Difference between revisions of "CF Standard Names - OLD Submitted Atmospheric Chemistry and Aerosol Terms"

From Earth Science Information Partners (ESIP)
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{{CF-links}}
 
{{CF-links}}
  
This page is updated according to the discussions in the [http://www.cgd.ucar.edu/mailman/listinfo/cf-metadata CF mailing list], that can also be found on our [http://wiki.esipfed.org/index.php/Talk:CF_Standard_Names_-_Proposed_names_for_TF_HTAP discussion page].
+
The talbe is updated according to the discussions in the [http://www.cgd.ucar.edu/mailman/listinfo/cf-metadata CF mailing list], that can also be found on our [http://wiki.esipfed.org/index.php/Talk:CF_Standard_Names_-_Proposed_names_for_TF_HTAP discussion page].
 +
 
 +
Version 1 18.08.2006<br>
 +
Version 2 26.09.2006
  
 
It is the philosophy of CF only define those standard_names for which a demand has been expressed. The proposed standard_names on this page are needed for a [http://aqm.jrc.it/HTAP/ model intercomparison] within the Task Force on Hemispheric Transport of Air Pollution [http://www.htap.org/ TF HTAP].
 
It is the philosophy of CF only define those standard_names for which a demand has been expressed. The proposed standard_names on this page are needed for a [http://aqm.jrc.it/HTAP/ model intercomparison] within the Task Force on Hemispheric Transport of Air Pollution [http://www.htap.org/ TF HTAP].
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You can directly modify the tables here, all versions are stored under 'history'. However, in order to keep track of the changes, please send an email to [[User:ChristianeTextor|ChristianeTextor]].
 
You can directly modify the tables here, all versions are stored under 'history'. However, in order to keep track of the changes, please send an email to [[User:ChristianeTextor|ChristianeTextor]].
  
 +
TABLE VERSION 2, updated
  
 
{|{{prettytable}}
 
{|{{prettytable}}
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| width="84" | Canonical unit
 
| width="84" | Canonical unit
 
| width="200,25" |  Explanation  
 
| width="200,25" |  Explanation  
 
|- style="font-size:12pt"
 
| Height="15" |
 
|
 
|
 
  
 
|- style="font-size:12pt"
 
|- style="font-size:12pt"
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|- style="background-color:#CCFFCC;font-size:12pt;font-weight:bold"
 
|- style="background-color:#CCFFCC;font-size:12pt;font-weight:bold"
| Height="15,75" | surface dry deposition flux
+
| Height="15,75" | dry deposition flux at the surface
 
  |  
 
  |  
 
  |  
 
  |  
Line 53: Line 52:
 
| Height="120" | surface_dry_deposition_mass_flux_of_all_nitrogen_oxides
 
| Height="120" | surface_dry_deposition_mass_flux_of_all_nitrogen_oxides
 
  | kg m-2 s-1
 
  | kg m-2 s-1
| 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"
+
" | 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"
  
 
|- style="font-size:12pt"
 
|- style="font-size:12pt"
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|- style="font-size:12pt"
 
|- style="font-size:12pt"
| Height="45" | surface_dry_deposition_mass_flux_of_organic_carbon_as_particulate_organic_carbon_dry_aerosol
+
| Height="45" | surface_dry_deposition_mass_flux_of_particulate_organic_carbon_as_particulate_organic_carbon_dry_aerosol
 
  | kg m-2 s-1
 
  | kg m-2 s-1
 
  | Dry deposition includes gravitational settling, impact scavenging, and turbulent deposition
 
  | Dry deposition includes gravitational settling, impact scavenging, and turbulent deposition
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|- style="font-size:12pt"
 
|- style="font-size:12pt"
| Height="30" | surface_wet_deposition_mass_flux_of_organic_carbon_as_particulate_organic_carbon_dry_aerosol
+
| Height="30" | surface_wet_deposition_mass_flux_of_particulate_organic_carbon_as_particulate_organic_carbon_dry_aerosol
 
  | kg m-2 s-1
 
  | kg m-2 s-1
 
  |  
 
  |  
Line 226: Line 226:
  
 
|- style="background-color:#CCFFCC;font-size:12pt;font-weight:bold"
 
|- style="background-color:#CCFFCC;font-size:12pt;font-weight:bold"
| Height="15,75" | emission flux at the surface
+
| Height="15,75" | emission fluxes
 
  |  
 
  |  
 
  |  
 
  |  
Line 256: Line 256:
  
 
|- style="font-size:12pt"
 
|- style="font-size:12pt"
| Height="15" | surface_emission_mass_flux_ammonia
+
| Height="15" | surface_emission_mass_flux_of_ammonia
 
  | kg m-2 s-1
 
  | kg m-2 s-1
 
  |  
 
  |  
Line 276: Line 276:
  
 
|- style="font-size:12pt"
 
|- style="font-size:12pt"
| Height="30" | surface_emission_mass_flux_of_organic_carbon_as_particulate_organic_carbon_dry_aerosol
+
| Height="30" | surface_emission_mass_flux_of_particulate_organic_carbon_as_particulate_organic_carbon_dry_aerosol
 
  | kg m-2 s-1
 
  | kg m-2 s-1
 
  |  
 
  |  
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| Height="15" | surface_emission_mass_flux_of_mercury_aerosol
 
| Height="15" | surface_emission_mass_flux_of_mercury_aerosol
 
  | kg m-2 s-1
 
  | kg m-2 s-1
 +
|
 +
 +
|- style="font-size:12pt"
 +
| Height="15" |
 +
|
 
  |  
 
  |  
  
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|- style="font-size:12pt"
 
|- style="font-size:12pt"
| Height="30" | mole_fraction_of_CO_with_lifetime_of_25_days_in_air
+
| Height="30" | mole_fraction_of_anthropogenic_non_methane_volatile_organic_compound_in_air
 
  | 1=mole mole-1
 
  | 1=mole mole-1
 
  |  
 
  |  
  
 
|- style="font-size:12pt"
 
|- style="font-size:12pt"
| Height="30" | mole_fraction_of_CO_due_to_methane_oxidation_in_air
+
| Height="30" | mole_fraction_of_biogenic_non_methane_volatile_organic_compound_in_air
 
  | 1=mole mole-1
 
  | 1=mole mole-1
 
  |  
 
  |  
  
 
|- style="font-size:12pt"
 
|- style="font-size:12pt"
| Height="30" | mole_fraction_of_CO_due_to_oxidation_of_anthropogenic_NMVOC_in_air
+
| Height="15" |
 +
|
 +
|
 +
 
 +
|- style="background-color:#CCFFCC;font-size:12pt;font-weight:bold"
 +
| Height="15,75" | HTAP experiments with tagged CO
 +
|
 +
|
 +
 
 +
|- style="font-size:12pt"
 +
| Height="30" | mole_fraction_of_carbon_monoxide_in_air
 
  | 1=mole mole-1
 
  | 1=mole mole-1
  |  
+
  | mole_fraction_of_carbon_monoxide_with_lifetime_of_25_days_in_air
  
 
|- style="font-size:12pt"
 
|- style="font-size:12pt"
| Height="30" | mole_fraction_of_CO_due_to_oxidation_of_biogenic_NMVOC_in_air
+
| Height="30" | mole_fraction_of_carbon_monoxide_in_air
 
  | 1=mole mole-1
 
  | 1=mole mole-1
  |  
+
  | mole_fraction_of_carbon_monoxide_due_to_methane_oxidation_in_air
  
 
|- style="font-size:12pt"
 
|- style="font-size:12pt"
| Height="30" | mole_fraction_of_CO_due_to_emissions_from_East_Asia_in_air
+
| Height="60" | mole_fraction_of_carbon_monoxide_in_air
 
  | 1=mole mole-1
 
  | 1=mole mole-1
  |  
+
  | mole_fraction_of_carbon_monoxide_due_to_oxidation_of_anthropogenic_non_methane_volatile_organic_compound_in_air
  
 
|- style="font-size:12pt"
 
|- style="font-size:12pt"
| Height="30" | mole_fraction_of_CO_due_to_emissions_from_Europe_and_North_Africa_in_air
+
| Height="60" | mole_fraction_of_carbon_monoxide_in_air
 
  | 1=mole mole-1
 
  | 1=mole mole-1
  |  
+
  | mole_fraction_of_carbon_monoxide_due_to_oxidation_of_biogenic_non_methane_volatile_organic_compound_in_air
  
 
|- style="font-size:12pt"
 
|- style="font-size:12pt"
| Height="30" | mole_fraction_of_CO_due_to_emissions_from_North_America_in_air
+
| Height="45" | mole_fraction_of_carbon_monoxide_in_air
 
  | 1=mole mole-1
 
  | 1=mole mole-1
  |  
+
  | mole_fraction_of_carbon_monoxide_due_to_emissions_from_East_Asia_in_air
  
 
|- style="font-size:12pt"
 
|- style="font-size:12pt"
| Height="30" | mole_fraction_of_CO_due_to_emissions_from_South_Asia_in_air
+
| Height="45" | mole_fraction_of_carbon_monoxide_in_air
 
  | 1=mole mole-1
 
  | 1=mole mole-1
  |  
+
  | mole_fraction_of_carbon_monoxide_due_to_emissions_from_Europe_and_North_Africa_in_air
  
 
|- style="font-size:12pt"
 
|- style="font-size:12pt"
| Height="30" | mole_fraction_of_anthropogenic_NMVOC_in_air
+
| Height="45" | mole_fraction_of_carbon_monoxide_in_air
 
  | 1=mole mole-1
 
  | 1=mole mole-1
  |  
+
  | mole_fraction_of_carbon_monoxide_due_to_emissions_from_North_America_in_air
  
 
|- style="font-size:12pt"
 
|- style="font-size:12pt"
| Height="30" | mole_fraction_of_biogenic_NMVOC_in_air
+
| Height="45" | mole_fraction_of_carbon_monoxide_in_air
 
  | 1=mole mole-1
 
  | 1=mole mole-1
  |  
+
  | mole_fraction_of_carbon_monoxide_due_to_emissions_from_South_Asia_in_air
  
 
|- style="font-size:12pt"
 
|- style="font-size:12pt"
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|- style="font-size:12pt"
 
|- style="font-size:12pt"
| Height="30" | mass_fraction_of_pm10_aerosol_at_50_percent_relative_humidity_in_air
+
| Height="45" | mass_fraction_of_pm10_aerosol_in_air
 
  | 1=kg/kg
 
  | 1=kg/kg
  |  
+
  | The relative humidity must be given in a coordinate variable using the standard name relative_humidity
  
 
|- style="font-size:12pt"
 
|- style="font-size:12pt"
| Height="30" | mass_fraction_of_pm2p5_aerosol_at_50_percent_relative_humidity_in_air
+
| Height="45" | mass_fraction_of_pm2p5_aerosol_in_air
 
  | 1=kg/kg
 
  | 1=kg/kg
  |  
+
  | The relative humidity must be given in a coordinate variable using the standard name relative_humidity
  
 
|- style="font-size:12pt"
 
|- style="font-size:12pt"
| Height="30" | mass_fraction_of_pm1_aerosol_at_50_percent_relative_humidity_in_air
+
| Height="45" | mass_fraction_of_pm1_aerosol_in_air
 
  | 1=kg/kg
 
  | 1=kg/kg
  |  
+
  | The relative humidity must be given in a coordinate variable using the standard name relative_humidity
  
 
|- style="font-size:12pt"
 
|- style="font-size:12pt"
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|- style="font-size:12pt"
 
|- style="font-size:12pt"
| Height="30" | mass_fraction_of_organic_carbon_as_particulate_organic_carbon_dry_aerosol_in_air
+
| Height="30" | mass_fraction_of_particulate_organic_carbon_as_particulate_organic_carbon_dry_aerosol_in_air
 
  | 1=kg/kg
 
  | 1=kg/kg
 
  |  
 
  |  
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  |  
 
  |  
  
|- style="background-color:#CCFFCC;font-size:12pt"
+
|- style="font-size:12pt"
|style="font-weight:bold" Height="15,75" | optical thickness at 550 nm
+
|style="background-color:#CCFFCC;font-weight:bold" Height="60" | optical thickness
|  
+
|style="background-color:#CCFFCC" |  
  |  
+
  | The wavelength should be given as as scalar coordinate variables usig the standard name radiation_wavelength
  
 
|- style="font-size:12pt"
 
|- style="font-size:12pt"
| Height="15" | pm10_aerosol_ambient_optical_depth_at_550_nm
+
| Height="60" | pm10_aerosol_ambient_optical_depth
 
  | 1
 
  | 1
  |  
+
  | The wavelength should be given as as scalar coordinate variables usig the standard name radiation_wavelength
  
 
|- style="font-size:12pt"
 
|- style="font-size:12pt"
| Height="15" | pm2p5_aerosol_ambient_optical_depth_at_550_nm
+
| Height="60" | pm2p5_aerosol_ambient_optical_depth
 
  | 1
 
  | 1
  |  
+
  | The wavelength should be given as as scalar coordinate variables usig the standard name radiation_wavelength
  
 
|- style="font-size:12pt"
 
|- style="font-size:12pt"
| Height="15" | pm1_aerosol_ambient_optical_depth_at_550_nm
+
| Height="60" | pm1_aerosol_ambient_optical_depth
 
  | 1
 
  | 1
  |  
+
  | The wavelength should be given as as scalar coordinate variables usig the standard name radiation_wavelength
  
 
|- style="font-size:12pt"
 
|- style="font-size:12pt"
| Height="15" | nitrate_aerosol_ambient_optical_depth_at_550_nm
+
| Height="60" | nitrate_aerosol_ambient_optical_depth
 
  | 1
 
  | 1
  |  
+
  | The wavelength should be given as as scalar coordinate variables usig the standard name radiation_wavelength
  
 
|- style="font-size:12pt"
 
|- style="font-size:12pt"
| Height="15" | sulfate_aerosol_ambient_optical_depth_at_550_nm
+
| Height="60" | sulfate_aerosol_ambient_optical_depth
 
  | 1
 
  | 1
  |  
+
  | The wavelength should be given as as scalar coordinate variables usig the standard name radiation_wavelength
  
 
|- style="font-size:12pt"
 
|- style="font-size:12pt"
| Height="15" | ammonium_aerosol_ambient_optical_depth_at_550_nm
+
| Height="60" | ammonium_aerosol_ambient_optical_depth
 
  | 1
 
  | 1
  |  
+
  | The wavelength should be given as as scalar coordinate variables usig the standard name radiation_wavelength
  
 
|- style="font-size:12pt"
 
|- style="font-size:12pt"
| Height="15" | black_carbon_aerosol_ambient_optical_depth_at_550_nm
+
| Height="60" | black_carbon_aerosol_ambient_optical_depth
 
  | 1
 
  | 1
  |  
+
  | The wavelength should be given as as scalar coordinate variables usig the standard name radiation_wavelength
  
 
|- style="font-size:12pt"
 
|- style="font-size:12pt"
| Height="15" | organic_carbon_aerosol_ambient_optical_depth_at_550_nm
+
| Height="60" | organic_carbon_aerosol_ambient_optical_depth
 
  | 1
 
  | 1
  |  
+
  | The wavelength should be given as as scalar coordinate variables usig the standard name radiation_wavelength
  
 
|- style="font-size:12pt"
 
|- style="font-size:12pt"
| Height="15" | seasalt_aerosol_ambient_optical_depth_at_550_nm
+
| Height="60" | seasalt_aerosol_ambient_optical_depth
 
  | 1
 
  | 1
  |  
+
  | The wavelength should be given as as scalar coordinate variables usig the standard name radiation_wavelength
  
 
|- style="font-size:12pt"
 
|- style="font-size:12pt"
| Height="15" | dust_aerosol_ambient_optical_depth_at_550_nm
+
| Height="60" | dust_aerosol_ambient_optical_depth
 
  | 1
 
  | 1
  |  
+
  | The wavelength should be given as as scalar coordinate variables usig the standard name radiation_wavelength
  
 
|- style="font-size:12pt"
 
|- style="font-size:12pt"
| Height="15" | aerosol_water_aerosol_ambient_optical_depth_at_550_nm
+
| Height="60" | aerosol_water_aerosol_ambient_optical_depth
 
  | 1
 
  | 1
  |  
+
  | The wavelength should be given as as scalar coordinate variables usig the standard name radiation_wavelength
  
 
|- style="font-size:12pt"
 
|- style="font-size:12pt"
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|- style="font-size:12pt"
 
|- style="font-size:12pt"
| Height="15" | atmosphere_mass_content_of_air
+
| Height="15" | atmosphere_mass_of_air_per_unit_area
 
  | kg m-2
 
  | kg m-2
 
  | vertically integrated mass of air
 
  | vertically integrated mass of air
 +
 +
|- style="font-size:12pt"
 +
| Height="45" | source_region
 +
| 1
 +
| should give the name and the latitude and longitude boundaries of the region
  
 
|}
 
|}

Revision as of 11:17, September 26, 2006

Return to Start page for Atmospheric Chemistry and Aerosol Names PLEASE DO NOT USE THE NAVIGATION BAR ON THE LEFT HAND SIDE!


The talbe is updated according to the discussions in the CF mailing list, that can also be found on our discussion page.

Version 1 18.08.2006
Version 2 26.09.2006

It is the philosophy of CF only define those standard_names for which a demand has been expressed. The proposed standard_names on this page are needed for a model intercomparison within the Task Force on Hemispheric Transport of Air Pollution TF HTAP.

The proposed standard_names listed below are based on the ideas provided at Construction of Atmospheric Chemistry and Aerosol Terms and Future Standard_Names. They are constructed from name components and species mentioned in tables 1 and 2 of that page.


Comments to ChristianeTextor or directly on the discussion page are highly welcome!

You can directly modify the tables here, all versions are stored under 'history'. However, in order to keep track of the changes, please send an email to ChristianeTextor.

TABLE VERSION 2, updated

CF Standard_name Canonical unit Explanation
dry deposition flux at the surface
surface_dry_deposition_mass_flux_of_ozone kg m-2 s-1 Dry deposition includes gravitational settling, impact scavenging, and turbulent deposition
surface_dry_deposition_mass_flux_of_nitric_acid kg m-2 s-1 Dry deposition includes gravitational settling, impact scavenging, and turbulent deposition
surface_dry_deposition_mass_flux_of_nitrogen_dioxide kg m-2 s-1 Dry deposition includes gravitational settling, impact scavenging, and turbulent deposition
surface_dry_deposition_mass_flux_of_all_nitrogen_oxides kg m-2 s-1

" | 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"

surface_dry_deposition_mass_flux_of_ammonia kg m-2 s-1 Dry deposition includes gravitational settling, impact scavenging, and turbulent deposition
surface_dry_deposition_mass_flux_of_ammonium_as_ammonium kg m-2 s-1 Dry deposition includes gravitational settling, impact scavenging, and turbulent deposition
surface_dry_deposition_mass_flux_of_sulfur_dioxide kg m-2 s-1 Dry deposition includes gravitational settling, impact scavenging, and turbulent deposition
surface_dry_deposition_mass_flux_of_sulfate_as_sulfate_dry_aerosol kg m-2 s-1 Dry deposition includes gravitational settling, impact scavenging, and turbulent deposition
surface_dry_deposition_mass_flux_of_black_carbon_dry_aerosol kg m-2 s-1 Dry deposition includes gravitational settling, impact scavenging, and turbulent deposition
surface_dry_deposition_mass_flux_of_particulate_organic_carbon_as_particulate_organic_carbon_dry_aerosol kg m-2 s-1 Dry deposition includes gravitational settling, impact scavenging, and turbulent deposition
surface_dry_deposition_mass_flux_of_seasalt_dry_aerosol kg m-2 s-1 Dry deposition includes gravitational settling, impact scavenging, and turbulent deposition
surface_dry_deposition_mass_flux_of_dust_dry_aerosol kg m-2 s-1 Dry deposition includes gravitational settling, impact scavenging, and turbulent deposition
surface_dry_deposition_mass_flux_of_hexachlorbiphenyl kg m-2 s-1 Dry deposition includes gravitational settling, impact scavenging, and turbulent deposition
surface_dry_deposition_mass_flux_of_alpha_hexachlorocyclohexane kg m-2 s-1 Dry deposition includes gravitational settling, impact scavenging, and turbulent deposition
surface_dry_deposition_mass_flux_of_mercury_0 kg m-2 s-1 Dry deposition includes gravitational settling, impact scavenging, and turbulent deposition
surface_dry_deposition_mass_flux_of_mercury_2 kg m-2 s-1 Dry deposition includes gravitational settling, impact scavenging, and turbulent deposition
surface_dry_deposition_mass_flux_of_mercury_aerosol kg m-2 s-1 Dry deposition includes gravitational settling, impact scavenging, and turbulent deposition
stomatal flux
surface_dry_deposition_mass_flux_of_ozone_in_stomata kg m-2 s-1
wet deposition flux at the surface
surface_wet_deposition_mass_flux_of_all_nitrogen_oxides kg m-2 s-1 NOy is the sum of all simulated oxidized nitrogen species, out of NO, NO2, HNO3, HNO4, NO3aerosol, NO3(radical), N2O5, PAN, other organic nitrates
surface_wet_deposition_mass_flux_of_nitric_acid kg m-2 s-1
surface_wet_deposition_mass_flux_of_ammonia kg m-2 s-1
surface_wet_deposition_mass_flux_of_ammonium_as_ammonium kg m-2 s-1
surface_wet_deposition_mass_flux_of_sulfur_dioxide kg m-2 s-1
surface_wet_deposition_mass_flux_of_sulfate_as_sulfate_dry_aerosol kg m-2 s-1
surface_wet_deposition_mass_flux_of_black_carbon_dry_aerosol kg m-2 s-1
surface_wet_deposition_mass_flux_of_particulate_organic_carbon_as_particulate_organic_carbon_dry_aerosol kg m-2 s-1
surface_wet_deposition_mass_flux_of_seasalt_dry_aerosol kg m-2 s-1
surface_wet_deposition_mass_flux_of_dust_dry_aerosol kg m-2 s-1
surface_wet_deposition_mass_flux_of_hexachlorbiphenyl kg m-2 s-1
surface_wet_deposition_mass_flux_of_alpha_hexachlorocyclohexane kg m-2 s-1
surface_wet_deposition_mass_flux_of_mercury_0 kg m-2 s-1
surface_wet_deposition_mass_flux_of_mercury_2 kg m-2 s-1
surface_wet_deposition_mass_flux_of_mercury_aerosol kg m-2 s-1
emission fluxes
surface_emission_mass_flux_of_nox kg m-2 s-1 NOx=NO+NO2
surface_emission_mass_flux_of_carbon_monoxide kg m-2 s-1
surface_emission_mass_flux_of_non_methane_volatile_organic_compounds kg m-2 s-1
surface_emission_mass_flux_of_anthropogenic_non_methane_volatile_organic_compounds kg m-2 s-1
surface_emission_mass_flux_of_biogenic_non_methane_volatile_organic_compounds kg m-2 s-1
surface_emission_mass_flux_of_ammonia kg m-2 s-1
surface_emission_mass_flux_of_sulfur_dioxide kg m-2 s-1
surface_emission_mass_flux_of_sulfate_as_sulfate_dry_aerosol kg m-2 s-1
surface_emission_mass_flux_of_black_carbon_dry_aerosol kg m-2 s-1
surface_emission_mass_flux_of_particulate_organic_carbon_as_particulate_organic_carbon_dry_aerosol kg m-2 s-1
atmosphere_emission_mass_flux_of_secondary_organic_carbon_as_particulate_organic_carbon_dry_aerosol kg m-2 s-1
surface_emission_mass_flux_of_seasalt_dry_aerosol kg m-2 s-1
surface_emission_mass_flux_of_dust_dry_aerosol kg m-2 s-1
surface_emission_mass_flux_of_hexachlorbiphenyl kg m-2 s-1
surface_emission_mass_flux_of_alpha_hexachlorocyclohexane kg m-2 s-1
surface_re_emission_mass_flux_of_hexachlorbiphenyl kg m-2 s-1
surface_re_emission_mass_flux_of_alpha_hexachlorocyclohexane kg m-2 s-1
surface_emission_mass_flux_of_mercury_0 kg m-2 s-1
surface_emission_mass_flux_of_mercury_2 kg m-2 s-1
surface_emission_mass_flux_of_mercury_aerosol kg m-2 s-1
volume mixing ratios
mole_fraction_of_ozone_in_air 1=mole mole-1
mole_fraction_of_cabon_monoxide_in_air 1=mole mole-1
mole_fraction_of_nitrogen_monoxide_in_air 1=mole mole-1
mole_fraction_of_nitrogen_dioxide_in_air 1=mole mole-1
mole_fraction_of_nitrogen_acid_in_air 1=mole mole-1
mole_fraction_of_peroxyacetyl_nitrate_in_air 1=mole mole-1
mole_fraction_of_hydroxyl_radical_in_air 1=mole mole-1
mole_fraction_of_sulfur_dioxide_in_air 1=mole mole-1
mole_fraction_of_hexachlorbiphenyl_in_air 1=mole mole-1
mole_fraction_of_alpha_hexachlorocyclohexane_in_air 1=mole mole-1
mole_fraction_of_mercury_0_in_air 1=mole mole-1
mole_fraction_of_mercury_2_in_air 1=mole mole-1
mole_fraction_of_mercury_aerosol_in_air 1=mole mole-1
mole_fraction_of_anthropogenic_non_methane_volatile_organic_compound_in_air 1=mole mole-1
mole_fraction_of_biogenic_non_methane_volatile_organic_compound_in_air 1=mole mole-1
HTAP experiments with tagged CO
mole_fraction_of_carbon_monoxide_in_air 1=mole mole-1 mole_fraction_of_carbon_monoxide_with_lifetime_of_25_days_in_air
mole_fraction_of_carbon_monoxide_in_air 1=mole mole-1 mole_fraction_of_carbon_monoxide_due_to_methane_oxidation_in_air
mole_fraction_of_carbon_monoxide_in_air 1=mole mole-1 mole_fraction_of_carbon_monoxide_due_to_oxidation_of_anthropogenic_non_methane_volatile_organic_compound_in_air
mole_fraction_of_carbon_monoxide_in_air 1=mole mole-1 mole_fraction_of_carbon_monoxide_due_to_oxidation_of_biogenic_non_methane_volatile_organic_compound_in_air
mole_fraction_of_carbon_monoxide_in_air 1=mole mole-1 mole_fraction_of_carbon_monoxide_due_to_emissions_from_East_Asia_in_air
mole_fraction_of_carbon_monoxide_in_air 1=mole mole-1 mole_fraction_of_carbon_monoxide_due_to_emissions_from_Europe_and_North_Africa_in_air
mole_fraction_of_carbon_monoxide_in_air 1=mole mole-1 mole_fraction_of_carbon_monoxide_due_to_emissions_from_North_America_in_air
mole_fraction_of_carbon_monoxide_in_air 1=mole mole-1 mole_fraction_of_carbon_monoxide_due_to_emissions_from_South_Asia_in_air
mass mixing ratio
mass_fraction_of_pm10_aerosol_in_air 1=kg/kg The relative humidity must be given in a coordinate variable using the standard name relative_humidity
mass_fraction_of_pm2p5_aerosol_in_air 1=kg/kg The relative humidity must be given in a coordinate variable using the standard name relative_humidity
mass_fraction_of_pm1_aerosol_in_air 1=kg/kg The relative humidity must be given in a coordinate variable using the standard name relative_humidity
mass_fraction_ of_nitrate_as_nitrate_dry_aerosol_in_air 1=kg/kg
mass_fraction_of_sulfate_as_sulfate_dry_aerosol_in_air 1=kg/kg
mass_fraction_of_ammonium_as_ammonium_dry_aerosol_in_air 1=kg/kg
mass_fraction_ of_black_carbon_dry_aerosol_in_air 1=kg/kg
mass_fraction_of_particulate_organic_carbon_as_particulate_organic_carbon_dry_aerosol_in_air 1=kg/kg
mass_fraction_of_secondary_organic_carbon_as_particulate_organic_carbon_dry_aerosol_in_air 1=kg/kg
mass_fraction_ of_seasalt_dry_aerosol_in_air 1=kg/kg
mass_fraction_ of_dust_dry_aerosol_in_air 1=kg/kg
mass_fraction_ of_aerosol_water_ambient_aerosol_in_air 1=kg/kg
fluxes due to chemical reactions
chemical_gross_production_rate_of_mole_concentration_of_ozone mole m-3 s-1
chemical_destruction_rate_of_mole_concentration_of_ozone mole m-3 s-1
chemical_destruction_rate_of_mole_concentration_of_methane mole m-3 s-1
chemical_destruction_rate_of_mole_concentration_of_carbon_monoxide mole m-3 s-1
optical thickness The wavelength should be given as as scalar coordinate variables usig the standard name radiation_wavelength
pm10_aerosol_ambient_optical_depth 1 The wavelength should be given as as scalar coordinate variables usig the standard name radiation_wavelength
pm2p5_aerosol_ambient_optical_depth 1 The wavelength should be given as as scalar coordinate variables usig the standard name radiation_wavelength
pm1_aerosol_ambient_optical_depth 1 The wavelength should be given as as scalar coordinate variables usig the standard name radiation_wavelength
nitrate_aerosol_ambient_optical_depth 1 The wavelength should be given as as scalar coordinate variables usig the standard name radiation_wavelength
sulfate_aerosol_ambient_optical_depth 1 The wavelength should be given as as scalar coordinate variables usig the standard name radiation_wavelength
ammonium_aerosol_ambient_optical_depth 1 The wavelength should be given as as scalar coordinate variables usig the standard name radiation_wavelength
black_carbon_aerosol_ambient_optical_depth 1 The wavelength should be given as as scalar coordinate variables usig the standard name radiation_wavelength
organic_carbon_aerosol_ambient_optical_depth 1 The wavelength should be given as as scalar coordinate variables usig the standard name radiation_wavelength
seasalt_aerosol_ambient_optical_depth 1 The wavelength should be given as as scalar coordinate variables usig the standard name radiation_wavelength
dust_aerosol_ambient_optical_depth 1 The wavelength should be given as as scalar coordinate variables usig the standard name radiation_wavelength
aerosol_water_aerosol_ambient_optical_depth 1 The wavelength should be given as as scalar coordinate variables usig the standard name radiation_wavelength
others
grid_cell_area m2 model grid cell area
grid_cell_height m model grid cell height
atmosphere_mass_of_air_per_unit_area kg m-2 vertically integrated mass of air
source_region 1 should give the name and the latitude and longitude boundaries of the region