@ "comment":"Divergence of sea-ice velocity field (first shear strain invariant)", "dimensions":"longitude latitude time1", "frequency":"monPt", - "long_name":"Divergence of the sea-ice velocity field", + "long_name":"Divergence of the Sea-Ice Velocity Field", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sidivvel", @@ -204,16 +204,16 @@ }, "sidmassdyn":{ "cell_measures":"", - "cell_methods":"area: time: mean", + "cell_methods":"area: mean where sea time: mean", "comment":"Total change in sea-ice mass through dynamics-related processes (advection,...) divided by grid-cell area", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"sea-ice mass change from dynamics", + "long_name":"Sea-Ice Mass Change from Dynamics", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sidmassdyn", "positive":"", - "standard_name":"tendency_of_sea_ice_amount_due_to_dynamics", + "standard_name":"tendency_of_sea_ice_amount_due_to_sea_ice_dynamics", "type":"real", "units":"kg m-2 s-1", "valid_max":"", @@ -221,16 +221,16 @@ }, "sidmassevapsubl":{ "cell_measures":"", - "cell_methods":"area: time: mean", + "cell_methods":"area: mean where sea time: mean", "comment":"The rate of change of sea-ice mass change through evaporation and sublimation divided by grid-cell area", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"sea-ice mass change through evaporation and sublimation", + "long_name":"Sea-Ice Mass Change Through Evaporation and Sublimation", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sidmassevapsubl", "positive":"up", - "standard_name":"water_evaporation_flux", + "standard_name":"water_evapotranspiration_flux", "type":"real", "units":"kg m-2 s-1", "valid_max":"", @@ -238,11 +238,11 @@ }, "sidmassgrowthbot":{ "cell_measures":"", - "cell_methods":"area: time: mean", + "cell_methods":"area: mean where sea time: mean", "comment":"The rate of change of sea ice mass due to vertical growth of existing sea ice at its base divided by grid-cell area.", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"sea-ice mass change through basal growth", + "long_name":"Sea-Ice Mass Change Through Basal Growth", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sidmassgrowthbot", @@ -255,16 +255,16 @@ }, "sidmassgrowthwat":{ "cell_measures":"", - "cell_methods":"area: time: mean", + "cell_methods":"area: mean where sea time: mean", "comment":"The rate of change of sea ice mass due to sea ice formation in supercooled water (often through frazil formation) divided by grid-cell area. Together, sidmassgrowthwat and sidmassgrowthbot should give total ice growth", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"sea-ice mass change through growth in supercooled open water (aka frazil)", + "long_name":"Sea-Ice Mass Change Through Growth in Supercooled Open Water (Frazil)", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sidmassgrowthwat", "positive":"", - "standard_name":"tendency_of_sea_ice_amount_due_to_freezing_in_open_water", + "standard_name":"tendency_of_sea_ice_amount_due_to_frazil_ice_accumulation_in_leads", "type":"real", "units":"kg m-2 s-1", "valid_max":"", @@ -272,11 +272,11 @@ }, "sidmasslat":{ "cell_measures":"", - "cell_methods":"area: time: mean", + "cell_methods":"area: mean where sea time: mean", "comment":"The rate of change of sea ice mass through lateral melting divided by grid-cell area (report 0 if not explicitly calculated thermodynamically)", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Lateral sea ice melt rate", + "long_name":"Lateral Sea Ice Melt Rate", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sidmasslat", @@ -289,11 +289,11 @@ }, "sidmassmeltbot":{ "cell_measures":"", - "cell_methods":"area: time: mean", + "cell_methods":"area: mean where sea time: mean", "comment":"The rate of change of sea ice mass through melting at the ice bottom divided by grid-cell area", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"sea-ice mass change through bottom melting", + "long_name":"Sea-Ice Mass Change Through Bottom Melting", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sidmassmeltbot", @@ -306,11 +306,11 @@ }, "sidmassmelttop":{ "cell_measures":"", - "cell_methods":"area: time: mean", + "cell_methods":"area: mean where sea time: mean", "comment":"The rate of change of sea ice mass through melting at the ice surface divided by grid-cell area", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"sea-ice mass change through surface melting", + "long_name":"Sea-Ice Mass Change Through Surface Melting", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sidmassmelttop", @@ -323,16 +323,16 @@ }, "sidmasssi":{ "cell_measures":"", - "cell_methods":"area: time: mean", + "cell_methods":"area: mean where sea time: mean", "comment":"The rate of change of sea ice mass due to transformation of snow to sea ice divided by grid-cell area", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"sea-ice mass change through snow-to-ice conversion", + "long_name":"Sea-Ice Mass Change Through Snow-to-Ice Conversion", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sidmasssi", "positive":"", - "standard_name":"tendency_of_sea_ice_amount_due_to_snow_conversion", + "standard_name":"tendency_of_sea_ice_amount_due_to_conversion_of_snow_to_sea_ice", "type":"real", "units":"kg m-2 s-1", "valid_max":"", @@ -340,16 +340,16 @@ }, "sidmassth":{ "cell_measures":"", - "cell_methods":"area: time: mean", + "cell_methods":"area: mean where sea time: mean", "comment":"Total change in sea-ice mass from thermodynamic processes divided by grid-cell area", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"sea-ice mass change from thermodynamics", + "long_name":"Sea-Ice Mass Change from Thermodynamics", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sidmassth", "positive":"", - "standard_name":"tendency_of_sea_ice_amount_due_to_thermodynamics", + "standard_name":"tendency_of_sea_ice_amount_due_to_sea_ice_thermodynamics", "type":"real", "units":"kg m-2 s-1", "valid_max":"", @@ -361,7 +361,7 @@ "comment":"Includes transport of both sea ice and snow by advection", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"X-component of sea-ice mass transport", + "long_name":"X-Component of Sea-Ice Mass Transport", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sidmasstranx", @@ -378,7 +378,7 @@ "comment":"Includes transport of both sea ice and snow by advection", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Y-component of sea-ice mass transport", + "long_name":"Y-Component of Sea-Ice Mass Transport", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sidmasstrany", @@ -391,16 +391,16 @@ }, "sidragbot":{ "cell_measures":"", - "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc or siconca)", + "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc)", "comment":"Oceanic drag coefficient that is used to calculate the oceanic momentum drag on sea ice", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Ocean drag coefficient", + "long_name":"Ocean Drag Coefficient", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sidragbot", "positive":"", - "standard_name":"surface_drag_coefficient_for_momentum_in_water", + "standard_name":"sea_ice_basal_drag_coefficient_for_momentum_in_sea_water", "type":"real", "units":"1", "valid_max":"", @@ -408,11 +408,11 @@ }, "sidragtop":{ "cell_measures":"", - "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc or siconca)", + "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc)", "comment":"Atmospheric drag coefficient that is used to calculate the atmospheric momentum drag on sea ice", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Atmospheric drag coefficient", + "long_name":"Atmospheric Drag Coefficient", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sidragtop", @@ -429,7 +429,7 @@ "comment":"Total area of all Northern-Hemisphere grid cells that are covered by at least 15 % areal fraction of sea ice", "dimensions":"time", "frequency":"mon", - "long_name":"Sea ice extent North", + "long_name":"Sea-Ice Extent North", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"siextentn", @@ -446,7 +446,7 @@ "comment":"Total area of all Southern-Hemisphere grid cells that are covered by at least 15 % areal fraction of sea ice", "dimensions":"time", "frequency":"mon", - "long_name":"Sea ice extent South", + "long_name":"Sea-Ice Extent South", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"siextents", @@ -459,11 +459,11 @@ }, "sifb":{ "cell_measures":"", - "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc or siconca)", + "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc)", "comment":"Mean height of sea-ice surface (=snow-ice interface when snow covered) above sea level", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Sea-ice freeboard", + "long_name":"Sea-Ice Freeboard", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sifb", @@ -476,16 +476,16 @@ }, "siflcondbot":{ "cell_measures":"", - "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc or siconca)", + "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc)", "comment":"the net heat conduction flux at the ice base", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Net conductive heat fluxes in ice at the bottom", + "long_name":"Net Conductive Heat Fluxes in Ice at the Bottom", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"siflcondbot", "positive":"down", - "standard_name":"conductive_heat_flux_at_sea_ice_bottom", + "standard_name":"basal_downward_heat_flux_in_sea_ice", "type":"real", "units":"W m-2", "valid_max":"", @@ -493,16 +493,16 @@ }, "siflcondtop":{ "cell_measures":"", - "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc or siconca)", + "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc)", "comment":"the net heat conduction flux at the ice surface", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Net conductive heat flux in ice at the surface", + "long_name":"Net Conductive Heat Flux in Ice at the Surface", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"siflcondtop", "positive":"down", - "standard_name":"conductive_heat_flux_at_sea_ice_surface", + "standard_name":"surface_downward_sensible_heat_flux", "type":"real", "units":"W m-2", "valid_max":"", @@ -510,16 +510,16 @@ }, "siflfwbot":{ "cell_measures":"", - "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc or siconca)", + "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc)", "comment":"Total flux of fresh water from water into sea ice divided by grid-cell area; This flux is negative during ice growth (liquid water mass decreases, hence upward flux of freshwater), positive during ice melt (liquid water mass increases, hence downward flux of freshwater)", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Freshwater flux from sea ice", + "long_name":"Freshwater Flux from Sea Ice", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"siflfwbot", "positive":"", - "standard_name":"freshwater_flux_from_ice", + "standard_name":"water_flux_into_sea_water_due_to_sea_ice_thermodynamics", "type":"real", "units":"kg m-2 s-1", "valid_max":"", @@ -527,16 +527,16 @@ }, "siflfwdrain":{ "cell_measures":"", - "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc or siconca)", + "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc)", "comment":"Total flux of fresh water from sea-ice surface into underlying ocean. This combines both surface melt water that drains directly into the ocean and the drainage of surface melt pond. By definition, this flux is always positive.", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Freshwater flux from sea-ice surface", + "long_name":"Freshwater Flux from Sea-Ice Surface", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"siflfwdrain", "positive":"", - "standard_name":"freshwater_flux_from_ice_surface", + "standard_name":"water_flux_into_sea_water_due_to_surface_drainage", "type":"real", "units":"kg m-2 s-1", "valid_max":"", @@ -544,11 +544,11 @@ }, "sifllatstop":{ "cell_measures":"", - "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc or siconca)", + "cell_methods":"area: time: mean where sea_ice (comment: mask=siconca)", "comment":"the net latent heat flux over sea ice", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Net latent heat flux over sea ice", + "long_name":"Net Latent Heat Flux over Sea Ice", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sifllatstop", @@ -561,11 +561,11 @@ }, "sifllwdtop":{ "cell_measures":"", - "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc or siconca)", + "cell_methods":"area: time: mean where sea_ice (comment: mask=siconca)", "comment":"the downwelling longwave flux over sea ice (always positive)", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Downwelling longwave flux over sea ice", + "long_name":"Downwelling Longwave Flux over Sea Ice", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sifllwdtop", @@ -578,7 +578,7 @@ }, "sifllwutop":{ "cell_measures":"", - "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc or siconca)", + "cell_methods":"area: time: mean where sea_ice (comment: mask=siconca)", "comment":"the upwelling longwave flux over sea ice (always negative)", "dimensions":"longitude latitude time", "frequency":"mon", @@ -595,11 +595,11 @@ }, "siflsenstop":{ "cell_measures":"", - "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc or siconca)", + "cell_methods":"area: time: mean where sea_ice (comment: mask=siconca)", "comment":"the net sensible heat flux over sea ice", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Net upward sensible heat flux over sea ice", + "long_name":"Net Upward Sensible Heat Flux over Sea Ice", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"siflsenstop", @@ -612,11 +612,11 @@ }, "siflsensupbot":{ "cell_measures":"", - "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc or siconca)", + "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc)", "comment":"the net sensible heat flux under sea ice from the ocean", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"", + "long_name":"Net Upward Sensible Heat Flux Under Sea Ice", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"siflsensupbot", @@ -629,16 +629,16 @@ }, "siflswdbot":{ "cell_measures":"", - "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc or siconca)", + "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc)", "comment":"The downwelling shortwave flux underneath sea ice (always positive)", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Downwelling shortwave flux under sea ice", + "long_name":"Downwelling Shortwave Flux Under Sea Ice", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"siflswdbot", "positive":"down", - "standard_name":"bottom_downwelling_shortwave_flux_into_ocean", + "standard_name":"downwelling_shortwave_flux_in_sea_water_at_sea_ice_base", "type":"real", "units":"W m-2", "valid_max":"", @@ -646,11 +646,11 @@ }, "siflswdtop":{ "cell_measures":"", - "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc or siconca)", + "cell_methods":"area: time: mean where sea_ice (comment: mask=siconca)", "comment":"The downwelling shortwave flux over sea ice (always positive by sign convention)", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Downwelling shortwave flux over sea ice", + "long_name":"Downwelling Shortwave Flux over Sea Ice", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"siflswdtop", @@ -663,7 +663,7 @@ }, "siflswutop":{ "cell_measures":"", - "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc or siconca)", + "cell_methods":"area: time: mean where sea_ice (comment: mask=siconca)", "comment":"The upwelling shortwave flux over sea ice (always negative)", "dimensions":"longitude latitude time", "frequency":"mon", @@ -684,12 +684,12 @@ "comment":"X-component of force on sea ice caused by coriolis force", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Coriolis force term in force balance (x-component)", + "long_name":"Coriolis Force Term in Force Balance (X-Component)", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"siforcecoriolx", "positive":"", - "standard_name":"coriolis_force_on_sea_ice_x", + "standard_name":"sea_ice_x_force_per_unit_area_due_to_coriolis_effect", "type":"real", "units":"N m-2", "valid_max":"", @@ -701,12 +701,12 @@ "comment":"Y-component of force on sea ice caused by coriolis force", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Coriolis force term in force balance (y-component)", + "long_name":"Coriolis Force Term in Force Balance (Y-Component)", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"siforcecorioly", "positive":"", - "standard_name":"coriolis_force_on_sea_ice_y", + "standard_name":"sea_ice_y_force_per_unit_area_due_to_coriolis_effect", "type":"real", "units":"N m-2", "valid_max":"", @@ -718,12 +718,12 @@ "comment":"X-component of force on sea ice caused by internal stress (divergence of sigma)", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Internal stress term in force balance (x-component)", + "long_name":"Internal Stress Term in Force Balance (X-Component)", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"siforceintstrx", "positive":"", - "standard_name":"internal_stress_in_sea_ice_x", + "standard_name":"sea_ice_x_internal_stress", "type":"real", "units":"N m-2", "valid_max":"", @@ -735,12 +735,12 @@ "comment":"Y-component of force on sea ice caused by internal stress (divergence of sigma)", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Internal stress term in force balance (y-component)", + "long_name":"Internal Stress Term in Force Balance (Y-Component)", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"siforceintstry", "positive":"", - "standard_name":"internal_stress_in_sea_ice_y", + "standard_name":"sea_ice_y_internal_stress", "type":"real", "units":"N m-2", "valid_max":"", @@ -752,12 +752,12 @@ "comment":"X-component of force on sea ice caused by sea-surface tilt", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Sea-surface tilt term in force balance (x-component)", + "long_name":"Sea-Surface Tilt Term in Force Balance (X-Component)", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"siforcetiltx", "positive":"", - "standard_name":"sea_surface_tilt_force_on_sea_ice_x", + "standard_name":"sea_ice_x_force_per_unit_area_due_to_sea_surface_tilt", "type":"real", "units":"N m-2", "valid_max":"", @@ -769,12 +769,12 @@ "comment":"Y-component of force on sea ice caused by sea-surface tilt", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Sea-surface tilt term in force balance (y-component)", + "long_name":"Sea-Surface Tilt Term in Force Balance (Y-Component)", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"siforcetilty", "positive":"", - "standard_name":"sea_surface_tilt_force_on_sea_ice_y", + "standard_name":"sea_ice_y_force_per_unit_area_due_to_sea_surface_tilt", "type":"real", "units":"N m-2", "valid_max":"", @@ -782,16 +782,16 @@ }, "sihc":{ "cell_measures":"", - "cell_methods":"area: time: mean", + "cell_methods":"area: mean where sea time: mean", "comment":"Heat content of all ice in grid cell divided by total grid-cell area. Water at 0 Celsius is assumed to have a heat content of 0 J. Does not include heat content of snow, but does include heat content of brine. Heat content is always negative, since both the sensible and the latent heat content of ice are less than that of water", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Sea-ice heat content per unit area", + "long_name":"Sea-Ice Heat Content per Unit Area", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sihc", "positive":"", - "standard_name":"integral_of_sea_ice_temperature_wrt_depth_expressed_as_heat_content", + "standard_name":"sea_ice_temperature_expressed_as_heat_content", "type":"real", "units":"J m-2", "valid_max":"", @@ -803,12 +803,12 @@ "comment":"Area fraction of grid cell covered by each ice-thickness category (vector with one entry for each thickness category starting from the thinnest category, netcdf file should use thickness bounds of the categories as third coordinate axis)", "dimensions":"longitude latitude iceband time", "frequency":"mon", - "long_name":"Sea-ice area fractions in thickness categories", + "long_name":"Sea-Ice Area Percentages in Thickness Categories", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"siitdconc", "positive":"", - "standard_name":"sea_ice_area_fraction_over_categories", + "standard_name":"sea_ice_area_fraction", "type":"real", "units":"%", "valid_max":"", @@ -820,12 +820,12 @@ "comment":"Area fraction of grid cell covered by snow in each ice-thickness category (vector with one entry for each thickness category starting from the thinnest category, netcdf file should use thickness bounds of the categories as third coordinate axis)", "dimensions":"longitude latitude iceband time", "frequency":"mon", - "long_name":"Snow area fractions in thickness categories", + "long_name":"Snow Area Percentages in Ice Thickness Categories", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"siitdsnconc", "positive":"", - "standard_name":"snow_area_fraction_over_categories", + "standard_name":"surface_snow_area_fraction", "type":"real", "units":"%", "valid_max":"", @@ -837,12 +837,12 @@ "comment":"Actual thickness of snow in each category (NOT volume divided by grid area), (vector with one entry for each thickness category starting from the thinnest category, netcdf file should use thickness bounds of categories as third coordinate axis)", "dimensions":"longitude latitude iceband time", "frequency":"mon", - "long_name":"Snow thickness in thickness categories", + "long_name":"Snow Thickness in Ice Thickness Categories", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"siitdsnthick", "positive":"", - "standard_name":"snow_thickness_over_categories", + "standard_name":"surface_snow_thickness", "type":"real", "units":"m", "valid_max":"", @@ -854,12 +854,12 @@ "comment":"Actual (floe) thickness of sea ice in each category (NOT volume divided by grid area), (vector with one entry for each thickness category starting from the thinnest category, netcdf file should use thickness bounds of categories as third coordinate axis)", "dimensions":"longitude latitude iceband time", "frequency":"mon", - "long_name":"Sea-ice thickness in thickness categories", + "long_name":"Sea-Ice Thickness in Thickness Categories", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"siitdthick", "positive":"", - "standard_name":"sea_ice_thickness_over_categories", + "standard_name":"sea_ice_thickness", "type":"real", "units":"m", "valid_max":"", @@ -867,11 +867,11 @@ }, "simass":{ "cell_measures":"", - "cell_methods":"area: time: mean", + "cell_methods":"area: mean where sea time: mean", "comment":"Total mass of sea ice divided by grid-cell area", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Sea-ice mass per area", + "long_name":"Sea-Ice Mass per Area", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"simass", @@ -888,7 +888,7 @@ "comment":"net (sum of transport in all directions) sea ice area transport through the following four passages, positive into the Arctic Ocean 1. Fram Strait = (11.5W,81.3N to (10.5E,79.6N) 2. Canadian Archipelago = (128.2W,70.6N) to (59.3W,82.1N) 3. Barents opening = (16.8E,76.5N) to (19.2E,70.2N) 4. Bering Strait = (171W,66.2N) to (166W,65N)", "dimensions":"siline time", "frequency":"mon", - "long_name":"Sea mass area flux through straits", + "long_name":"Sea Mass Area Flux Through Straits", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"simassacrossline", @@ -902,10 +902,10 @@ "simpconc":{ "cell_measures":"", "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc)", - "comment":"Fraction of sea ice, by area, which is covered by melt ponds, giving equal weight to every square metre of sea ice .", + "comment":"Percentage of sea ice, by area, which is covered by melt ponds, giving equal weight to every square metre of sea ice .", "dimensions":"longitude latitude time typemp", "frequency":"mon", - "long_name":"Percentage Cover of Sea-Ice by Meltpond", + "long_name":"Percentage Cover of Sea Ice by Meltpond", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"simpconc", @@ -919,17 +919,17 @@ "simpmass":{ "cell_measures":"", "cell_methods":"area: time: mean where sea_ice_melt_pond (comment: mask=simpconc)", - "comment":"Meltpond mass per area of sea ice.", + "comment":"Meltpond Depth", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Meltpond Mass per Unit Area", + "long_name":"Meltpond Mass per Unit Area (as Depth)", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"simpmass", "positive":"", - "standard_name":"surface_liquid_water_amount", + "standard_name":"sea_ice_melt_pond_thickness", "type":"real", - "units":"kg m-2", + "units":"m", "valid_max":"", "valid_min":"" }, @@ -944,7 +944,7 @@ "ok_min_mean_abs":"", "out_name":"simprefrozen", "positive":"", - "standard_name":"melt_pond_refrozen_ice", + "standard_name":"thickness_of_ice_on_sea_ice_melt_pond", "type":"real", "units":"m", "valid_max":"", @@ -952,11 +952,11 @@ }, "sipr":{ "cell_measures":"", - "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc or siconca)", + "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc)", "comment":"mass of liquid precipitation falling onto sea ice divided by grid-cell area", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Rainfall rate over sea ice", + "long_name":"Rainfall Rate over Sea Ice", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sipr", @@ -969,16 +969,16 @@ }, "sirdgconc":{ "cell_measures":"", - "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc or siconca)", + "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc)", "comment":"Fraction of sea ice, by area, which is covered by sea ice ridges, giving equal weight to every square metre of sea ice .", - "dimensions":"longitude latitude time", + "dimensions":"longitude latitude time typesirdg", "frequency":"mon", - "long_name":"Percentage Cover of Sea-Ice by Ridging", + "long_name":"Percentage Cover of Sea Ice by Ridging", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sirdgconc", "positive":"", - "standard_name":"fraction_of_ridged_sea_ice", + "standard_name":"area_fraction", "type":"real", "units":"1", "valid_max":"", @@ -986,16 +986,16 @@ }, "sirdgthick":{ "cell_measures":"", - "cell_methods":"area: time: mean where sea_ice (comment: mask=sirdgconc - ridges only)", + "cell_methods":"area: time: mean where sea_ice_ridges (comment: mask=sirdgconc)", "comment":"Sea Ice Ridge Height (representing mean height over the ridged area)", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Ridged ice thickness", + "long_name":"Ridged Ice Thickness", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sirdgthick", "positive":"", - "standard_name":"thickness_of_ridged_sea_ice", + "standard_name":"sea_ice_thickness", "type":"real", "units":"m", "valid_max":"", @@ -1003,11 +1003,11 @@ }, "sisali":{ "cell_measures":"", - "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc or siconca)", + "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc)", "comment":"Mean sea-ice salinity of all sea ice in grid cell", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Sea ice salinity", + "long_name":"Sea Ice Salinity", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sisali", @@ -1020,16 +1020,16 @@ }, "sisaltmass":{ "cell_measures":"", - "cell_methods":"area: time: mean", + "cell_methods":"area: mean where sea time: mean", "comment":"Total mass of all salt in sea ice divided by grid-cell area", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Mass of salt in sea ice per area", + "long_name":"Mass of Salt in Sea Ice per Area", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sisaltmass", "positive":"", - "standard_name":"sea_ice_salt_mass", + "standard_name":"sea_ice_mass_content_of_salt", "type":"real", "units":"kg m-2", "valid_max":"", @@ -1041,12 +1041,12 @@ "comment":"Maximum shear of sea-ice velocity field (second shear strain invariant)", "dimensions":"longitude latitude time1", "frequency":"monPt", - "long_name":"Maximum shear of sea-ice velocity field", + "long_name":"Maximum Shear of Sea-Ice Velocity Field", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sishevel", "positive":"", - "standard_name":"maximum_shear_of_sea_ice_velocity", + "standard_name":"maximum_over_coordinate_rotation_of_sea_ice_horizontal_shear_strain_rate", "type":"real", "units":"s-1", "valid_max":"", @@ -1054,11 +1054,11 @@ }, "sisnconc":{ "cell_measures":"", - "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc or siconca)", + "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc)", "comment":"Fraction of sea ice, by area, which is covered by snow, giving equal weight to every square metre of sea ice . Exclude snow that lies on land or land ice.", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Snow area fraction", + "long_name":"Snow Area Percentage", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sisnconc", @@ -1071,11 +1071,11 @@ }, "sisnhc":{ "cell_measures":"", - "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc or siconca)", + "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc)", "comment":"Heat-content of all snow in grid cell divided by total grid-cell area. Snow-water equivalent at 0 Celsius is assumed to have a heat content of 0 J. Does not include heat content of sea ice.", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Snow-heat content per unit area", + "long_name":"Snow Heat Content per Unit Area", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sisnhc", @@ -1088,11 +1088,11 @@ }, "sisnmass":{ "cell_measures":"", - "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc or siconca)", - "comment":"Total mass of snow on sea ice divided by grid-cell area", + "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc)", + "comment":"Total mass of snow on sea ice divided by sea-ice area.", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Snow mass per area", + "long_name":"Snow Mass per Area", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sisnmass", @@ -1109,7 +1109,7 @@ "comment":"Actual thickness of snow (snow volume divided by snow-covered area)", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Snow thickness", + "long_name":"Snow Thickness", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sisnthick", @@ -1122,11 +1122,11 @@ }, "sispeed":{ "cell_measures":"", - "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc or siconca)", + "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc)", "comment":"Speed of ice (i.e. mean absolute velocity) to account for back-and-forth movement of the ice", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Sea-ice speed", + "long_name":"Sea-Ice Speed", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sispeed", @@ -1143,12 +1143,12 @@ "comment":"Maximum shear stress in sea ice (second stress invariant)", "dimensions":"longitude latitude time1", "frequency":"monPt", - "long_name":"Maximum shear stress in sea ice", + "long_name":"Maximum Shear Stress in Sea Ice", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sistremax", "positive":"", - "standard_name":"maximum_shear_stress", + "standard_name":"maximum_over_coordinate_rotation_of_sea_ice_horizontal_shear_stress", "type":"real", "units":"N m-1", "valid_max":"", @@ -1160,12 +1160,12 @@ "comment":"Average normal stress in sea ice (first stress invariant)", "dimensions":"longitude latitude time1", "frequency":"monPt", - "long_name":"Average normal stress in sea ice", + "long_name":"Average Normal Stress in Sea Ice", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sistresave", "positive":"", - "standard_name":"average_normal_stress", + "standard_name":"sea_ice_average_normal_horizontal_stress", "type":"real", "units":"N m-1", "valid_max":"", @@ -1177,7 +1177,7 @@ "comment":"X-component of atmospheric stress on sea ice", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"X-component of atmospheric stress on sea ice", + "long_name":"X-Component of Atmospheric Stress on Sea Ice", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sistrxdtop", @@ -1190,11 +1190,11 @@ }, "sistrxubot":{ "cell_measures":"", - "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc or siconca)", + "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc)", "comment":"X-component of ocean stress on sea ice", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"X-component of ocean stress on sea ice", + "long_name":"X-Component of Ocean Stress on Sea Ice", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sistrxubot", @@ -1211,7 +1211,7 @@ "comment":"Y-component of atmospheric stress on sea ice", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Y-component of atmospheric stress on sea ice", + "long_name":"Y-Component of Atmospheric Stress on Sea Ice", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sistrydtop", @@ -1224,11 +1224,11 @@ }, "sistryubot":{ "cell_measures":"", - "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc or siconca)", + "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc)", "comment":"Y-component of ocean stress on sea ice", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Y-component of ocean stress on sea ice", + "long_name":"Y-Component of Ocean Stress on Sea Ice", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sistryubot", @@ -1241,16 +1241,16 @@ }, "sitempbot":{ "cell_measures":"", - "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc or siconca)", + "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc)", "comment":"Report temperature at interface, NOT temperature within lowermost model layer", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Temperature at ice-ocean interface", + "long_name":"Temperature at Ice-Ocean Interface", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sitempbot", "positive":"", - "standard_name":"sea_ice_bottom_temperature", + "standard_name":"sea_ice_basal_temperature", "type":"real", "units":"K", "valid_max":"", @@ -1258,11 +1258,11 @@ }, "sitempsnic":{ "cell_measures":"", - "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc or siconca)", + "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc)", "comment":"Report surface temperature of ice where snow thickness is zero", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Temperature at snow-ice interface", + "long_name":"Temperature at Snow-Ice Interface", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sitempsnic", @@ -1275,11 +1275,11 @@ }, "sitemptop":{ "cell_measures":"", - "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc or siconca)", + "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc)", "comment":"Report surface temperature of snow where snow covers the sea ice.", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Surface temperature of sea ice", + "long_name":"Surface Temperature of Sea Ice", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sitemptop", @@ -1292,7 +1292,7 @@ }, "sithick":{ "cell_measures":"", - "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc or siconca)", + "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc)", "comment":"Actual (floe) thickness of sea ice (NOT volume divided by grid area as was done in CMIP5)", "dimensions":"longitude latitude time", "frequency":"mon", @@ -1309,16 +1309,16 @@ }, "sitimefrac":{ "cell_measures":"", - "cell_methods":"area: time: mean", + "cell_methods":"area: mean where sea time: mean", "comment":"Fraction of time steps of the averaging period during which sea ice is present (siconc >0 ) in a grid cell", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Fraction of time steps with sea ice", + "long_name":"Fraction of Time Steps with Sea Ice", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sitimefrac", "positive":"", - "standard_name":"sea_ice_time_fraction", + "standard_name":"fraction_of_time_with_sea_ice_area_fraction_above_threshold", "type":"real", "units":"1", "valid_max":"", @@ -1330,7 +1330,7 @@ "comment":"The x-velocity of ice on native model grid", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"X-component of sea ice velocity", + "long_name":"X-Component of Sea-Ice Velocity", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"siu", @@ -1347,7 +1347,7 @@ "comment":"The y-velocity of ice on native model grid", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Y-component of sea ice velocity", + "long_name":"Y-Component of Sea-Ice Velocity", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"siv", @@ -1360,11 +1360,11 @@ }, "sivol":{ "cell_measures":"", - "cell_methods":"area: time: mean", + "cell_methods":"area: mean where sea time: mean", "comment":"Total volume of sea ice divided by grid-cell area (this used to be called ice thickness in CMIP5)", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Sea-ice volume per area", + "long_name":"Sea-Ice Volume per Area", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sivol", @@ -1381,7 +1381,7 @@ "comment":"total volume of sea ice in the Northern hemisphere", "dimensions":"time", "frequency":"mon", - "long_name":"Sea ice volume North", + "long_name":"Sea-Ice Volume North", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sivoln", @@ -1398,7 +1398,7 @@ "comment":"total volume of sea ice in the Southern hemisphere", "dimensions":"time", "frequency":"mon", - "long_name":"Sea ice volume South", + "long_name":"Sea-Ice Volume South", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sivols", @@ -1411,16 +1411,16 @@ }, "sndmassdyn":{ "cell_measures":"", - "cell_methods":"area: time: mean", - "comment":"the rate of change of snow mass through advection with sea ice divided by grid-cell area", + "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc)", + "comment":"The rate of change of snow mass through advection with sea ice divided by sea-ice area", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Snow Mass Rate of Change through Avection by Sea-ice Dynamics", + "long_name":"Snow Mass Rate of Change Through Advection by Sea-Ice Dynamics", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sndmassdyn", "positive":"", - "standard_name":"tendency_of_snow_mass_due_to_sea_ice_dynamics", + "standard_name":"tendency_of_surface_snow_amount_due_to_sea_ice_dynamics", "type":"real", "units":"kg m-2 s-1", "valid_max":"", @@ -1428,11 +1428,11 @@ }, "sndmassmelt":{ "cell_measures":"", - "cell_methods":"area: time: mean", - "comment":"the rate of change of snow mass through melt divided by grid-cell area", + "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc)", + "comment":"the rate of change of snow mass through melt divided by sea-ice area", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Snow Mass Rate of Change through Melt", + "long_name":"Snow Mass Rate of Change Through Melt", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sndmassmelt", @@ -1445,11 +1445,11 @@ }, "sndmasssi":{ "cell_measures":"", - "cell_methods":"area: time: mean", - "comment":"the rate of change of snow mass due to transformation of snow to sea ice divided by grid-cell area", + "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc)", + "comment":"the rate of change of snow mass due to transformation of snow to sea ice divided by sea-ice area", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Snow Mass Rate of Change through Snow-to-Ice Conversion", + "long_name":"Snow Mass Rate of Change Through Snow-to-Ice Conversion", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sndmasssi", @@ -1462,11 +1462,11 @@ }, "sndmasssnf":{ "cell_measures":"", - "cell_methods":"area: time: mean", - "comment":"mass of solid precipitation falling onto sea ice divided by grid-cell area", + "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc)", + "comment":"mass of solid precipitation falling onto sea ice divided by sea-ice area", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"snow mass change through snow fall", + "long_name":"Snow Mass Change Through Snow Fall", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sndmasssnf", @@ -1479,16 +1479,16 @@ }, "sndmasssubl":{ "cell_measures":"", - "cell_methods":"area: time: mean", - "comment":"the rate of change of snow mass through sublimation and evaporation divided by grid-cell area", + "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc)", + "comment":"the rate of change of snow mass through sublimation and evaporation divided by sea-ice area", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Snow Mass Rate of Change through Evaporation or Sublimation", + "long_name":"Snow Mass Rate of Change Through Evaporation or Sublimation", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sndmasssubl", "positive":"", - "standard_name":"surface_snow_sublimation_flux", + "standard_name":"tendency_of_atmosphere_mass_content_of_water_vapor_due_to_sublimation_of_surface_snow_and_ice", "type":"real", "units":"kg m-2 s-1", "valid_max":"", @@ -1496,16 +1496,16 @@ }, "sndmasswindrif":{ "cell_measures":"", - "cell_methods":"area: time: mean", - "comment":"the rate of change of snow mass through wind drift of snow (from sea-ice into the sea) divided by grid-cell area", + "cell_methods":"area: time: mean where sea_ice (comment: mask=siconc)", + "comment":"the rate of change of snow mass through wind drift of snow (from sea-ice into the sea) divided by sea-ice area", "dimensions":"longitude latitude time", "frequency":"mon", - "long_name":"Snow Mass Rate of Change through Wind Drift of Snow", + "long_name":"Snow Mass Rate of Change Through Wind Drift of Snow", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"sndmasswindrif", "positive":"", - "standard_name":"tendency_of_snow_mass_due_to_drifting_snow", + "standard_name":"tendency_of_surface_snow_amount_due_to_drifting_into_sea", "type":"real", "units":"kg m-2 s-1", "valid_max":"", @@ -1514,15 +1514,15 @@ "snmassacrossline":{ "cell_measures":"", "cell_methods":"time: mean", - "comment":"net (sum of transport in all directions) snow mass transport through the following four passages, positive into the Arctic Ocean 1. Fram Strait = (11.5W,81.3N to (10.5E,79.6N) 2. Canadian Archipela", + "comment":"net (sum of transport in all directions) sea ice area transport through the following four passages, positive into the Arctic Ocean 1. Fram Strait = (11.5W,81.3N to (10.5E,79.6N) 2. Canadian Archipelago = (128.2W,70.6N) to (59.3W,82.1N) 3. Barents opening = (16.8E,76.5N) to (19.2E,70.2N) 4. Bering Strait = (171W,66.2N) to (166W,65N)", "dimensions":"siline time", "frequency":"mon", - "long_name":"Snow mass flux through straits", + "long_name":"Snow Mass Flux Through Straits", "ok_max_mean_abs":"", "ok_min_mean_abs":"", "out_name":"snmassacrossline", "positive":"", - "standard_name":"snow_mass_transport_across_line", + "standard_name":"snow_transport_across_line_due_to_sea_ice_dynamics", "type":"real", "units":"kg s-1", "valid_max":"", diff --git a/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_coordinate.json b/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_coordinate.json index cafd418bd0..a82ba1b52e 100644 --- a/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_coordinate.json +++ b/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_coordinate.json @@ -1,32 +1,11 @@ { "axis_entry":{ - "alev1":{ - "axis":"Z", - "bounds_values":"", - "climatology":"", - "formula":"", - "long_name":"lowest atmospheric model level", - "must_have_bounds":"yes", - "out_name":"lev", - "positive":"", - "requested":"", - "requested_bounds":"", - "standard_name":"", - "stored_direction":"", - "tolerance":"", - "type":"double", - "units":"", - "valid_max":"", - "valid_min":"", - "value":"", - "z_bounds_factors":"", - "z_factors":"" - }, "alt16":{ "axis":"Z", "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"altitude", "must_have_bounds":"yes", "out_name":"alt16", @@ -99,6 +78,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"altitude", "must_have_bounds":"yes", "out_name":"alt40", @@ -243,6 +223,7 @@ "bounds_values":"", "climatology":"", "formula":"p = ap + b*ps", + "generic_level_name":"alevel", "long_name":"hybrid sigma pressure coordinate", "must_have_bounds":"yes", "out_name":"lev", @@ -260,11 +241,35 @@ "z_bounds_factors":"ap: ap_bnds b: b_bnds ps: ps", "z_factors":"ap: ap b: b ps: ps" }, + "alternate_hybrid_sigma_half":{ + "axis":"Z", + "bounds_values":"", + "climatology":"", + "formula":"p = ap + b*ps", + "generic_level_name":"alevhalf", + "long_name":"hybrid sigma pressure coordinate", + "must_have_bounds":"no", + "out_name":"lev", + "positive":"down", + "requested":"", + "requested_bounds":"", + "standard_name":"atmosphere_hybrid_sigma_pressure_coordinate", + "stored_direction":"decreasing", + "tolerance":"", + "type":"", + "units":"1", + "valid_max":"1.0", + "valid_min":"0.0", + "value":"", + "z_bounds_factors":"ap: ap_bnds b: b_bnds ps: ps", + "z_factors":"ap: ap b: b ps: ps" + }, "basin":{ "axis":"", "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"ocean basin", "must_have_bounds":"no", "out_name":"basin", @@ -291,6 +296,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"CloudSat simulator equivalent radar reflectivity factor", "must_have_bounds":"yes", "out_name":"dbze", @@ -360,6 +366,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"depth", "must_have_bounds":"no", "out_name":"depth", @@ -382,6 +389,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"depth", "must_have_bounds":"no", "out_name":"depth", @@ -401,11 +409,12 @@ }, "depth2000m":{ "axis":"Z", - "bounds_values":"", + "bounds_values":"0.0 2000.0", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"depth", - "must_have_bounds":"no", + "must_have_bounds":"yes", "out_name":"depth", "positive":"down", "requested":"", @@ -415,19 +424,20 @@ "tolerance":"", "type":"double", "units":"m", - "valid_max":"2200.0", - "valid_min":"1980.0", - "value":"2000", + "valid_max":"2000", + "valid_min":"0.0", + "value":"1000.", "z_bounds_factors":"", "z_factors":"" }, "depth300m":{ "axis":"Z", - "bounds_values":"", + "bounds_values":"0.0 300.0", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"depth", - "must_have_bounds":"no", + "must_have_bounds":"yes", "out_name":"depth", "positive":"down", "requested":"", @@ -437,19 +447,20 @@ "tolerance":"", "type":"double", "units":"m", - "valid_max":"320.0", - "valid_min":"280.0", - "value":"300", + "valid_max":"300.0", + "valid_min":"0.0", + "value":"150.", "z_bounds_factors":"", "z_factors":"" }, "depth700m":{ "axis":"Z", - "bounds_values":"", + "bounds_values":"0.0 700.0", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"depth", - "must_have_bounds":"no", + "must_have_bounds":"yes", "out_name":"depth", "positive":"down", "requested":"", @@ -459,9 +470,9 @@ "tolerance":"", "type":"double", "units":"m", - "valid_max":"720.0", - "valid_min":"680.0", - "value":"700", + "valid_max":"700.0", + "valid_min":"0.0", + "value":"350.", "z_bounds_factors":"", "z_factors":"" }, @@ -470,6 +481,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"olevel", "long_name":"ocean depth coordinate", "must_have_bounds":"yes", "out_name":"lev", @@ -487,11 +499,35 @@ "z_bounds_factors":"", "z_factors":"" }, + "depth_coord_half":{ + "axis":"Z", + "bounds_values":"", + "climatology":"", + "formula":"", + "generic_level_name":"olevhalf", + "long_name":"ocean depth coordinate", + "must_have_bounds":"no", + "out_name":"lev", + "positive":"down", + "requested":"", + "requested_bounds":"", + "standard_name":"depth", + "stored_direction":"increasing", + "tolerance":"", + "type":"", + "units":"m", + "valid_max":"12000.0", + "valid_min":"0.0", + "value":"", + "z_bounds_factors":"", + "z_factors":"" + }, "effectRadIc":{ "axis":"", "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"Effective Radius [Values to be specified]", "must_have_bounds":"", "out_name":"effectRadIc", @@ -534,6 +570,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"Effective Radius [Values to be specified]", "must_have_bounds":"", "out_name":"effectRadLi", @@ -571,11 +608,35 @@ "z_bounds_factors":"", "z_factors":"" }, + "gridlatitude":{ + "axis":"Y", + "bounds_values":"", + "climatology":"", + "formula":"", + "generic_level_name":"", + "long_name":"Grid Latitude", + "must_have_bounds":"yes", + "out_name":"rlat", + "positive":"", + "requested":"", + "requested_bounds":"", + "standard_name":"grid_latitude", + "stored_direction":"increasing", + "tolerance":"", + "type":"double", + "units":"degrees", + "valid_max":"90.0", + "valid_min":"-90.0", + "value":"", + "z_bounds_factors":"", + "z_factors":"" + }, "height100m":{ "axis":"Z", "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"height", "must_have_bounds":"no", "out_name":"height", @@ -598,6 +659,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"height", "must_have_bounds":"no", "out_name":"height", @@ -620,6 +682,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"height", "must_have_bounds":"no", "out_name":"height", @@ -642,6 +705,7 @@ "bounds_values":"", "climatology":"", "formula":"z = a + b*orog", + "generic_level_name":"alevel", "long_name":"hybrid height coordinate", "must_have_bounds":"yes", "out_name":"lev", @@ -659,11 +723,35 @@ "z_bounds_factors":"a: lev_bnds b: b_bnds orog: orog", "z_factors":"a: lev b: b orog: orog" }, + "hybrid_height_half":{ + "axis":"Z", + "bounds_values":"", + "climatology":"", + "formula":"z = a + b*orog", + "generic_level_name":"alevhalf", + "long_name":"hybrid height coordinate", + "must_have_bounds":"no", + "out_name":"lev", + "positive":"up", + "requested":"", + "requested_bounds":"", + "standard_name":"atmosphere_hybrid_height_coordinate", + "stored_direction":"increasing", + "tolerance":"", + "type":"", + "units":"m", + "valid_max":"", + "valid_min":"0.0", + "value":"", + "z_bounds_factors":"a: lev_bnds b: b_bnds orog: orog", + "z_factors":"a: lev b: b orog: orog" + }, "iceband":{ "axis":"", "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"Ice Depth Band", "must_have_bounds":"yes", "out_name":"iceband", @@ -681,11 +769,35 @@ "z_bounds_factors":"", "z_factors":"" }, + "lambda550nm":{ + "axis":"", + "bounds_values":"", + "climatology":"", + "formula":"", + "generic_level_name":"", + "long_name":"Radiation Wavelength 550 nanometers", + "must_have_bounds":"", + "out_name":"wavelength", + "positive":"", + "requested":"", + "requested_bounds":"", + "standard_name":"radiation_wavelength", + "stored_direction":"", + "tolerance":"", + "type":"double", + "units":"nm", + "valid_max":"", + "valid_min":"", + "value":"550.0", + "z_bounds_factors":"", + "z_factors":"" + }, "landUse":{ "axis":"", "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"Land use type", "must_have_bounds":"no", "out_name":"landuse", @@ -713,7 +825,8 @@ "bounds_values":"", "climatology":"", "formula":"", - "long_name":"latitude", + "generic_level_name":"", + "long_name":"Latitude", "must_have_bounds":"yes", "out_name":"lat", "positive":"", @@ -735,6 +848,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"location index", "must_have_bounds":"no", "out_name":"loc", @@ -757,7 +871,8 @@ "bounds_values":"", "climatology":"", "formula":"", - "long_name":"longitude", + "generic_level_name":"", + "long_name":"Longitude", "must_have_bounds":"yes", "out_name":"lon", "positive":"", @@ -779,6 +894,7 @@ "bounds_values":"", "climatology":"", "formula":"p = p0 * exp(-lev)", + "generic_level_name":"alevel", "long_name":"atmosphere natural log pressure coordinate", "must_have_bounds":"yes", "out_name":"lev", @@ -796,11 +912,35 @@ "z_bounds_factors":"p0: p0 lev: lev_bnds", "z_factors":"p0: p0 lev: lev" }, + "natural_log_pressure_half":{ + "axis":"Z", + "bounds_values":"", + "climatology":"", + "formula":"p = p0 * exp(-lev)", + "generic_level_name":"alevhalf", + "long_name":"atmosphere natural log pressure coordinate", + "must_have_bounds":"no", + "out_name":"lev", + "positive":"down", + "requested":"", + "requested_bounds":"", + "standard_name":"atmosphere_ln_pressure_coordinate", + "stored_direction":"decreasing", + "tolerance":"", + "type":"", + "units":"", + "valid_max":"20.0", + "valid_min":"-1.0", + "value":"", + "z_bounds_factors":"p0: p0 lev: lev_bnds", + "z_factors":"p0: p0 lev: lev" + }, "ocean_double_sigma":{ "axis":"Z", "bounds_values":"", "climatology":"", "formula":"for k <= k_c:\n z(k,j,i)= sigma(k)*f(j,i) \n for k > k_c:\n z(k,j,i)= f(j,i) + (sigma(k)-1)*(depth(j,i)-f(j,i)) \n f(j,i)= 0.5*(z1+ z2) + 0.5*(z1-z2)* tanh(2*a/(z1-z2)*(depth(j,i)-href))", + "generic_level_name":"olevel", "long_name":"ocean double sigma coordinate", "must_have_bounds":"yes", "out_name":"lev", @@ -823,6 +963,7 @@ "bounds_values":"", "climatology":"", "formula":"z(n,k,j,i) = eta(n,j,i)*(1+s(k)) + depth_c*s(k) + (depth(j,i)-depth_c)*C(k) \n where \n C(k)=(1-b)*sinh(a*s(k))/sinh(a) +\n b*(tanh(a*(s(k)+0.5))/(2*tanh(0.5*a)) - 0.5)", + "generic_level_name":"olevel", "long_name":"ocean s-coordinate", "must_have_bounds":"yes", "out_name":"lev", @@ -845,6 +986,7 @@ "bounds_values":"", "climatology":"", "formula":"z(n,k,j,i) = eta(n,j,i) + sigma(k)*(depth(j,i)+eta(n,j,i))", + "generic_level_name":"olevel", "long_name":"ocean sigma coordinate", "must_have_bounds":"yes", "out_name":"lev", @@ -867,6 +1009,7 @@ "bounds_values":"", "climatology":"", "formula":"for k <= nsigma: z(n,k,j,i) = eta(n,j,i) + sigma(k)*(min(depth_c,depth(j,i))+eta(n,j,i)) ; for k > nsigma: z(n,k,j,i) = zlev(k)", + "generic_level_name":"olevel", "long_name":"ocean sigma over z coordinate", "must_have_bounds":"yes", "out_name":"lev", @@ -889,6 +1032,7 @@ "bounds_values":"0.0 100.0", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"depth", "must_have_bounds":"no", "out_name":"depth", @@ -906,11 +1050,35 @@ "z_bounds_factors":"", "z_factors":"" }, + "olevhalf":{ + "axis":"Z", + "bounds_values":"", + "climatology":"", + "formula":"", + "generic_level_name":"", + "long_name":"ocean model half levels", + "must_have_bounds":"no", + "out_name":"lev", + "positive":"down", + "requested":"", + "requested_bounds":"", + "standard_name":"", + "stored_direction":"", + "tolerance":"", + "type":"double", + "units":"", + "valid_max":"", + "valid_min":"", + "value":"", + "z_bounds_factors":"", + "z_factors":"" + }, "oline":{ "axis":"", "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"ocean passage", "must_have_bounds":"no", "out_name":"line", @@ -918,19 +1086,20 @@ "requested":[ "barents_opening", "bering_strait", - "canadian_archipelago", + "windward_passage", + "davis_strait", "denmark_strait", "drake_passage", "english_channel", - "pacific_equatorial_undercurrent", "faroe_scotland_channel", "florida_bahamas_strait", "fram_strait", + "gibraltar_strait", "iceland_faroe_channel", "indonesian_throughflow", "mozambique_channel", - "taiwan_luzon_straits", - "windward_passage" + "pacific_equatorial_undercurrent", + "taiwan_luzon_straits" ], "requested_bounds":"", "standard_name":"region", @@ -949,6 +1118,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"pressure", "must_have_bounds":"no", "out_name":"plev", @@ -971,6 +1141,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"pressure", "must_have_bounds":"no", "out_name":"plev", @@ -993,6 +1164,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"pressure", "must_have_bounds":"no", "out_name":"plev", @@ -1015,6 +1187,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"pressure", "must_have_bounds":"no", "out_name":"plev", @@ -1037,6 +1210,7 @@ "bounds_values":"44000.0 0.0", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"pressure", "must_have_bounds":"yes", "out_name":"plev", @@ -1059,6 +1233,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"pressure", "must_have_bounds":"no", "out_name":"plev", @@ -1081,6 +1256,7 @@ "bounds_values":"68000.0 44000.0", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"pressure", "must_have_bounds":"yes", "out_name":"plev", @@ -1103,6 +1279,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"pressure", "must_have_bounds":"no", "out_name":"plev", @@ -1125,6 +1302,7 @@ "bounds_values":"100000.0 68000.0", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"pressure", "must_have_bounds":"yes", "out_name":"plev", @@ -1147,6 +1325,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"pressure", "must_have_bounds":"no", "out_name":"plev", @@ -1169,6 +1348,7 @@ "bounds_values":"85000.0 60000.0", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"pressure", "must_have_bounds":"yes", "out_name":"plev", @@ -1186,44 +1366,12 @@ "z_bounds_factors":"", "z_factors":"" }, - "plev10":{ - "axis":"Z", - "bounds_values":"", - "climatology":"", - "formula":"", - "long_name":"pressure", - "must_have_bounds":"no", - "out_name":"plev", - "positive":"down", - "requested":[ - "100000.", - "85000.", - "70000.", - "50000.", - "25000.", - "15000.", - "10000.", - "7000.", - "5000.", - "1000." - ], - "requested_bounds":"", - "standard_name":"air_pressure", - "stored_direction":"decreasing", - "tolerance":"", - "type":"double", - "units":"Pa", - "valid_max":"", - "valid_min":"", - "value":"", - "z_bounds_factors":"", - "z_factors":"" - }, "plev19":{ "axis":"Z", "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"pressure", "must_have_bounds":"no", "out_name":"plev", @@ -1266,6 +1414,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"pressure", "must_have_bounds":"no", "out_name":"plev", @@ -1312,6 +1461,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"pressure", "must_have_bounds":"no", "out_name":"plev", @@ -1362,6 +1512,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"pressure", "must_have_bounds":"no", "out_name":"plev", @@ -1388,6 +1539,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"pressure", "must_have_bounds":"no", "out_name":"plev", @@ -1450,6 +1602,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"pressure", "must_have_bounds":"no", "out_name":"plev", @@ -1476,6 +1629,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"pressure", "must_have_bounds":"no", "out_name":"plev", @@ -1503,6 +1657,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"pressure", "must_have_bounds":"yes", "out_name":"plev", @@ -1548,6 +1703,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"pressure", "must_have_bounds":"yes", "out_name":"plev", @@ -1593,6 +1749,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"pressure", "must_have_bounds":"no", "out_name":"plev", @@ -1623,6 +1780,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"pressure", "must_have_bounds":"no", "out_name":"plev", @@ -1654,6 +1812,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"potential density referenced to 2000 dbar", "must_have_bounds":"yes", "out_name":"rho", @@ -1673,9 +1832,10 @@ }, "scatratio":{ "axis":"", - "bounds_values":"0.0 0.01 1.2 3.0 5.0 7.0 10.0 15.0 20.0 25.0 30.0 40.0 50.0 60.0 80.0 100000.0", + "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"lidar backscattering ratio", "must_have_bounds":"yes", "out_name":"scatratio", @@ -1736,7 +1896,30 @@ "units":"1", "valid_max":"", "valid_min":"", - "value":"0.005, 0.605, 2.1, 4, 6, 8.5, 12.5, 17.5, 22.5, 27.5, 35, 45, 55, 70, 50040", + "value":"", + "z_bounds_factors":"", + "z_factors":"" + }, + "scatter180":{ + "axis":"", + "bounds_values":"", + "climatology":"", + "formula":"", + "generic_level_name":"", + "long_name":"Scattering Angle", + "must_have_bounds":"no", + "out_name":"scatangle", + "positive":"", + "requested":"", + "requested_bounds":"", + "standard_name":"scattering_angle", + "stored_direction":"", + "tolerance":"", + "type":"double", + "units":"degree", + "valid_max":"", + "valid_min":"", + "value":"180.0", "z_bounds_factors":"", "z_factors":"" }, @@ -1745,6 +1928,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"depth", "must_have_bounds":"yes", "out_name":"depth", @@ -1767,6 +1951,7 @@ "bounds_values":"0.0 0.1", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"depth", "must_have_bounds":"yes", "out_name":"depth", @@ -1778,17 +1963,41 @@ "tolerance":"", "type":"double", "units":"m", - "valid_max":"0.2", + "valid_max":"0.1", "valid_min":"0.0", "value":"0.05", "z_bounds_factors":"", "z_factors":"" }, + "sdepth10":{ + "axis":"Z", + "bounds_values":"0.0 1.0", + "climatology":"", + "formula":"", + "generic_level_name":"", + "long_name":"depth", + "must_have_bounds":"yes", + "out_name":"depth", + "positive":"down", + "requested":"", + "requested_bounds":"", + "standard_name":"depth", + "stored_direction":"increasing", + "tolerance":"", + "type":"double", + "units":"m", + "valid_max":"1.0", + "valid_min":"0.0", + "value":"0.5", + "z_bounds_factors":"", + "z_factors":"" + }, "siline":{ "axis":"", "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"ocean passage", "must_have_bounds":"no", "out_name":"line", @@ -1816,6 +2025,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"site index", "must_have_bounds":"no", "out_name":"site", @@ -1833,11 +2043,35 @@ "z_bounds_factors":"", "z_factors":"" }, + "sithreshold":{ + "axis":"", + "bounds_values":"", + "climatology":"", + "formula":"", + "generic_level_name":"", + "long_name":"Sea Ice Area Fraction Threshold", + "must_have_bounds":"no", + "out_name":"threshold", + "positive":"", + "requested":"", + "requested_bounds":"", + "standard_name":"sea_ice_area_fraction", + "stored_direction":"", + "tolerance":"", + "type":"double", + "units":"%", + "valid_max":"", + "valid_min":"", + "value":"15.0", + "z_bounds_factors":"", + "z_factors":"" + }, "smooth_level":{ "axis":"Z", "bounds_values":"", "climatology":"", "formula":"z = a*ztop + b1*zsurf1 + b2*zsurf2", + "generic_level_name":"alevel", "long_name":"atmosphere smooth level vertical (SLEVE) coordinate", "must_have_bounds":"yes", "out_name":"lev", @@ -1855,11 +2089,35 @@ "z_bounds_factors":"a: a_bnds b1: b1_bnds b2: b2_bnds ztop: ztop zsurf1: zsurf1 zsurf2: zsurf2", "z_factors":"a: a b1: b1 b2: b2 ztop: ztop zsurf1: zsurf1 zsurf2: zsurf2" }, + "smooth_level_half":{ + "axis":"Z", + "bounds_values":"", + "climatology":"", + "formula":"z = a*ztop + b1*zsurf1 + b2*zsurf2", + "generic_level_name":"alevhalf", + "long_name":"atmosphere smooth level vertical (SLEVE) coordinate", + "must_have_bounds":"no", + "out_name":"lev", + "positive":"up", + "requested":"", + "requested_bounds":"", + "standard_name":"atmosphere_sleve_coordinate", + "stored_direction":"increasing", + "tolerance":"", + "type":"", + "units":"m", + "valid_max":"800000.0", + "valid_min":"-200.0", + "value":"", + "z_bounds_factors":"a: a_bnds b1: b1_bnds b2: b2_bnds ztop: ztop zsurf1: zsurf1 zsurf2: zsurf2", + "z_factors":"a: a b1: b1 b2: b2 ztop: ztop zsurf1: zsurf1 zsurf2: zsurf2" + }, "snowband":{ "axis":"", "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"Snow Depth Band", "must_have_bounds":"yes", "out_name":"snowband", @@ -1877,36 +2135,15 @@ "z_bounds_factors":"", "z_factors":"" }, - "snowdepth":{ - "axis":"Z", - "bounds_values":"", - "climatology":"", - "formula":"", - "long_name":"depth", - "must_have_bounds":"yes", - "out_name":"depth", - "positive":"down", - "requested":"", - "requested_bounds":"", - "standard_name":"depth", - "stored_direction":"increasing", - "tolerance":"", - "type":"double", - "units":"m", - "valid_max":"200.0", - "valid_min":"0.0", - "value":"", - "z_bounds_factors":"", - "z_factors":"" - }, "soilpools":{ "axis":"", "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"Soil Pools", "must_have_bounds":"no", - "out_name":"soilpools", + "out_name":"type", "positive":"", "requested":"", "requested_bounds":"", @@ -1926,6 +2163,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"Spectral Frequency Band", "must_have_bounds":"yes", "out_name":"spectband", @@ -1948,6 +2186,7 @@ "bounds_values":"", "climatology":"", "formula":"p = a*p0 + b*ps", + "generic_level_name":"alevel", "long_name":"hybrid sigma pressure coordinate", "must_have_bounds":"yes", "out_name":"lev", @@ -1965,11 +2204,35 @@ "z_bounds_factors":"p0: p0 a: a_bnds b: b_bnds ps: ps", "z_factors":"p0: p0 a: a b: b ps: ps" }, + "standard_hybrid_sigma_half":{ + "axis":"Z", + "bounds_values":"", + "climatology":"", + "formula":"p = a*p0 + b*ps", + "generic_level_name":"alevhalf", + "long_name":"hybrid sigma pressure coordinate", + "must_have_bounds":"no", + "out_name":"lev", + "positive":"down", + "requested":"", + "requested_bounds":"", + "standard_name":"atmosphere_hybrid_sigma_pressure_coordinate", + "stored_direction":"decreasing", + "tolerance":"", + "type":"", + "units":"1", + "valid_max":"1.0", + "valid_min":"0.0", + "value":"", + "z_bounds_factors":"p0: p0 a: a_bnds b: b_bnds ps: ps", + "z_factors":"p0: p0 a: a b: b ps: ps" + }, "standard_sigma":{ "axis":"Z", "bounds_values":"", "climatology":"", "formula":"p = ptop + sigma*(ps - ptop)", + "generic_level_name":"alevel", "long_name":"sigma coordinate", "must_have_bounds":"yes", "out_name":"lev", @@ -1987,11 +2250,58 @@ "z_bounds_factors":"ptop: ptop sigma: lev_bnds ps: ps", "z_factors":"ptop: ptop sigma: lev ps: ps" }, + "standard_sigma_half":{ + "axis":"Z", + "bounds_values":"", + "climatology":"", + "formula":"p = ptop + sigma*(ps - ptop)", + "generic_level_name":"alevhalf", + "long_name":"sigma coordinate", + "must_have_bounds":"no", + "out_name":"lev", + "positive":"down", + "requested":"", + "requested_bounds":"", + "standard_name":"atmosphere_sigma_coordinate", + "stored_direction":"decreasing", + "tolerance":"", + "type":"", + "units":"", + "valid_max":"1.0", + "valid_min":"0.0", + "value":"", + "z_bounds_factors":"ptop: ptop sigma: lev_bnds ps: ps", + "z_factors":"ptop: ptop sigma: lev ps: ps" + }, + "stempzero":{ + "axis":"Z", + "bounds_values":"", + "climatology":"", + "formula":"", + "generic_level_name":"", + "long_name":"Soil Temperature Zero", + "must_have_bounds":"no", + "out_name":"stempzero", + "positive":"", + "requested":"", + "requested_bounds":"", + "standard_name":"soil_temperature", + "stored_direction":"", + "tolerance":"", + "type":"double", + "units":"degC", + "valid_max":"", + "valid_min":"", + "value":"0.0", + "z_bounds_factors":"", + "z_factors":"" + }, "sza5":{ "axis":"", "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"solar zenith angle", "must_have_bounds":"no", "out_name":"sza", @@ -2020,6 +2330,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"cloud optical thickness", "must_have_bounds":"yes", "out_name":"tau", @@ -2065,6 +2376,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"time", "must_have_bounds":"yes", "out_name":"time", @@ -2087,6 +2399,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"time", "must_have_bounds":"no", "out_name":"time", @@ -2109,6 +2422,7 @@ "bounds_values":"", "climatology":"yes", "formula":"", + "generic_level_name":"", "long_name":"time", "must_have_bounds":"yes", "out_name":"time", @@ -2131,6 +2445,7 @@ "bounds_values":"", "climatology":"yes", "formula":"", + "generic_level_name":"", "long_name":"time", "must_have_bounds":"yes", "out_name":"time", @@ -2153,6 +2468,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"surface type", "must_have_bounds":"no", "out_name":"type", @@ -2175,6 +2491,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"Burnt vegetation area type", "must_have_bounds":"no", "out_name":"type", @@ -2192,11 +2509,81 @@ "z_bounds_factors":"", "z_factors":"" }, + "typec3crop":{ + "axis":"", + "bounds_values":"", + "climatology":"", + "formula":"", + "generic_level_name":"", + "long_name":"surface type", + "must_have_bounds":"no", + "out_name":"type", + "positive":"", + "requested":"", + "requested_bounds":"", + "standard_name":"area_type", + "stored_direction":"", + "tolerance":"", + "type":"character", + "units":"", + "valid_max":"", + "valid_min":"", + "value":"crops_of_c3_plant_functional_types", + "z_bounds_factors":"", + "z_factors":"" + }, + "typec3natg":{ + "axis":"", + "bounds_values":"", + "climatology":"", + "formula":"", + "generic_level_name":"", + "long_name":"C3 Natural grass area type", + "must_have_bounds":"no", + "out_name":"type", + "positive":"", + "requested":"", + "requested_bounds":"", + "standard_name":"area_type", + "stored_direction":"", + "tolerance":"", + "type":"character", + "units":"", + "valid_max":"", + "valid_min":"", + "value":"natural_grasses_of_c3_plant_functional_types", + "z_bounds_factors":"", + "z_factors":"" + }, + "typec3pastures":{ + "axis":"", + "bounds_values":"", + "climatology":"", + "formula":"", + "generic_level_name":"", + "long_name":"C3 Pastures area type", + "must_have_bounds":"no", + "out_name":"type", + "positive":"", + "requested":"", + "requested_bounds":"", + "standard_name":"area_type", + "stored_direction":"", + "tolerance":"", + "type":"character", + "units":"", + "valid_max":"", + "valid_min":"", + "value":"pastures_of_c3_plant_functional_types", + "z_bounds_factors":"", + "z_factors":"" + }, "typec3pft":{ "axis":"", "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"surface type", "must_have_bounds":"no", "out_name":"type", @@ -2214,11 +2601,81 @@ "z_bounds_factors":"", "z_factors":"" }, + "typec4crop":{ + "axis":"", + "bounds_values":"", + "climatology":"", + "formula":"", + "generic_level_name":"", + "long_name":"surface type", + "must_have_bounds":"no", + "out_name":"type", + "positive":"", + "requested":"", + "requested_bounds":"", + "standard_name":"area_type", + "stored_direction":"", + "tolerance":"", + "type":"character", + "units":"", + "valid_max":"", + "valid_min":"", + "value":"crops_of_c4_plant_functional_types", + "z_bounds_factors":"", + "z_factors":"" + }, + "typec4natg":{ + "axis":"", + "bounds_values":"", + "climatology":"", + "formula":"", + "generic_level_name":"", + "long_name":"C4 Natural grass area type", + "must_have_bounds":"no", + "out_name":"type", + "positive":"", + "requested":"", + "requested_bounds":"", + "standard_name":"area_type", + "stored_direction":"", + "tolerance":"", + "type":"character", + "units":"", + "valid_max":"", + "valid_min":"", + "value":"natural_grasses_of_c4_plant_functional_types", + "z_bounds_factors":"", + "z_factors":"" + }, + "typec4pastures":{ + "axis":"", + "bounds_values":"", + "climatology":"", + "formula":"", + "generic_level_name":"", + "long_name":"C4 Pastures area type", + "must_have_bounds":"no", + "out_name":"type", + "positive":"", + "requested":"", + "requested_bounds":"", + "standard_name":"area_type", + "stored_direction":"", + "tolerance":"", + "type":"character", + "units":"", + "valid_max":"", + "valid_min":"", + "value":"pastures_of_c4_plant_functional_types", + "z_bounds_factors":"", + "z_factors":"" + }, "typec4pft":{ "axis":"", "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"surface type", "must_have_bounds":"no", "out_name":"type", @@ -2241,6 +2698,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"Cloud area type", "must_have_bounds":"no", "out_name":"type", @@ -2263,6 +2721,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"Crop area type", "must_have_bounds":"no", "out_name":"type", @@ -2285,6 +2744,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"Floating Ice Shelf area type", "must_have_bounds":"no", "out_name":"type", @@ -2307,6 +2767,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"Grounded Ice Sheet area type", "must_have_bounds":"no", "out_name":"type", @@ -2329,6 +2790,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"Land area type", "must_have_bounds":"no", "out_name":"type", @@ -2351,6 +2813,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"Land Ice area type", "must_have_bounds":"no", "out_name":"type", @@ -2373,6 +2836,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"Melt pond area type", "must_have_bounds":"no", "out_name":"type", @@ -2395,6 +2859,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"Natural grass area type", "must_have_bounds":"no", "out_name":"type", @@ -2417,6 +2882,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"Non-Woody Vegetation area type", "must_have_bounds":"no", "out_name":"type", @@ -2430,7 +2896,7 @@ "units":"", "valid_max":"", "valid_min":"", - "value":"non_woody_vegetation", + "value":"herbaceous_vegetation", "z_bounds_factors":"", "z_factors":"" }, @@ -2439,6 +2905,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"Pasture area type", "must_have_bounds":"no", "out_name":"type", @@ -2461,6 +2928,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"surface type", "must_have_bounds":"no", "out_name":"type", @@ -2483,6 +2951,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"surface type", "must_have_bounds":"no", "out_name":"type", @@ -2505,6 +2974,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"Residual area", "must_have_bounds":"no", "out_name":"type", @@ -2527,6 +2997,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"surface type", "must_have_bounds":"no", "out_name":"type", @@ -2549,6 +3020,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"Ocean area type", "must_have_bounds":"no", "out_name":"type", @@ -2571,6 +3043,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"surface type", "must_have_bounds":"no", "out_name":"type", @@ -2593,6 +3066,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"Shrub area type", "must_have_bounds":"no", "out_name":"type", @@ -2615,6 +3089,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"Sea Ice area type", "must_have_bounds":"no", "out_name":"type", @@ -2632,11 +3107,35 @@ "z_bounds_factors":"", "z_factors":"" }, + "typesirdg":{ + "axis":"", + "bounds_values":"", + "climatology":"", + "formula":"", + "generic_level_name":"", + "long_name":"Sea Ice Ridge area type", + "must_have_bounds":"no", + "out_name":"type", + "positive":"", + "requested":"", + "requested_bounds":"", + "standard_name":"area_type", + "stored_direction":"", + "tolerance":"", + "type":"character", + "units":"", + "valid_max":"", + "valid_min":"", + "value":"sea_ice_ridges", + "z_bounds_factors":"", + "z_factors":"" + }, "typetree":{ "axis":"", "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"Tree area type", "must_have_bounds":"no", "out_name":"type", @@ -2659,6 +3158,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"Tree area type (Broadleaf Deciduous)", "must_have_bounds":"no", "out_name":"type", @@ -2681,6 +3181,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"Tree area type (Broadleaf Evergreen)", "must_have_bounds":"no", "out_name":"type", @@ -2703,7 +3204,8 @@ "bounds_values":"", "climatology":"", "formula":"", - "long_name":"Tree area type (Narrowleaf Deciduous)", + "generic_level_name":"", + "long_name":"Tree area type (Needleleaf Deciduous)", "must_have_bounds":"no", "out_name":"type", "positive":"", @@ -2725,7 +3227,8 @@ "bounds_values":"", "climatology":"", "formula":"", - "long_name":"Tree area type (Narrowleaf Evergreen)", + "generic_level_name":"", + "long_name":"Tree area type (Needleleaf Evergreen)", "must_have_bounds":"no", "out_name":"type", "positive":"", @@ -2747,6 +3250,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"Vegetation area type", "must_have_bounds":"no", "out_name":"type", @@ -2769,6 +3273,7 @@ "bounds_values":"", "climatology":"", "formula":"", + "generic_level_name":"", "long_name":"Wetland", "must_have_bounds":"no", "out_name":"type", @@ -2782,7 +3287,7 @@ "units":"", "valid_max":"", "valid_min":"", - "value":"", + "value":"wetland", "z_bounds_factors":"", "z_factors":"" }, @@ -2791,7 +3296,8 @@ "bounds_values":"", "climatology":"", "formula":"", - "long_name":"plant functional type", + "generic_level_name":"", + "long_name":"Vegetation or Land Cover Type", "must_have_bounds":"no", "out_name":"type", "positive":"", @@ -2813,7 +3319,8 @@ "bounds_values":"", "climatology":"", "formula":"", - "long_name":"__unset__", + "generic_level_name":"", + "long_name":"X-coordinate of Antarctic grid", "must_have_bounds":"", "out_name":"xant", "positive":"", @@ -2835,7 +3342,8 @@ "bounds_values":"", "climatology":"", "formula":"", - "long_name":"__unset__", + "generic_level_name":"", + "long_name":"X-coordinate of Greenland grid", "must_have_bounds":"", "out_name":"xgre", "positive":"", @@ -2857,7 +3365,8 @@ "bounds_values":"", "climatology":"", "formula":"", - "long_name":"__unset__", + "generic_level_name":"", + "long_name":"Y-coordinate of Antarctic grid", "must_have_bounds":"", "out_name":"yant", "positive":"", @@ -2879,7 +3388,8 @@ "bounds_values":"", "climatology":"", "formula":"", - "long_name":"__unset__", + "generic_level_name":"", + "long_name":"Y-coordinate of Greenland grid", "must_have_bounds":"", "out_name":"ygre", "positive":"", diff --git a/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_formula_terms.json b/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_formula_terms.json index 08da1580cb..2c4018a875 100644 --- a/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_formula_terms.json +++ b/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_formula_terms.json @@ -14,6 +14,20 @@ "type":"double", "units":"" }, + "a_half":{ + "dimensions":"alevhalf", + "long_name":"vertical coordinate formula term: a(k)", + "out_name":"a", + "type":"double", + "units":"" + }, + "a_half_bnds":{ + "dimensions":"alevhalf", + "long_name":"vertical coordinate formula term: a(k+1/2)", + "out_name":"a_bnds", + "type":"double", + "units":"" + }, "ap":{ "dimensions":"alevel", "long_name":"vertical coordinate formula term: ap(k)", @@ -28,6 +42,20 @@ "type":"double", "units":"Pa" }, + "ap_half":{ + "dimensions":"alevhalf", + "long_name":"vertical coordinate formula term: ap(k)", + "out_name":"ap", + "type":"double", + "units":"Pa" + }, + "ap_half_bnds":{ + "dimensions":"alevel", + "long_name":"vertical coordinate formula term: ap(k+1/2)", + "out_name":"ap_bnds", + "type":"double", + "units":"Pa" + }, "b":{ "dimensions":"alevel", "long_name":"vertical coordinate formula term: b(k)", @@ -35,6 +63,34 @@ "type":"double", "units":"" }, + "b1":{ + "dimensions":"alevel", + "long_name":"vertical coordinate formula term: b1(k)", + "out_name":"b1", + "type":"double", + "units":"" + }, + "b1_half":{ + "dimensions":"alevhalf", + "long_name":"vertical coordinate formula term: b1(k)", + "out_name":"b1", + "type":"double", + "units":"" + }, + "b2":{ + "dimensions":"alevel", + "long_name":"vertical coordinate formula term: b2(k)", + "out_name":"b2", + "type":"double", + "units":"" + }, + "b2_half":{ + "dimensions":"alevhalf", + "long_name":"vertical coordinate formula term: b2(k)", + "out_name":"b2", + "type":"double", + "units":"" + }, "b_bnds":{ "dimensions":"alevel", "long_name":"vertical coordinate formula term: b(k+1/2)", @@ -42,6 +98,20 @@ "type":"double", "units":"" }, + "b_half":{ + "dimensions":"alevhalf", + "long_name":"vertical coordinate formula term: b(k)", + "out_name":"b", + "type":"double", + "units":"" + }, + "b_half_bnds":{ + "dimensions":"alevhalf", + "long_name":"vertical coordinate formula term: b(k+1/2)", + "out_name":"b_bnds", + "type":"double", + "units":"" + }, "depth":{ "dimensions":"longitude latitude", "long_name":"Sea Floor Depth: formula term: thetao", @@ -102,7 +172,7 @@ "dimensions":"", "long_name":"vertical coordinate formula term: reference pressure", "out_name":"p0", - "type":"", + "type":"double", "units":"Pa" }, "ps":{ @@ -130,7 +200,7 @@ "dimensions":"", "long_name":"pressure at top of model", "out_name":"ptop", - "type":"", + "type":"double", "units":"Pa" }, "sigma":{ @@ -179,7 +249,7 @@ "dimensions":"", "long_name":"height of top of model", "out_name":"ztop", - "type":"", + "type":"double", "units":"m" } } diff --git a/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_fx.json b/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_fx.json index d36c2cae21..5e86223bdb 100644 --- a/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_fx.json +++ b/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_fx.json @@ -1,17 +1,17 @@ { "Header":{ - "#dataRequest_specs_version":"01.00.21", + "#dataRequest_specs_version":"01.00.29", "#mip_era":"CMIP6", "Conventions":"CF-1.7 ODS-2.1", "approx_interval":"0.00000", - "cmor_version":"3.2", + "cmor_version":"3.4", "data_specs_version":"2.1.0", "generic_levels":"alevel", "int_missing_value":"-2147483648", "missing_value":"1e20", "product":"observations", "realm":"fx", - "table_date":"07 March 2018", + "table_date":"11 April 2019", "table_id":"Table obs4MIPs_fx" }, "variable_entry":{ @@ -21,7 +21,7 @@ "comment":"For atmospheres with more than 1 mesh (e.g., staggered grids), report areas that apply to surface vertical fluxes of energy.", "dimensions":"longitude latitude", "frequency":"fx", - "long_name":"Grid-Cell Area for Atmospheric Variables", + "long_name":"Grid-Cell Area for Atmospheric Grid Variables", "modeling_realm":"atmos land", "ok_max_mean_abs":"", "ok_min_mean_abs":"", @@ -57,7 +57,7 @@ "comment":"The bulk water content retained by the soil at -33 J/kg of suction pressure, expressed as mass per unit land area; report as missing where there is no land", "dimensions":"longitude latitude", "frequency":"fx", - "long_name":"Capacity of Soil to Store Water", + "long_name":"Capacity of Soil to Store Water (Field Capacity)", "modeling_realm":"land", "ok_max_mean_abs":"", "ok_min_mean_abs":"", @@ -111,7 +111,7 @@ "comment":"Fraction of grid cell covered by land ice (ice sheet, ice shelf, ice cap, glacier)", "dimensions":"longitude latitude typeli", "frequency":"fx", - "long_name":"Fraction of Grid Cell Covered with Glacier", + "long_name":"Land Ice Area Percentage", "modeling_realm":"land", "ok_max_mean_abs":"", "ok_min_mean_abs":"", @@ -129,7 +129,7 @@ "comment":"Please express 'X_area_fraction' as the percentage of horizontal area occupied by X.", "dimensions":"longitude latitude typeland", "frequency":"fx", - "long_name":"Land Area Fraction", + "long_name":"Percentage of the grid cell occupied by land (including lakes)", "modeling_realm":"atmos", "ok_max_mean_abs":"", "ok_min_mean_abs":"", @@ -144,7 +144,7 @@ "zfull":{ "cell_measures":"area: areacella", "cell_methods":"area: mean", - "comment":"", + "comment":"Height of full model levels above a reference ellipsoid. A reference ellipsoid is a mathematical figure that approximates the geoid. The geoid is a surface of constant geopotential with which mean sea level would coincide if the ocean were at rest. The ellipsoid is an approximation because the geoid is an irregular shape. A number of reference ellipsoids are defined for use in the field of geodesy. To specify which reference ellipsoid is being used, a grid_mapping variable should be attached to the data variable as described in Chapter 5.6 of the CF Convention.", "dimensions":"longitude latitude alevel", "frequency":"fx", "long_name":"Altitude of Model Full-Levels", diff --git a/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_grids.json b/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_grids.json index 276beaf467..49a4195c74 100644 --- a/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_grids.json +++ b/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_grids.json @@ -1,12 +1,12 @@ { "Header":{ - "#dataRequest_specs_version":"01.00.21", + "#dataRequest_specs_version":"01.00.29", "Conventions":"CF-1.7 ODS-2.1", - "cmor_version":"3.2", + "cmor_version":"3.4", "data_specs_version":"2.1.0", "missing_value":"1e20", "product":"observations", - "table_date":"07 March 2018", + "table_date":"11 April 2019", "table_id":"Table obs4MIPs_grids" }, "axis_entry":{ @@ -15,7 +15,7 @@ "long_name":"latitude in rotated pole grid", "out_name":"rlat", "standard_name":"grid_latitude", - "type":"", + "type":"double", "units":"degrees" }, "grid_longitude":{ @@ -23,7 +23,7 @@ "long_name":"longitude in rotated pole grid", "out_name":"rlon", "standard_name":"grid_longitude", - "type":"", + "type":"double", "units":"degrees" }, "i_index":{ @@ -79,7 +79,7 @@ "long_name":"x coordinate of projection", "out_name":"", "standard_name":"projection_x_coordinate", - "type":"", + "type":"double", "units":"m" }, "x_deg":{ @@ -87,7 +87,7 @@ "long_name":"x coordinate of projection", "out_name":"x", "standard_name":"projection_x_coordinate", - "type":"", + "type":"double", "units":"degrees" }, "y":{ @@ -95,7 +95,7 @@ "long_name":"y coordinate of projection", "out_name":"", "standard_name":"projection_y_coordinate", - "type":"", + "type":"double", "units":"m" }, "y_deg":{ @@ -103,7 +103,7 @@ "long_name":"y coordinate of projection", "out_name":"y", "standard_name":"projection_y_coordinate", - "type":"", + "type":"double", "units":"degrees" } }, @@ -117,18 +117,20 @@ "variable_entry":{ "latitude":{ "dimensions":"longitude latitude", - "long_name":"", + "long_name":"latitude", "out_name":"latitude", - "standard_name":"", + "standard_name":"latitude", + "type":"double", "units":"degrees_north", "valid_max":"90.0", "valid_min":"-90.0" }, "longitude":{ "dimensions":"longitude latitude", - "long_name":"", + "long_name":"longitude", "out_name":"longitude", - "standard_name":"", + "standard_name":"longitude", + "type":"double", "units":"degrees_east", "valid_max":"360.0", "valid_min":"0.0" @@ -138,6 +140,7 @@ "long_name":"", "out_name":"vertices_latitude", "standard_name":"", + "type":"double", "units":"degrees_north", "valid_max":"90.0", "valid_min":"-90.0" @@ -147,6 +150,7 @@ "long_name":"", "out_name":"vertices_longitude", "standard_name":"", + "type":"double", "units":"degrees_east", "valid_max":"360.0", "valid_min":"0.0" diff --git a/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_monNobs.json b/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_monNobs.json index da00c57753..b4d2e69547 100644 --- a/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_monNobs.json +++ b/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_monNobs.json @@ -3,14 +3,14 @@ "#mip_era":"CMIP6", "Conventions":"CF-1.7 ODS-2.1", "approx_interval":"30.00000", - "cmor_version":"3.2", + "cmor_version":"3.4", "data_specs_version":"2.1.0", "generic_levels":"alevel alevhalf", "int_missing_value":"-2147483648", "missing_value":"1e20", "product":"observations", "realm":"aerosol atmos atmosChem land landIce ocean ocnBgchem seaIce", - "table_date":"07 March 2018", + "table_date":"11 April 2019", "table_id":"Table obs4MIPs_monNobs" }, "variable_entry":{ diff --git a/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_monStderr.json b/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_monStderr.json index 3c4b3814b8..da151d954b 100644 --- a/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_monStderr.json +++ b/esmvaltool/cmor/tables/obs4mips/Tables/obs4MIPs_monStderr.json @@ -3,14 +3,14 @@ "#mip_era":"CMIP6", "Conventions":"CF-1.7 ODS-2.1", "approx_interval":"30.00000", - "cmor_version":"3.2", + "cmor_version":"3.4", "data_specs_version":"2.1.0", "generic_levels":"alevel alevhalf", "int_missing_value":"-2147483648", "missing_value":"1e20", "product":"observations", "realm":"aerosol atmos atmosChem land landIce ocean ocnBgchem seaIce", - "table_date":"07 March 2018", + "table_date":"11 April 2019", "table_id":"Table obs4MIPs_monStderr" }, "variable_entry":{ diff --git a/esmvaltool/cmor/tables/obs4mips/obs4MIPs_grid_label.json b/esmvaltool/cmor/tables/obs4mips/obs4MIPs_grid_label.json index fa079918e2..f4d887da7f 100644 --- a/esmvaltool/cmor/tables/obs4mips/obs4MIPs_grid_label.json +++ b/esmvaltool/cmor/tables/obs4mips/obs4MIPs_grid_label.json @@ -1,49 +1,63 @@ { "grid_label":{ - "gm":"global mean data", - "gn":"data reported on a model's native grid", - "gna":"data reported on a native grid in the region of Antarctica", - "gng":"data reported on a native grid in the region of Greenland", - "gnz":"zonal mean data reported on a model's native latitude grid", - "gr":"regridded data reported on the data provider's preferred target grid", - "gr1":"regridded data reported on a grid other than the native grid and other than the preferred target grid", - "gr1a":"regridded data reported in the region of Antarctica on a grid other than the native grid and other than the preferred target grid", - "gr1g":"regridded data reported in the region of Greenland on a grid other than the native grid and other than the preferred target grid", - "gr1z":"regridded zonal mean data reported on a grid other than the native latitude grid and other than the preferred latitude target grid", - "gr2":"regridded data reported on a grid other than the native grid and other than the preferred target grid", - "gr2a":"regridded data reported in the region of Antarctica on a grid other than the native grid and other than the preferred target grid", - "gr2g":"regridded data reported in the region of Greenland on a grid other than the native grid and other than the preferred target grid", - "gr2z":"regridded zonal mean data reported on a grid other than the native latitude grid and other than the preferred latitude target grid", - "gr3":"regridded data reported on a grid other than the native grid and other than the preferred target grid", - "gr3a":"regridded data reported in the region of Antarctica on a grid other than the native grid and other than the preferred target grid", - "gr3g":"regridded data reported in the region of Greenland on a grid other than the native grid and other than the preferred target grid", - "gr3z":"regridded zonal mean data reported on a grid other than the native latitude grid and other than the preferred latitude target grid", - "gr4":"regridded data reported on a grid other than the native grid and other than the preferred target grid", - "gr4a":"regridded data reported in the region of Antarctica on a grid other than the native grid and other than the preferred target grid", - "gr4g":"regridded data reported in the region of Greenland on a grid other than the native grid and other than the preferred target grid", - "gr4z":"regridded zonal mean data reported on a grid other than the native latitude grid and other than the preferred latitude target grid", - "gr5":"regridded data reported on a grid other than the native grid and other than the preferred target grid", - "gr5a":"regridded data reported in the region of Antarctica on a grid other than the native grid and other than the preferred target grid", - "gr5g":"regridded data reported in the region of Greenland on a grid other than the native grid and other than the preferred target grid", - "gr5z":"regridded zonal mean data reported on a grid other than the native latitude grid and other than the preferred latitude target grid", - "gr6":"regridded data reported on a grid other than the native grid and other than the preferred target grid", - "gr6a":"regridded data reported in the region of Antarctica on a grid other than the native grid and other than the preferred target grid", - "gr6g":"regridded data reported in the region of Greenland on a grid other than the native grid and other than the preferred target grid", - "gr6z":"regridded zonal mean data reported on a grid other than the native latitude grid and other than the preferred latitude target grid", - "gr7":"regridded data reported on a grid other than the native grid and other than the preferred target grid", - "gr7a":"regridded data reported in the region of Antarctica on a grid other than the native grid and other than the preferred target grid", - "gr7g":"regridded data reported in the region of Greenland on a grid other than the native grid and other than the preferred target grid", - "gr7z":"regridded zonal mean data reported on a grid other than the native latitude grid and other than the preferred latitude target grid", - "gr8":"regridded data reported on a grid other than the native grid and other than the preferred target grid", - "gr8a":"regridded data reported in the region of Antarctica on a grid other than the native grid and other than the preferred target grid", - "gr8g":"regridded data reported in the region of Greenland on a grid other than the native grid and other than the preferred target grid", - "gr8z":"regridded zonal mean data reported on a grid other than the native latitude grid and other than the preferred latitude target grid", - "gr9":"regridded data reported on a grid other than the native grid and other than the preferred target grid", - "gr9a":"regridded data reported in the region of Antarctica on a grid other than the native grid and other than the preferred target grid", - "gr9g":"regridded data reported in the region of Greenland on a grid other than the native grid and other than the preferred target grid", - "gr9z":"regridded zonal mean data reported on a grid other than the native latitude grid and other than the preferred latitude target grid", - "gra":"regridded data in the region of Antarctica reported on the data provider's preferred target grid", - "grg":"regridded data in the region of Greenland reported on the data provider's preferred target grid", - "grz":"regridded zonal mean data reported on the data provider's preferred latitude target grid" + "grid_label":{ + "gm":"global mean data", + "gn":"data reported on a model's native grid", + "gnNH":"data reported on a native grid in the Northern Hemisphere", + "gnSH":"data reported on a native grid in the Southern Hemisphere", + "gna":"data reported on a native grid in the region of Antarctica", + "gng":"data reported on a native grid in the region of Greenland", + "gnz":"zonal mean data reported on a model's native latitude grid", + "gr":"regridded data reported on the data provider's preferred target grid", + "gr1":"regridded data reported on a grid other than the native grid and other than the preferred target grid", + "gr1a":"regridded data reported in the region of Antarctica on a grid other than the native grid and other than the preferred target grid", + "gr1g":"regridded data reported in the region of Greenland on a grid other than the native grid and other than the preferred target grid", + "gr1z":"regridded zonal mean data reported on a grid other than the native latitude grid and other than the preferred latitude target grid", + "gr2":"regridded data reported on a grid other than the native grid and other than the preferred target grid", + "gr2a":"regridded data reported in the region of Antarctica on a grid other than the native grid and other than the preferred target grid", + "gr2g":"regridded data reported in the region of Greenland on a grid other than the native grid and other than the preferred target grid", + "gr2z":"regridded zonal mean data reported on a grid other than the native latitude grid and other than the preferred latitude target grid", + "gr3":"regridded data reported on a grid other than the native grid and other than the preferred target grid", + "gr3a":"regridded data reported in the region of Antarctica on a grid other than the native grid and other than the preferred target grid", + "gr3g":"regridded data reported in the region of Greenland on a grid other than the native grid and other than the preferred target grid", + "gr3z":"regridded zonal mean data reported on a grid other than the native latitude grid and other than the preferred latitude target grid", + "gr4":"regridded data reported on a grid other than the native grid and other than the preferred target grid", + "gr4a":"regridded data reported in the region of Antarctica on a grid other than the native grid and other than the preferred target grid", + "gr4g":"regridded data reported in the region of Greenland on a grid other than the native grid and other than the preferred target grid", + "gr4z":"regridded zonal mean data reported on a grid other than the native latitude grid and other than the preferred latitude target grid", + "gr5":"regridded data reported on a grid other than the native grid and other than the preferred target grid", + "gr5a":"regridded data reported in the region of Antarctica on a grid other than the native grid and other than the preferred target grid", + "gr5g":"regridded data reported in the region of Greenland on a grid other than the native grid and other than the preferred target grid", + "gr5z":"regridded zonal mean data reported on a grid other than the native latitude grid and other than the preferred latitude target grid", + "gr6":"regridded data reported on a grid other than the native grid and other than the preferred target grid", + "gr6a":"regridded data reported in the region of Antarctica on a grid other than the native grid and other than the preferred target grid", + "gr6g":"regridded data reported in the region of Greenland on a grid other than the native grid and other than the preferred target grid", + "gr6z":"regridded zonal mean data reported on a grid other than the native latitude grid and other than the preferred latitude target grid", + "gr7":"regridded data reported on a grid other than the native grid and other than the preferred target grid", + "gr7a":"regridded data reported in the region of Antarctica on a grid other than the native grid and other than the preferred target grid", + "gr7g":"regridded data reported in the region of Greenland on a grid other than the native grid and other than the preferred target grid", + "gr7z":"regridded zonal mean data reported on a grid other than the native latitude grid and other than the preferred latitude target grid", + "gr8":"regridded data reported on a grid other than the native grid and other than the preferred target grid", + "gr8a":"regridded data reported in the region of Antarctica on a grid other than the native grid and other than the preferred target grid", + "gr8g":"regridded data reported in the region of Greenland on a grid other than the native grid and other than the preferred target grid", + "gr8z":"regridded zonal mean data reported on a grid other than the native latitude grid and other than the preferred latitude target grid", + "gr9":"regridded data reported on a grid other than the native grid and other than the preferred target grid", + "gr9a":"regridded data reported in the region of Antarctica on a grid other than the native grid and other than the preferred target grid", + "gr9g":"regridded data reported in the region of Greenland on a grid other than the native grid and other than the preferred target grid", + "gr9z":"regridded zonal mean data reported on a grid other than the native latitude grid and other than the preferred latitude target grid", + "gra":"regridded data in the region of Antarctica reported on the data provider's preferred target grid", + "grg":"regridded data in the region of Greenland reported on the data provider's preferred target grid", + "grz":"regridded zonal mean data reported on the data provider's preferred latitude target grid" + }, + "version_metadata":{ + "CV_collection_modified":"Mon Mar 25 14:32:35 2019 -0700", + "CV_collection_version":"6.2.20.1", + "author":"Paul J. Durack ", + "grid_label_CV_modified":"Fri Sep 8 18:12:00 2017 -0700", + "grid_label_CV_note":"Issue395 durack1 augment grid_label with description (#401)", + "institution_id":"PCMDI", + "previous_commit":"690451863bfd7a92a6fa13d879a9df6af32e0379", + "specs_doc":"v6.2.7 (10th September 2018; https://goo.gl/v1drZl)" + } } } \ No newline at end of file diff --git a/esmvaltool/cmor/tables/obs4mips/obs4MIPs_institution_id.json b/esmvaltool/cmor/tables/obs4mips/obs4MIPs_institution_id.json index 8ac6bca123..7f852179bd 100644 --- a/esmvaltool/cmor/tables/obs4mips/obs4MIPs_institution_id.json +++ b/esmvaltool/cmor/tables/obs4mips/obs4MIPs_institution_id.json @@ -1,6 +1,8 @@ { "institution_id":{ + "CNES":"Centre national d'etudes spatiales", "DWD":"Deutscher Wetterdienst, Offenbach 63067, Germany", + "NASA-GSFC":"National Aeronautics and Space Administration, Goddard Space Flight Center", "NASA-JPL":"NASA's Jet Propulsion Laboratory, Pasadena, CA 91109, USA", "NOAA-NCEI":"NOAA's National Centers for Environmental Information, Asheville, NC 28801, USA", "PCMDI":"Program for Climate Model Diagnosis and Intercomparison, Lawrence Livermore National Laboratory, Livermore, CA 94550, USA", diff --git a/esmvaltool/cmor/tables/obs4mips/obs4MIPs_source_id.json b/esmvaltool/cmor/tables/obs4mips/obs4MIPs_source_id.json index 21ea8cef00..eb461b82f2 100644 --- a/esmvaltool/cmor/tables/obs4mips/obs4MIPs_source_id.json +++ b/esmvaltool/cmor/tables/obs4mips/obs4MIPs_source_id.json @@ -16,6 +16,54 @@ ], "source_version_number":"1.0" }, + "AIRS-2-0":{ + "institution_id":"NASA-JPL", + "region":[ + "global" + ], + "release_year":"2011", + "source_description":"Atmospheric Infrared Sounder", + "source_label":"AIRS", + "source_name":"AIRS", + "source_type":"satellite_retrieval", + "source_variables":[ + "hus", + "ta" + ], + "source_version_number":"2.0" + }, + "AMSRE-v7":{ + "institution_id":"RSS", + "region":[ + "global_ocean" + ], + "release_year":"2011", + "source_description":"Sea Surface Temperature from AMSR-E onboard AQUA", + "source_id":"AMSRE-v7", + "source_label":"AMRSE v7", + "source_name":"Sea Surface Temperature", + "source_type":"satellite_retrieval", + "source_variables":[ + "tos" + ], + "source_version_number":"v7" + }, + "AVISO-1-0":{ + "institution_id":"CNES", + "region":[ + "global" + ], + "release_year":"2011", + "source_description":"Sea Surface Height Above Geoid", + "source_id":"AVISO-1-0", + "source_label":"AVISO 1 0", + "source_name":"SSALTO/DUACS", + "source_type":"satellite_retrieval", + "source_variables":[ + "zos" + ], + "source_version_number":"1.0" + }, "Aura-MLS-v04-2":{ "institution_id":"NASA-JPL", "region":[ @@ -202,6 +250,51 @@ ], "source_version_number":"1.3" }, + "GPCP-1DD":{ + "institution_id":"NASA-GSFC", + "region":[ + "global" + ], + "release_year":"2013", + "source_description":"Global Precipitation Climatology Project One Degree Daily", + "source_label":"GPCP 1DD", + "source_name":"GPCP 1DD", + "source_type":"satellite_blended", + "source_variables":[ + "pr" + ], + "source_version_number":"1.3" + }, + "GPCP-SG":{ + "institution_id":"NASA-GSFC", + "region":[ + "global" + ], + "release_year":"2016", + "source_description":"Global Precipitation Climatology Project Satellite-Gauge", + "source_label":"GPCP SG", + "source_name":"GPCP SG", + "source_type":"satellite_blended", + "source_variables":[ + "pr" + ], + "source_version_number":"2.3" + }, + "MODIS-1-0":{ + "institution_id":"NASA-GSFC", + "region":[ + "global" + ], + "release_year":"2011", + "source_description":"Atmospheric Infrared Sounder", + "source_label":"MODIS", + "source_name":"MODIS", + "source_type":"satellite_retrieval", + "source_variables":[ + "clt" + ], + "source_version_number":"1.0" + }, "NOAA-NCEI-AVHRR-NDVI-4-0":{ "institution_id":"NOAA-NCEI", "region":[ @@ -266,6 +359,21 @@ ], "source_version_number":"4.0" }, + "NOAA-NCEI-HIRS-OLR-1-2":{ + "institution_id":"NOAA-NCEI", + "region":[ + "global" + ], + "release_year":"2014", + "source_description":"HIRS Outgoing Longwave Radiation", + "source_label":"NOAA NCEI HIRS OLR", + "source_name":"NOAA NCEI HIRS OLR", + "source_type":"satellite_retrieval", + "source_variables":[ + "rlut" + ], + "source_version_number":"1.2" + }, "NOAA-NCEI-LAI-4-0":{ "institution_id":"NOAA-NCEI", "region":[ @@ -282,6 +390,21 @@ ], "source_version_number":"4.0" }, + "NOAA-NCEI-OISST-2-0":{ + "institution_id":"NOAA-NCEI", + "region":[ + "global_ocean" + ], + "release_year":"2008", + "source_description":"Optimal Interpolation Sea Surface Temperature", + "source_label":"NOAA NCEI OISST", + "source_name":"NOAA NCEI OISST", + "source_type":"satellite_blended", + "source_variables":[ + "tos" + ], + "source_version_number":"2.0" + }, "NOAA-NCEI-PERSIANN-1-1":{ "institution_id":"NOAA-NCEI", "region":[ @@ -298,6 +421,22 @@ ], "source_version_number":"1.1" }, + "NOAA-NCEI-SSMI-SeaIce-2-0":{ + "institution_id":"NOAA-NCEI", + "region":[ + "arctic_ocean", + "southern_ocean" + ], + "release_year":"2013", + "source_description":"SSMI Passive Microwave Sea Ice Area Fraction", + "source_label":"NOAA-NCEI-SSMI-SeaIce", + "source_name":"NOAA NCEI SSMI SeaIce", + "source_type":"satellite_retrieval", + "source_variables":[ + "siconc" + ], + "source_version_number":"2.0" + }, "NOAA-NCEI-SeaWinds-1-2":{ "institution_id":"NOAA-NCEI", "region":[ @@ -348,6 +487,40 @@ "prw" ], "source_version_number":"6.6.0" + }, + "RSS-v7":{ + "institution_id":"RSS", + "region":[ + "global_ocean" + ], + "release_year":"2011", + "source_description":"Satellite derived fields produced by RSS", + "source_id":"RSS-v7", + "source_label":"RSS-v7", + "source_name":"Satellite derived fields", + "source_type":"satellite_retrieval", + "source_variables":[ + "prw", + "sfcWind", + "tos" + ], + "source_version_number":"v7" + }, + "TES-1-0":{ + "institution_id":"NASA-JPL", + "region":[ + "global" + ], + "release_year":"2011", + "source_description":"Mole Fraction of O3", + "source_id":"TES-1-0", + "source_label":"TES 1 0", + "source_name":"JPL AURA satellite retrieval", + "source_type":"satellite_retrieval", + "source_variables":[ + "tro3" + ], + "source_version_number":"1.0" } } } diff --git a/tests/integration/cmor/test_table.py b/tests/integration/cmor/test_table.py index c9e33300a0..b92424d5b3 100644 --- a/tests/integration/cmor/test_table.py +++ b/tests/integration/cmor/test_table.py @@ -26,6 +26,14 @@ def test_custom_tables_location(self): cmor_tables_path = os.path.abspath(cmor_tables_path) CMIP6Info(cmor_tables_path) + def test_get_table_frequency(self): + """Test get table frequency""" + self.assertEqual( + self.variables_info.get_table('Amon').frequency, + 'mon' + ) + self.assertEqual(self.variables_info.get_table('day').frequency, 'day') + def test_get_variable_tas(self): """Get tas variable.""" var = self.variables_info.get_variable('Amon', 'tas') @@ -36,6 +44,16 @@ def test_get_variable_from_alias(self): var = self.variables_info.get_variable('SImon', 'sic') self.assertEqual(var.short_name, 'siconc') + def test_get_variable_from_custom(self): + """Get a variable from default.""" + var = self.variables_info.get_variable('Amon', 'swcre') + self.assertEqual(var.short_name, 'swcre') + self.assertEqual(var.frequency, 'mon') + + var = self.variables_info.get_variable('day', 'swcre') + self.assertEqual(var.short_name, 'swcre') + self.assertEqual(var.frequency, 'day') + def test_get_bad_variable(self): """Get none if a variable is not in the given table.""" self.assertIsNone(self.variables_info.get_variable('Omon', 'tas')) @@ -56,6 +74,13 @@ def setUpClass(cls): default=CustomInfo() ) + def test_get_table_frequency(self): + """Test get table frequency""" + self.assertEqual( + self.variables_info.get_table('obs4MIPs_monStderr').frequency, + 'mon' + ) + def test_custom_tables_location(self): """Test constructor with custom tables location.""" cwd = os.path.dirname(os.path.realpath(__file__)) @@ -64,10 +89,22 @@ def test_custom_tables_location(self): cmor_tables_path = os.path.abspath(cmor_tables_path) CMIP6Info(cmor_tables_path) - def test_get_variable_tas(self): - """Get tas variable.""" - var = self.variables_info.get_variable('monStderr', 'ndviStderr') + def test_get_variable_ndvi(self): + """Get ndviStderr variable. Note table name obs4MIPs_[mip]""" + var = self.variables_info.get_variable('obs4MIPs_monStderr', + 'ndviStderr') self.assertEqual(var.short_name, 'ndviStderr') + self.assertEqual(var.frequency, 'mon') + + def test_get_variable_from_custom(self): + """Get a variable from default.""" + var = self.variables_info.get_variable('obs4MIPs_Amon', 'swcre') + self.assertEqual(var.short_name, 'swcre') + self.assertEqual(var.frequency, 'mon') + + var = self.variables_info.get_variable('obs4MIPs_Aday', 'swcre') + self.assertEqual(var.short_name, 'swcre') + self.assertEqual(var.frequency, 'day') def test_get_bad_variable(self): """Get none if a variable is not in the given table.""" @@ -99,6 +136,16 @@ def test_get_variable_tas(self): var = self.variables_info.get_variable('Amon', 'tas') self.assertEqual(var.short_name, 'tas') + def test_get_variable_from_custom(self): + """Get a variable from default.""" + var = self.variables_info.get_variable('Amon', 'swcre') + self.assertEqual(var.short_name, 'swcre') + self.assertEqual(var.frequency, 'mon') + + var = self.variables_info.get_variable('day', 'swcre') + self.assertEqual(var.short_name, 'swcre') + self.assertEqual(var.frequency, 'day') + def test_get_bad_variable(self): """Get none if a variable is not in the given table.""" self.assertIsNone(self.variables_info.get_variable('Omon', 'tas'))