root/cf-standard-names/tags/10/src/cf-standard-name-table.xml

<?xml version="1.0"?>
<standard_name_table xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance" xsi:noNamespaceSchemaLocation="CFStandardNameTable-1.1.xsd">
  <version_number>10</version_number>
  <last_modified>2008-10-21T12:26:52Z</last_modified>
  <institution>Program for Climate Model Diagnosis and Intercomparison</institution>
  <contact>webmaster@pcmdi.llnl.gov</contact>
  <entry id="aerosol_angstrom_exponent">
    <canonical_units>1</canonical_units>
    <description>&quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets).</description>
  </entry>
  <entry id="age_of_stratospheric_air">
    <canonical_units>s</canonical_units>
    <description>&quot;Age of stratospheric air&quot; means an estimate of the time since a parcel of stratospheric air was last in contact with the troposphere.</description>
  </entry>
  <entry id="air_density">
    <canonical_units>kg m-3</canonical_units>
    <description></description>
  </entry>
  <entry id="air_potential_temperature">
    <canonical_units>K</canonical_units>
    <grib>13</grib>
    <amip>theta</amip>
    <description>Potential temperature is the temperature a parcel of air or sea water would have if moved adiabatically to sea level pressure.</description>
  </entry>
  <entry id="air_pressure">
    <canonical_units>Pa</canonical_units>
    <grib>1</grib>
    <amip>plev</amip>
    <description></description>
  </entry>
  <entry id="air_pressure_anomaly">
    <canonical_units>Pa</canonical_units>
    <grib>26</grib>
    <description>&quot;anomaly&quot; means difference from climatology.</description>
  </entry>
  <entry id="air_pressure_at_cloud_base">
    <canonical_units>Pa</canonical_units>
    <description>cloud_base refers to the base of the lowest cloud.</description>
  </entry>
  <entry id="air_pressure_at_cloud_top">
    <canonical_units>Pa</canonical_units>
    <description>cloud_top refers to the top of the highest cloud.</description>
  </entry>
  <entry id="air_pressure_at_convective_cloud_base">
    <canonical_units>Pa</canonical_units>
    <description>cloud_base refers to the base of the lowest cloud. Convective cloud is that produced by the convection schemes in an atmosphere model.</description>
  </entry>
  <entry id="air_pressure_at_convective_cloud_top">
    <canonical_units>Pa</canonical_units>
    <description>cloud_top refers to the top of the highest cloud. Convective cloud is that produced by the convection schemes in an atmosphere model.</description>
  </entry>
  <entry id="air_pressure_at_freezing_level">
    <canonical_units>Pa</canonical_units>
    <description></description>
  </entry>
  <entry id="air_pressure_at_sea_level">
    <canonical_units>Pa</canonical_units>
    <grib>2 E151</grib>
    <amip>psl</amip>
    <description>sea_level means mean sea level, which is close to the geoid in sea areas. Air pressure at sea level is the quantity often abbreviated as MSLP or PMSL.</description>
  </entry>
  <entry id="air_temperature">
    <canonical_units>K</canonical_units>
    <grib>11 E130</grib>
    <amip>ta</amip>
    <description>Air temperature is the bulk temperature of the air, not the surface (skin) temperature.</description>
  </entry>
  <entry id="air_temperature_anomaly">
    <canonical_units>K</canonical_units>
    <grib>25</grib>
    <description>&quot;anomaly&quot; means difference from climatology. Air temperature is the bulk temperature of the air, not the surface (skin) temperature.</description>
  </entry>
  <entry id="air_temperature_at_cloud_top">
    <canonical_units>K</canonical_units>
    <description>cloud_top refers to the top of the highest cloud. Air temperature is the bulk temperature of the air, not the surface (skin) temperature.</description>
  </entry>
  <entry id="air_temperature_lapse_rate">
    <canonical_units>K m-1</canonical_units>
    <grib>19</grib>
    <description>Air temperature is the bulk temperature of the air, not the surface (skin) temperature. A lapse rate is the negative derivative of a quantity with respect to increasing height above the surface, or the (positive) derivative with respect to increasing depth.</description>
  </entry>
  <entry id="air_temperature_threshold">
    <canonical_units>K</canonical_units>
    <description>Air temperature is the bulk temperature of the air, not the surface (skin) temperature. Air temperature excess and deficit are calculated relative to the air temperature threshold.</description>
  </entry>
  <entry id="altimeter_range">
    <canonical_units>m</canonical_units>
    <description>An altimeter operates by sending out a short pulse of radiation and measuring the time required for the pulse to return from the sea surface; this measurement is used to calculate the distance between the instrument and the sea surface.  That measurement is called the &quot;altimeter range&quot; and does not include any range corrections.</description>
  </entry>
  <entry id="altimeter_range_correction_due_to_dry_troposphere">
    <canonical_units>m</canonical_units>
    <description>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.   To apply the altimeter range correction it must be added to the quantity with standard name altimeter_range.  &quot;Correction_due_to_dry_troposphere&quot; means a correction for dry gases in the troposphere, i.e. excluding the effect of liquid water.  Additional altimeter range corrections are given by the quantities with standard names altimeter_range_correction_due_to_wet_troposphere, altimeter_range_correction_due_to_ionosphere, sea_surface_height_correction_due_to_air_pressure_at_low_frequency and sea_surface_height_correction_due_to_air_pressure_and_wind_at_high_frequency.</description>
  </entry>
  <entry id="altimeter_range_correction_due_to_ionosphere">
    <canonical_units>m</canonical_units>
    <description>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.   To apply the altimeter range correction it must be added to the quantity with standard name altimeter_range.  &quot;Correction_due_to_ionosphere&quot; means a correction for the atmosphere's electron content in the ionosphere. Additional altimeter range corrections are given by the quantities with standard names altimeter_range_correction_due_to_wet_troposphere, altimeter_range_correction_due_to_dry_troposphere, sea_surface_height_correction_due_to_air_pressure_at_low_frequency and sea_surface_height_correction_due_to_air_pressure_and_wind_at_high_frequency.</description>
  </entry>
  <entry id="altimeter_range_correction_due_to_wet_troposphere">
    <canonical_units>m</canonical_units>
    <description>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.   To apply the altimeter range correction it must be added to the quantity with standard name altimeter_range.  &quot;Correction_due_to_wet_troposphere&quot; means a correction for the effect of liquid water in the troposphere.  Additional altimeter range corrections are given by the quantities with standard names altimeter_range_correction_due_to_dry_troposphere, altimeter_range_correction_due_to_ionosphere, sea_surface_height_correction_due_to_air_pressure_at_low_frequency and sea_surface_height_correction_due_to_air_pressure_and_wind_at_high_frequency.</description>
  </entry>
  <entry id="altitude">
    <canonical_units>m</canonical_units>
    <grib>8</grib>
    <description>Altitude is the (geometric) height above the geoid, which is the reference geopotential surface. The geoid is similar to mean sea level.</description>
  </entry>
  <entry id="altitude_at_top_of_dry_convection">
    <canonical_units>m</canonical_units>
    <description>Altitude is the (geometric) height above the geoid, which is the reference geopotential surface. The geoid is similar to mean sea level.</description>
  </entry>
  <entry id="angle_of_rotation_from_east_to_x">
    <canonical_units>degree</canonical_units>
    <description>The quantity with standard name angle_of_rotation_from_east_to_x is the angle, anticlockwise reckoned positive, between due East and (dr/di)jk, where r(i,j,k) is the vector 3D position of the point with coordinate indices (i,j,k).  It could be used for rotating vector fields between model space and latitude-longitude space.</description>
  </entry>
  <entry id="angle_of_rotation_from_east_to_y">
  <canonical_units>degree</canonical_units>
  <description>The quantity with standard name angle_of_rotation_from_east_to_y is the angle, anticlockwise reckoned positive, between due East and (dr/dj)ik, where r(i,j,k) is the vector 3D position of the point with coordinate indices (i,j,k).  It could be used for rotating vector fields between model space and latitude-longitude space.</description>
  </entry>
  <entry id="area_fraction">
    <canonical_units>1</canonical_units>
    <description>&quot;Area fraction&quot; means the fraction of horizontal area. To specify which area is quantified by a variable of area_fraction, provide a coordinate variable or scalar coordinate variable of land_cover or surface_cover. Alternatively, if one is defined, use a more specific standard name of &quot;X_area_fraction&quot; for the fraction of horizontal area occupied by X.</description>
  </entry>
  <entry id="area_fraction_below_surface">
    <canonical_units>1</canonical_units>
    <amip>psbg</amip>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. The fraction of horizontal area where the surface specified by the axes other than horizontal axes, for instance an isobaric surface, is below the (ground or sea) surface.</description>
  </entry>
  <entry id="atmosphere_absolute_vorticity">
    <canonical_units>s-1</canonical_units>
    <grib>41</grib>
    <description>Absolute vorticity is the sum of relative vorticity and the upward component of vorticity due to the Earth's rotation.</description>
  </entry>
  <entry id="atmosphere_boundary_layer_thickness">
    <canonical_units>m</canonical_units>
    <amip>zmla</amip>
    <description>The atmosphere boundary layer thickness is the &quot;depth&quot; or &quot;height&quot; of the (atmosphere) planetary boundary layer.</description>
  </entry>
  <entry id="atmosphere_cloud_condensed_water_content">
    <canonical_units>kg m-2</canonical_units>
    <grib>76</grib>
    <amip>clwvi</amip>
    <description>&quot;condensed_water&quot; means liquid and ice. &quot;Content&quot; indicates a quantity per unit area. The &quot;atmosphere content&quot; of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used.</description>
  </entry>
  <entry id="atmosphere_cloud_ice_content">
    <canonical_units>kg m-2</canonical_units>
    <grib>58</grib>
    <amip>clivi</amip>
    <description>&quot;Content&quot; indicates a quantity per unit area. The &quot;atmosphere content&quot; of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used.</description>
  </entry>
  <entry id="atmosphere_cloud_liquid_water_content">
    <canonical_units>kg m-2</canonical_units>
    <description>&quot;Content&quot; indicates a quantity per unit area. The &quot;atmosphere content&quot; of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used.</description>
  </entry>
  <entry id="atmosphere_content_of_sulfate_aerosol">
    <canonical_units>kg m-2</canonical_units>
    <amip>trsult</amip>
    <description>&quot;Content&quot; indicates a quantity per unit area. &quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets).</description>
  </entry>
  <entry id="atmosphere_convective_cloud_condensed_water_content">
    <canonical_units>kg m-2</canonical_units>
    <description>&quot;condensed_water&quot; means liquid and ice. Convective cloud is that produced by the convection schemes in an atmosphere model. &quot;Content&quot; indicates a quantity per unit area. The &quot;atmosphere content&quot; of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used.</description>
  </entry>
  <entry id="atmosphere_convective_cloud_liquid_water_content">
    <canonical_units>kg m-2</canonical_units>
    <description>Convective cloud is that produced by the convection schemes in an atmosphere model.  &quot;Content&quot; indicates a quantity per unit area. The &quot;atmosphere content&quot; of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used.</description>
  </entry>
  <entry id="atmosphere_convective_mass_flux">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; 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.</description>
  </entry>
  <entry id="atmosphere_dry_energy_content">
    <canonical_units>J m-2</canonical_units>
    <description>&quot;Content&quot; indicates a quantity per unit area. The &quot;atmosphere content&quot; of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. Dry energy is the sum of dry static energy and kinetic energy. Dry static energy is the sum of enthalpy and potential energy (itself the sum of gravitational and centripetal potential energy). Enthalpy can be written either as (1) CpT, where Cp is heat capacity at constant pressure, T is absolute temperature, or (2) U+pV, where U is internal energy, p is pressure and V is volume.</description>
  </entry>
  <entry id="atmosphere_dry_static_energy_content">
    <canonical_units>J m-2</canonical_units>
    <description>&quot;Content&quot; indicates a quantity per unit area. The &quot;atmosphere content&quot; of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. Dry static energy is the sum of enthalpy and potential energy (itself the sum of gravitational and centripetal potential energy). Enthalpy can be written either as (1) CpT, where Cp is heat capacity at constant pressure, T is absolute temperature, or (2) U+pV, where U is internal energy, p is pressure and V is volume.</description>
  </entry>
  <entry id="atmosphere_eastward_stress_due_to_gravity_wave_drag">
    <canonical_units>Pa</canonical_units>
    <amip>tauugwd</amip>
    <description>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. &quot;Eastward&quot; indicates a vector component which is positive when directed eastward (negative westward). Atmosphere_Xward_stress is a stress which tends to accelerate the atmosphere in direction X.</description>
  </entry>
  <entry id="atmosphere_energy_content">
    <canonical_units>J m-2</canonical_units>
    <description>&quot;Content&quot; indicates a quantity per unit area. The &quot;atmosphere content&quot; of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. &quot;Atmosphere energy content&quot; has not yet been precisely defined! Please express your views on this quantity on the CF email list.</description>
  </entry>
  <entry id="atmosphere_enthalpy_content">
    <canonical_units>J m-2</canonical_units>
    <description>&quot;Content&quot; indicates a quantity per unit area. The &quot;atmosphere content&quot; of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. Enthalpy can be written either as (1) CpT, where Cp is heat capacity at constant pressure, T is absolute temperature, or (2) U+pV, where U is internal energy, p is pressure and V is volume.</description>
  </entry>
  <entry id="atmosphere_heat_diffusivity">
    <canonical_units>m2 s-1</canonical_units>
    <description></description>
  </entry>
  <entry id="atmosphere_horizontal_streamfunction">
    <canonical_units>m2 s-1</canonical_units>
    <grib>35</grib>
    <description>&quot;Horizontal&quot; indicates that the streamfunction applies to a horizontal velocity field on a particular vertical level.</description>
  </entry>
  <entry id="atmosphere_horizontal_velocity_potential">
    <canonical_units>m2 s-1</canonical_units>
    <grib>36</grib>
    <description>A velocity is a vector quantity. &quot;Horizontal&quot; indicates that the velocity potential applies to a horizontal velocity field on a particular vertical level.</description>
  </entry>
  <entry id="atmosphere_hybrid_height_coordinate">
    <canonical_units>m</canonical_units>
    <description>See Appendix D of the CF convention for information about dimensionless vertical coordinates.</description>
  </entry>
  <entry id="atmosphere_hybrid_sigma_pressure_coordinate">
    <canonical_units>1</canonical_units>
    <description>See Appendix D of the CF convention for information about dimensionless vertical coordinates.</description>
  </entry>
  <entry id="atmosphere_kinetic_energy_content">
    <canonical_units>J m-2</canonical_units>
    <description>&quot;Content&quot; indicates a quantity per unit area. The &quot;atmosphere content&quot; of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used.</description>
  </entry>
  <entry id="atmosphere_ln_pressure_coordinate">
    <canonical_units>1</canonical_units>
    <description>&quot;ln_X&quot; means natural logarithm of X. X must be dimensionless. See Appendix D of the CF convention for information about dimensionless vertical coordinates.</description>
  </entry>
  <entry id="atmosphere_mass_of_air_per_unit_area">
    <canonical_units>kg m-2</canonical_units>
    <description>&quot;Mass_of_air&quot; means the mass due solely to the gaseous constituents of the atmosphere.  The standard name for the mass including precipitation and aerosol particles is atmosphere_mass_per_unit_area.</description>
  </entry>
  <entry id="atmosphere_mass_per_unit_area">
    <canonical_units>kg m-2</canonical_units>
    <description>&quot;X_area&quot; means the horizontal area occupied by X within the grid cell.</description>
  </entry>
  <entry id="atmosphere_momentum_diffusivity">
    <canonical_units>m2 s-1</canonical_units>
    <description></description>
  </entry>
  <entry id="atmosphere_net_rate_of_absorption_of_longwave_energy">
    <canonical_units>W m-2</canonical_units>
    <description>&quot;longwave&quot; means longwave radiation. Net absorbed radiation is the difference between absorbed and emitted radiation.</description>
  </entry>
  <entry id="atmosphere_net_rate_of_absorption_of_shortwave_energy">
    <canonical_units>W m-2</canonical_units>
    <description>&quot;shortwave&quot; means shortwave radiation. Net absorbed radiation is the difference between absorbed and emitted radiation.</description>
  </entry>
  <entry id="atmosphere_northward_stress_due_to_gravity_wave_drag">
    <canonical_units>Pa</canonical_units>
    <amip>tauvgwd</amip>
    <description>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. &quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). Atmosphere_Xward_stress is a stress which tends to accelerate the atmosphere in direction X.</description>
  </entry>
  <entry id="atmosphere_optical_thickness_due_to_aerosol">
    <canonical_units>1</canonical_units>
    <description>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. 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. The atmosphere optical thickness applies to radiation passing through the entire atmosphere. &quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets).</description>
  </entry>
  <entry id="atmosphere_optical_thickness_due_to_black_carbon_ambient_aerosol">
    <canonical_units>1</canonical_units>
    <description>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. 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. The atmosphere optical thickness applies to radiation passing through the entire atmosphere. &quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets).  &quot;Ambient aerosol&quot; is aerosol that has taken up ambient water through hygroscopic growth.  The extent of hygroscopic growth depends on the relative humidity and the composition of the aerosol.  Black carbon aerosol is composed of elemental carbon.  It is strongly light absorbing.</description>
  </entry>
  <entry id="atmosphere_optical_thickness_due_to_dust_ambient_aerosol">
    <canonical_units>1</canonical_units>
    <description>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. 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. The atmosphere optical thickness applies to radiation passing through the entire atmosphere. &quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets).  &quot;Ambient aerosol&quot; is aerosol that has taken up ambient water through hygroscopic growth.  The extent of hygroscopic growth depends on the relative humidity and the composition of the aerosol.</description>
  </entry>
  <entry id="atmosphere_optical_thickness_due_to_particulate_organic_matter_ambient_aerosol">
    <canonical_units>1</canonical_units>
    <description>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. 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. The atmosphere optical thickness applies to radiation passing through the entire atmosphere. &quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets).  &quot;Ambient aerosol&quot; is aerosol that has taken up ambient water through hygroscopic growth.  The extent of hygroscopic growth depends on the relative humidity and the composition of the aerosol.</description>
  </entry>
  <entry id="atmosphere_optical_thickness_due_to_pm10_ambient_aerosol">
    <canonical_units>1</canonical_units>
    <description>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. 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. The atmosphere optical thickness applies to radiation passing through the entire atmosphere. &quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets).  &quot;Ambient aerosol&quot; is aerosol that has taken up ambient water through hygroscopic growth.  The extent of hygroscopic growth depends on the relative humidity and the composition of the aerosol.  &quot;Pm10 aerosol&quot; is an air pollutant with an aerodynamic diameter of less than or equal to 10 micrometers.</description>
  </entry>
  <entry id="atmosphere_optical_thickness_due_to_pm1_ambient_aerosol">
    <canonical_units>1</canonical_units>
    <description>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. 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. The atmosphere optical thickness applies to radiation passing through the entire atmosphere. &quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets).  &quot;Ambient aerosol&quot; is aerosol that has taken up ambient water through hygroscopic growth.  The extent of hygroscopic growth depends on the relative humidity and the composition of the aerosol.  &quot;Pm1 aerosol&quot; is an air pollutant with an aerodynamic diameter of less than or equal to 1 micrometer.</description>
  </entry>
  <entry id="atmosphere_optical_thickness_due_to_pm2p5_ambient_aerosol">
    <canonical_units>1</canonical_units>
    <description>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. 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. The atmosphere optical thickness applies to radiation passing through the entire atmosphere. &quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets).  &quot;Ambient aerosol&quot; is aerosol that has taken up ambient water through hygroscopic growth.  The extent of hygroscopic growth depends on the relative humidity and the composition of the aerosol.  &quot;Pm2p5 aerosol&quot; is an air pollutant with an aerodynamic diameter of less than or equal to 2.5 micrometers.</description>
  </entry>
  <entry id="atmosphere_optical_thickness_due_to_seasalt_ambient_aerosol">
    <canonical_units>1</canonical_units>
    <description>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. 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. The atmosphere optical thickness applies to radiation passing through the entire atmosphere. &quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets).  &quot;Ambient aerosol&quot; is aerosol that has taken up ambient water through hygroscopic growth.  The extent of hygroscopic growth depends on the relative humidity and the composition of the aerosol.</description>
  </entry>
  <entry id="atmosphere_optical_thickness_due_to_water_in_ambient_aerosol">
    <canonical_units>1</canonical_units>
    <description>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. 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. The atmosphere optical thickness applies to radiation passing through the entire atmosphere. &quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets). &quot;atmosphere_optical_thickness_due_to_water_in_ambient_aerosol&quot; refers to the optical thickness due to the water that is associated with aerosol particles due to hygroscopic growth in ambient air, affecting the particle's radius and refractive index.  It corresponds to the difference between the total dry aerosol optical thickness and the total ambient aerosol optical thickness.</description>
  </entry>
  <entry id="atmosphere_potential_energy_content">
    <canonical_units>J m-2</canonical_units>
    <description>&quot;Content&quot; indicates a quantity per unit area. The &quot;atmosphere content&quot; of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. 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.)</description>
  </entry>
  <entry id="atmosphere_relative_vorticity">
    <canonical_units>s-1</canonical_units>
    <grib>43 E138</grib>
    <description>Relative vorticity is the upward component of the vorticity vector i.e. the component which arises from horizontal velocity.</description>
  </entry>
  <entry id="atmosphere_sigma_coordinate">
    <canonical_units>1</canonical_units>
    <description>See Appendix D of the CF convention for information about dimensionless vertical coordinates.</description>
  </entry>
  <entry id="atmosphere_sleve_coordinate">
    <canonical_units>1</canonical_units>
    <description>See Appendix D of the CF convention for information about dimensionless vertical coordinates.</description>
  </entry>
  <entry id="atmosphere_specific_convective_available_potential_energy">
    <canonical_units>J kg-1</canonical_units>
    <description>&quot;specific&quot; means per unit mass. 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.) Convective(ly) available potential energy is often abbreviated as &quot;CAPE&quot;.</description>
  </entry>
  <entry id="atmosphere_sulfate_content">
    <canonical_units>kg m-2</canonical_units>
    <description>&quot;Content&quot; indicates a quantity per unit area. The &quot;atmosphere content&quot; of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used.</description>
  </entry>
  <entry id="atmosphere_water_content">
    <canonical_units>kg m-2</canonical_units>
    <description>&quot;Content&quot; indicates a quantity per unit area. The &quot;atmosphere content&quot; of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. &quot;Water&quot; means water in all phases.</description>
  </entry>
  <entry id="atmosphere_water_vapor_content">
    <canonical_units>kg m-2</canonical_units>
    <grib>54</grib>
    <amip>prw</amip>
    <description>&quot;Content&quot; indicates a quantity per unit area. The &quot;atmosphere content&quot; of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. Atmosphere water vapor content is sometimes referred to as &quot;precipitable water&quot;, although this term does not imply the water could all be precipitated.</description>
  </entry>
  <entry id="baroclinic_eastward_sea_water_velocity">
    <canonical_units>m s-1</canonical_units>
    <description>A velocity is a vector quantity. &quot;Eastward&quot; indicates a vector component which is positive when directed eastward (negative westward).</description>
  </entry>
  <entry id="baroclinic_northward_sea_water_velocity">
    <canonical_units>m s-1</canonical_units>
    <description>A velocity is a vector quantity. &quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward).</description>
  </entry>
  <entry id="barotropic_eastward_sea_water_velocity">
    <canonical_units>m s-1</canonical_units>
    <description>A velocity is a vector quantity. &quot;Eastward&quot; indicates a vector component which is positive when directed eastward (negative westward).</description>
  </entry>
  <entry id="barotropic_northward_sea_water_velocity">
    <canonical_units>m s-1</canonical_units>
    <description>A velocity is a vector quantity. &quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward).</description>
  </entry>
  <entry id="baseflow_amount">
    <canonical_units>kg m-2</canonical_units>
    <description>&quot;Baseflow&quot; is subsurface runoff which takes place below the level of the water table. Runoff is the liquid water which drains from land. &quot;Amount&quot; means mass per unit area.</description>
  </entry>
  <entry id="beaufort_wind_force">
    <canonical_units>1</canonical_units>
    <description>&quot;Beaufort wind force&quot; is an index assigned on the Beaufort wind force scale and relates a qualitative description of the degree of disturbance or destruction caused by wind to the speed of the wind.  The Beaufort wind scale varies between 0 (qualitatively described as calm, smoke rises vertically, sea appears glassy) (wind speeds in the range 0 - 0.2 m s-1) and 12 (hurricane, wave heights in excess of 14 m) (wind speeds in excess of 32.7 m s-1).</description>
  </entry>
  <entry id="bedrock_altitude">
    <canonical_units>m</canonical_units>
    <description>Altitude is the (geometric) height above the geoid, which is the reference geopotential surface. The geoid is similar to mean sea level. &quot;Bedrock&quot; is the solid Earth surface beneath land ice or ocean water.</description>
  </entry>
  <entry id="bedrock_altitude_change_due_to_isostatic_adjustment">
    <canonical_units>m</canonical_units>
    <description>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. Altitude is the (geometric) height above the geoid, which is the reference geopotential surface. The geoid is similar to mean sea level. &quot;Bedrock&quot; is the solid Earth surface beneath land ice or ocean water. The zero of bedrock altitude change is arbitrary. Isostatic adjustment is the vertical movement of the lithosphere due to changing surface ice and water loads.</description>
  </entry>
  <entry id="bioluminescent_photon_rate_in_sea_water">
    <canonical_units>s-1 m-3</canonical_units>
    <description></description>
  </entry>
  <entry id="biomass_burning_carbon_flux">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;Biomass burning carbon&quot; refers to the rate at which biomass is burned by forest fires etc., expressed as the mass of carbon which it contains. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="bolus_eastward_sea_water_velocity">
    <canonical_units>m s-1</canonical_units>
    <description>Bolus velocity in an ocean model means the velocity due to a scheme representing eddy-induced effects which are not resolved on the grid scale of the model.  &quot;Eastward&quot; indicates a vector component which is positive when directed eastward (negative westward).</description>
  </entry>
  <entry id="bolus_northward_sea_water_velocity">
    <canonical_units>m s-1</canonical_units>
    <description>Bolus velocity in an ocean model means the velocity due to a scheme representing eddy-induced effects which are not resolved on the grid scale of the model.  &quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward).</description>
  </entry>
  <entry id="bolus_sea_water_x_velocity">
    <canonical_units>m s-1</canonical_units>
    <description>A velocity is a vector quantity. &quot;x&quot; indicates a vector component along the grid x-axis, when this is not true longitude, positive with increasing x. Bolus velocity in an ocean model means the velocity due to a scheme representing eddy-induced effects which are not resolved on the grid scale of the model.  bolus_sea_water_x_velocity is used in some parameterisations of lateral diffusion in the ocean. </description>
  </entry>
  <entry id="bolus_sea_water_y_velocity">
    <canonical_units>m s-1</canonical_units>
    <description>A velocity is a vector quantity. &quot;y&quot; indicates a vector component along the grid y-axis, when this is not true longitude, positive with increasing y. Bolus velocity in an ocean model means the velocity due to a scheme representing eddy-induced effects which are not resolved on the grid scale of the model. bolus_sea_water_y_velocity is used in some parameterisations of lateral diffusion in the ocean.</description>
  </entry>
  <entry id="bolus_upward_sea_water_velocity">
    <canonical_units>m s-1</canonical_units>
    <description>Bolus velocity in an ocean model means the velocity due to a scheme representing eddy-induced effects which are not resolved on the grid scale of the model.  &quot;Upward&quot; indicates a vector component which is positive when directed upward (negative downward).</description>
  </entry>
  <entry id="brightness_temperature">
    <canonical_units>K</canonical_units>
    <grib>118</grib>
    <description>The brightness temperature of a body is the temperature of a black body which radiates the same power per unit solid angle per unit area.</description>
  </entry>
  <entry id="brunt_vaisala_frequency_in_air">
    <canonical_units>s-1</canonical_units>
    <description>Frequency is the number of oscillations of a wave per unit time.</description>
  </entry>
  <entry id="canopy_and_surface_water_amount">
    <canonical_units>kg m-2</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Amount&quot; means mass per unit area. &quot;Water&quot; means water in all phases, including frozen i.e. ice and snow. &quot;Canopy&quot; means the plant or vegetation canopy. &quot;Canopy and surface water&quot; means the sum of water on the ground and on the canopy.</description>
  </entry>
  <entry id="canopy_height">
    <canonical_units>m</canonical_units>
    <description>Height is the vertical distance above the surface. &quot;Canopy&quot; means the plant or vegetation canopy.</description>
  </entry>
  <entry id="canopy_temperature">
    <canonical_units>K</canonical_units>
    <description>&quot;Canopy&quot; means the plant or vegetation canopy.  &quot;Canopy_temperature&quot; is the bulk temperature of the canopy, not the surface (skin) temperature.
</description>
  </entry>
  <entry id="canopy_throughfall_flux">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;Canopy&quot; means the plant or vegetation canopy.  &quot;Throughfall&quot; is the part of the precipitation flux that reaches the ground directly through the vegetative canopy, through intershrub spaces in the canopy, and as drip from the leaves, twigs, and stems (but not including snowmelt).  In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="canopy_water_amount">
    <canonical_units>kg m-2</canonical_units>
    <description>&quot;Amount&quot; means mass per unit area. &quot;Water&quot; means water in all phases, including frozen i.e. ice and snow. &quot;Canopy&quot; means the plant or vegetation canopy. The canopy water is the water on the canopy.</description>
  </entry>
  <entry id="cell_area">
    <canonical_units>m2</canonical_units>
    <description>&quot;Cell_area&quot; is the horizontal area of a gridcell.</description>
  </entry>
  <entry id="change_in_atmosphere_energy_content_due_to_change_in_sigma_coordinate_wrt_surface_pressure">
    <canonical_units>J m-2</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. 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. &quot;wrt&quot; means with respect to. &quot;Content&quot; indicates a quantity per unit area. The &quot;atmosphere content&quot; of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. &quot;Atmosphere energy content&quot; has not yet been precisely defined! Please express your views on this quantity on the CF email list. See Appendix D of the CF convention for information about dimensionless vertical coordinates.</description>
  </entry>
  <entry id="change_in_energy_content_of_atmosphere_layer_due_to_change_in_sigma_coordinate_wrt_surface_pressure">
    <canonical_units>J m-2</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. 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. &quot;wrt&quot; means with respect to. &quot;Content&quot; indicates a quantity per unit area. &quot;Layer&quot; 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. See Appendix D of the CF convention for information about dimensionless vertical coordinates.</description>
  </entry>
  <entry id="change_over_time_in_atmospheric_water_content_due_to_advection">
    <canonical_units>kg m-2</canonical_units>
    <description>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. &quot;change_over_time_in_X&quot; means change in a quantity X over a time-interval, which should be defined by the bounds of the time coordinate. &quot;Content&quot; indicates a quantity per unit area. &quot;Water&quot; means water in all phases.</description>
  </entry>
  <entry id="change_over_time_in_surface_snow_amount">
    <canonical_units>kg m-2</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;change_over_time_in_X&quot; means change in a quantity X over a time-interval, which should be defined by the bounds of the time coordinate. &quot;Amount&quot; means mass per unit area. Surface amount refers to the amount on the ground, excluding that on the plant or vegetation canopy.</description>
  </entry>
  <entry id="cloud_area_fraction">
    <canonical_units>1</canonical_units>
    <grib>71 E164</grib>
    <amip>clt</amip>
    <description>&quot;X_area_fraction&quot; means the fraction of horizontal area occupied by X. &quot;X_area&quot; means the horizontal area occupied by X within the grid cell. Cloud area fraction is also called &quot;cloud amount&quot; and &quot;cloud cover&quot;. The cloud area fraction is for the whole atmosphere column, as seen from the surface or the top of the atmosphere. The cloud area fraction in a layer of the atmosphere has the standard name cloud_area_fraction_in_atmosphere_layer.</description>
  </entry>
  <entry id="cloud_area_fraction_in_atmosphere_layer">
    <canonical_units>1</canonical_units>
    <amip>cl</amip>
    <description>&quot;Layer&quot; 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. &quot;X_area_fraction&quot; means the fraction of horizontal area occupied by X. &quot;X_area&quot; means the horizontal area occupied by X within the grid cell. Cloud area fraction is also called &quot;cloud amount&quot; and &quot;cloud cover&quot;.</description>
  </entry>
  <entry id="cloud_base_altitude">
    <canonical_units>m</canonical_units>
    <description>cloud_base refers to the base of the lowest cloud. Altitude is the (geometric) height above the geoid, which is the reference geopotential surface. The geoid is similar to mean sea level.</description>
  </entry>
  <entry id="cloud_condensed_water_content_of_atmosphere_layer">
    <canonical_units>kg m-2</canonical_units>
    <description>&quot;condensed_water&quot; means liquid and ice. &quot;Content&quot; indicates a quantity per unit area. &quot;Layer&quot; 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.</description>
  </entry>
  <entry id="cloud_ice_content_of_atmosphere_layer">
    <canonical_units>kg m-2</canonical_units>
    <description>&quot;Content&quot; indicates a quantity per unit area. &quot;Layer&quot; 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.</description>
  </entry>
  <entry id="cloud_liquid_water_content_of_atmosphere_layer">
    <canonical_units>kg m-2</canonical_units>
    <description>&quot;Content&quot; indicates a quantity per unit area. &quot;Layer&quot; 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.</description>
  </entry>
  <entry id="cloud_top_altitude">
    <canonical_units>m</canonical_units>
    <description>cloud_top refers to the top of the highest cloud. Altitude is the (geometric) height above the geoid, which is the reference geopotential surface. The geoid is similar to mean sea level.</description>
  </entry>
  <entry id="concentration_of_chlorophyll_in_sea_water">
    <canonical_units>kg m-3</canonical_units>
    <description></description>
  </entry>
  <entry id="concentration_of_suspended_matter_in_sea_water">
    <canonical_units>kg m-3</canonical_units>
    <description></description>
  </entry>
  <entry id="convective_cloud_area_fraction">
    <canonical_units>1</canonical_units>
    <grib>72 E185</grib>
    <description>&quot;X_area_fraction&quot; means the fraction of horizontal area occupied by X. &quot;X_area&quot; means the horizontal area occupied by X within the grid cell. Cloud area fraction is also called &quot;cloud amount&quot; and &quot;cloud cover&quot;. The cloud area fraction is for the whole atmosphere column, as seen from the surface or the top of the atmosphere. The cloud area fraction in a layer of the atmosphere has the standard name cloud_area_fraction_in_atmosphere_layer. Convective cloud is that produced by the convection schemes in an atmosphere model.</description>
  </entry>
  <entry id="convective_cloud_area_fraction_in_atmosphere_layer">
    <canonical_units>1</canonical_units>
    <description>&quot;Layer&quot; 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. &quot;X_area_fraction&quot; means the fraction of horizontal area occupied by X. &quot;X_area&quot; means the horizontal area occupied by X within the grid cell. Cloud area fraction is also called &quot;cloud amount&quot; and &quot;cloud cover&quot;. Convective cloud is that produced by the convection schemes in an atmosphere model.</description>
  </entry>
  <entry id="convective_cloud_base_altitude">
    <canonical_units>m</canonical_units>
    <description>cloud_base refers to the base of the lowest cloud. Altitude is the (geometric) height above the geoid, which is the reference geopotential surface. The geoid is similar to mean sea level. Convective cloud is that produced by the convection schemes in an atmosphere model.</description>
  </entry>
  <entry id="convective_cloud_base_height">
    <canonical_units>m</canonical_units>
    <description>cloud_base refers to the base of the lowest cloud. Height is the vertical distance above the surface. Convective cloud is that produced by the convection schemes in an atmosphere model.</description>
  </entry>
  <entry id="convective_cloud_top_altitude">
    <canonical_units>m</canonical_units>
    <description>cloud_top refers to the top of the highest cloud. Altitude is the (geometric) height above the geoid, which is the reference geopotential surface. The geoid is similar to mean sea level. Convective cloud is that produced by the convection schemes in an atmosphere model.</description>
  </entry>
  <entry id="convective_cloud_top_height">
    <canonical_units>m</canonical_units>
    <description>cloud_top refers to the top of the highest cloud. Height is the vertical distance above the surface. Convective cloud is that produced by the convection schemes in an atmosphere model.</description>
  </entry>
  <entry id="convective_precipitation_amount">
    <canonical_units>kg m-2</canonical_units>
    <grib>63</grib>
    <description>&quot;Amount&quot; means mass per unit area.</description>
  </entry>
  <entry id="convective_precipitation_flux">
    <canonical_units>kg m-2 s-1</canonical_units>
    <amip>prc</amip>
    <description>In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="convective_rainfall_amount">
    <canonical_units>kg m-2</canonical_units>
    <description>&quot;Amount&quot; means mass per unit area.</description>
  </entry>
  <entry id="convective_rainfall_flux">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="convective_rainfall_rate">
    <canonical_units>m s-1</canonical_units>
    <description></description>
  </entry>
  <entry id="convective_snowfall_amount">
    <canonical_units>kg m-2</canonical_units>
    <grib>78</grib>
    <description>&quot;Amount&quot; means mass per unit area.</description>
  </entry>
  <entry id="convective_snowfall_flux">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="coriolis_parameter">
    <canonical_units>s-1</canonical_units>
    <description>The Coriolis parameter is twice the component of the earth's angular velocity about the local vertical i.e. 2 W sin L, where L is latitude and W the angular speed of the earth.</description>
  </entry>
  <entry id="correction_for_model_negative_specific_humidity">
    <canonical_units>1</canonical_units>
    <description>A numerical correction which is added to modelled negative specific humidities in order to obtain a value of zero.</description>
  </entry>
  <entry id="depth">
    <canonical_units>m</canonical_units>
    <description>Depth is the vertical distance below the surface.</description>
  </entry>
  <entry id="depth_at_maximum_upward_derivative_of_sea_water_potential_temperature">
    <canonical_units>m</canonical_units>
    <description>This quantity, often used to indicate the &quot;thermocline depth&quot;, is the depth of the maximum vertical gradient of sea water potential temperature.  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.</description>
  </entry>
  <entry id="depth_of_isosurface_of_sea_water_potential_temperature">
    <canonical_units>m</canonical_units>
    <description>This quantity, sometimes called the &quot;isotherm depth&quot;, 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.</description>
  </entry>
  <entry id="dew_point_depression">
    <canonical_units>K</canonical_units>
    <grib>18</grib>
    <description>Dew point depression is also called dew point deficit. It is the amount by which the air temperature exceeds its dew point temperature. Dew point temperature is the temperature at which a parcel of air reaches saturation upon being cooled at constant pressure and specific humidity.</description>
  </entry>
  <entry id="dew_point_temperature">
    <canonical_units>K</canonical_units>
    <grib>17</grib>
    <description>Dew point temperature is the temperature at which a parcel of air reaches saturation upon being cooled at constant pressure and specific humidity.</description>
  </entry>
  <entry id="difference_of_air_pressure_from_model_reference">
    <canonical_units>Pa</canonical_units>
    <description>In some atmosphere models, the difference of air pressure from model reference is a prognostic variable, instead of the air pressure itself. The model reference air pressure is a model-dependent constant.</description>
  </entry>
  <entry id="dimensionless_exner_function">
    <canonical_units>1</canonical_units>
    <description>The term &quot;Exner function&quot; is applied to various quantities in the literature. &quot;Dimensionless Exner function&quot; is the standard name of (p/p0)^(R/Cp), where p is pressure, p0 a reference pressure, R the gas constant and Cp the specific heat at constant pressure. This quantity is also the ratio of in-situ to potential temperature. Standard names for other variants can be defined on request.</description>
  </entry>
  <entry id="direction_of_sea_ice_velocity">
    <canonical_units>degree</canonical_units>
    <grib>93</grib>
    <description>&quot;direction_of_X&quot; means direction of a vector, a bearing. A velocity is a vector quantity. Sea ice velocity is defined as a two-dimensional vector, with no vertical component.</description>
  </entry>
  <entry id="direction_of_sea_water_velocity">
    <canonical_units>degree</canonical_units>
    <grib>47</grib>
    <description>&quot;direction_of_X&quot; means direction of a vector, a bearing. A velocity is a vector quantity.</description>
  </entry>
  <entry id="dissipation_in_atmosphere_boundary_layer">
    <canonical_units>W m-2</canonical_units>
    <grib>E145</grib>
    <description></description>
  </entry>
  <entry id="divergence_of_sea_ice_velocity">
    <canonical_units>s-1</canonical_units>
    <grib>98</grib>
    <description>&quot;[horizontal_]divergence_of_X&quot; means [horizontal] divergence of a vector X; if X does not have a vertical component then &quot;horizontal&quot; should be omitted. A velocity is a vector quantity. Sea ice velocity is defined as a two-dimensional vector, with no vertical component.</description>
  </entry>
  <entry id="divergence_of_wind">
    <canonical_units>s-1</canonical_units>
    <grib>44 E155</grib>
    <description>&quot;[horizontal_]divergence_of_X&quot; means [horizontal] divergence of a vector X; if X does not have a vertical component then &quot;horizontal&quot; should be omitted. Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)</description>
  </entry>
  <entry id="downward_dry_static_energy_flux_due_to_diffusion">
    <canonical_units>W m-2</canonical_units>
    <description>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. &quot;Downward&quot; indicates a vector component which is positive when directed downward (negative upward). Dry static energy is the sum of enthalpy and potential energy (itself the sum of gravitational and centripetal potential energy). Enthalpy can be written either as (1) CpT, where Cp is heat capacity at constant pressure, T is absolute temperature, or (2) U+pV, where U is internal energy, p is pressure and V is volume. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="downward_eastward_momentum_flux_in_air">
    <canonical_units>Pa</canonical_units>
    <grib>124</grib>
    <description>&quot;Eastward&quot; indicates a vector component which is positive when directed eastward (negative westward). &quot;Downward&quot; indicates a vector component which is positive when directed downward (negative upward). &quot;Downward eastward&quot; indicates the ZX component of a tensor. Momentum flux is dimensionally equivalent to stress and pressure. It is a tensor quantity. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="downward_eastward_stress_at_sea_ice_base">
    <canonical_units>Pa</canonical_units>
    <description>&quot;Eastward&quot; indicates a vector component which is positive when directed eastward (negative westward). &quot;Downward&quot; indicates a vector component which is positive when directed downward (negative upward). &quot;Downward eastward&quot; indicates the ZX component of a tensor. A downward eastward stress is a downward flux of eastward momentum, which accelerates the lower medium eastward and the upper medium westward.</description>
  </entry>
  <entry id="downward_heat_flux_at_ground_level_in_snow">
    <canonical_units>W m-2</canonical_units>
    <description>ground_level means the land surface (beneath the snow and surface water, if any). &quot;Downward&quot; indicates a vector component which is positive when directed downward (negative upward). In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="downward_heat_flux_at_ground_level_in_soil">
    <canonical_units>W m-2</canonical_units>
    <description>ground_level means the land surface (beneath the snow and surface water, if any). &quot;Downward&quot; indicates a vector component which is positive when directed downward (negative upward). In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="downward_heat_flux_in_air">
    <canonical_units>W m-2</canonical_units>
    <description>&quot;Downward&quot; 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, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="downward_heat_flux_in_sea_ice">
    <canonical_units>W m-2</canonical_units>
    <description>&quot;Downward&quot; indicates a vector component which is positive when directed downward (negative upward). In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="downward_heat_flux_in_soil">
    <canonical_units>W m-2</canonical_units>
    <description>&quot;Downward&quot; indicates a vector component which is positive when directed downward (negative upward). In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="downward_northward_momentum_flux_in_air">
    <canonical_units>Pa</canonical_units>
    <grib>125</grib>
    <description>&quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). &quot;Downward&quot; indicates a vector component which is positive when directed downward (negative upward). &quot;Downward northward&quot; indicates the ZY component of a tensor. Momentum flux is dimensionally equivalent to stress and pressure. It is a tensor quantity. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="downward_northward_stress_at_sea_ice_base">
    <canonical_units>Pa</canonical_units>
    <description>&quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). &quot;Downward&quot; indicates a vector component which is positive when directed downward (negative upward). &quot;Downward northward&quot; indicates the ZY component of a tensor. A downward northward stress is a downward flux of northward momentum, which accelerates the lower medium northward and the upper medium southward.</description>
  </entry>
  <entry id="downward_sea_ice_basal_salt_flux">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;Downward&quot; indicates a vector component which is positive when directed downward (negative upward). In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="downward_water_vapor_flux_in_air_due_to_diffusion">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>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. &quot;Downward&quot; indicates a vector component which is positive when directed downward (negative upward). In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="downward_x_stress_at_sea_ice_base">
    <canonical_units>Pa</canonical_units>
    <description>&quot;x&quot; indicates a vector component along the grid x-axis, when this is not true longitude, positive with increasing x. &quot;Downward&quot; indicates a vector component which is positive when directed downward (negative upward).</description>
  </entry>
  <entry id="downward_y_stress_at_sea_ice_base">
    <canonical_units>Pa</canonical_units>
    <description>&quot;y&quot; indicates a vector component along the grid y-axis, when this is not true latitude, positive with increasing y. &quot;Downward&quot; indicates a vector component which is positive when directed downward (negative upward).</description>
  </entry>
  <entry id="downwelling_longwave_flux_in_air">
    <canonical_units>W m-2</canonical_units>
    <description>&quot;longwave&quot; means longwave radiation. Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. When thought of as being incident on a surface, a radiative flux is sometimes called &quot;irradiance&quot;. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called &quot;vector irradiance&quot;. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="downwelling_longwave_radiance_in_air">
    <canonical_units>W m-2 sr-1</canonical_units>
    <description>&quot;longwave&quot; means longwave radiation. Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. Radiance is the radiative flux in a particular direction, per unit of solid angle. The direction from which it is coming must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead.</description>
  </entry>
  <entry id="downwelling_photon_flux_in_sea_water">
    <canonical_units>mol m-2 s-1</canonical_units>
    <description>Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. A photon flux is specified in terms of numbers of photons expressed in moles. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="downwelling_photon_radiance_in_sea_water">
    <canonical_units>mol m-2 s-1 sr-1</canonical_units>
    <description>Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. Photon radiance is the photon flux in a particular direction, per unit of solid angle. The direction from which it is coming must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead. A photon flux is specified in terms of numbers of photons expressed in moles.</description>
  </entry>
  <entry id="downwelling_photon_spherical_irradiance_in_sea_water">
    <canonical_units>mol m-2 s-1</canonical_units>
    <description>Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. Photon spherical irradiance is the photon flux incident on unit area of a hemispherical (or &quot;2-pi&quot;) collector. A photon flux is specified in terms of numbers of photons expressed in moles.</description>
  </entry>
  <entry id="downwelling_photosynthetic_photon_flux_in_sea_water">
    <canonical_units>mol m-2 s-1</canonical_units>
    <description>Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. &quot;Photosynthetic&quot; radiation is the part of the spectrum which is used in photosynthesis e.g. 300-700 nm. The range of wavelengths could be specified precisely by the bounds of a coordinate of radiation_wavelength. A photon flux is specified in terms of numbers of photons expressed in moles. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="downwelling_photosynthetic_photon_radiance_in_sea_water">
    <canonical_units>mol m-2 s-1 sr-1</canonical_units>
    <description>Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. Photon radiance is the photon flux in a particular direction, per unit of solid angle. The direction from which it is coming must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead. &quot;Photosynthetic&quot; radiation is the part of the spectrum which is used in photosynthesis e.g. 300-700 nm. The range of wavelengths could be specified precisely by the bounds of a coordinate of radiation_wavelength. A photon flux is specified in terms of numbers of photons expressed in moles.</description>
  </entry>
  <entry id="downwelling_photosynthetic_photon_spherical_irradiance_in_sea_water">
    <canonical_units>mol m-2 s-1</canonical_units>
    <description>Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. &quot;Photosynthetic&quot; radiation is the part of the spectrum which is used in photosynthesis e.g. 300-700 nm. The range of wavelengths could be specified precisely by the bounds of a coordinate of radiation_wavelength. Photon spherical irradiance is the photon flux incident on unit area of a hemispherical (or &quot;2-pi&quot;) collector. A photon flux is specified in terms of numbers of photons expressed in moles.</description>
  </entry>
  <entry id="downwelling_photosynthetic_radiance_in_sea_water">
    <canonical_units>W m-2 sr-1</canonical_units>
    <description>Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. Radiance is the radiative flux in a particular direction, per unit of solid angle. The direction from which it is coming must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead. &quot;Photosynthetic&quot; radiation is the part of the spectrum which is used in photosynthesis e.g. 300-700 nm. The range of wavelengths could be specified precisely by the bounds of a coordinate of radiation_wavelength.</description>
  </entry>
  <entry id="downwelling_photosynthetic_radiative_flux_in_sea_water">
    <canonical_units>W m-2</canonical_units>
    <description>Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. Radiative flux is the sum of shortwave and longwave radiative fluxes. &quot;Photosynthetic&quot; radiation is the part of the spectrum which is used in photosynthesis e.g. 300-700 nm. The range of wavelengths could be specified precisely by the bounds of a coordinate of radiation_wavelength. When thought of as being incident on a surface, a radiative flux is sometimes called &quot;irradiance&quot;. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called &quot;vector irradiance&quot;. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="downwelling_photosynthetic_spherical_irradiance_in_sea_water">
    <canonical_units>W m-2</canonical_units>
    <description>Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. &quot;Photosynthetic&quot; radiation is the part of the spectrum which is used in photosynthesis e.g. 300-700 nm. The range of wavelengths could be specified precisely by the bounds of a coordinate of radiation_wavelength. Spherical irradiance is the radiation incident on unit area of a hemispherical (or &quot;2-pi&quot;) collector. It is sometimes called &quot;scalar irradiance&quot;. The direction (up/downwelling) is specified. Radiation incident on a 4-pi collector has standard names of &quot;omnidirectional spherical irradiance&quot;.</description>
  </entry>
  <entry id="downwelling_radiance_in_sea_water">
    <canonical_units>W m-2 sr-1</canonical_units>
    <description>Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. Radiance is the radiative flux in a particular direction, per unit of solid angle. The direction from which it is coming must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead.</description>
  </entry>
  <entry id="downwelling_radiative_flux_in_sea_water">
    <canonical_units>W m-2</canonical_units>
    <description>Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. Radiative flux is the sum of shortwave and longwave radiative fluxes. When thought of as being incident on a surface, a radiative flux is sometimes called &quot;irradiance&quot;. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called &quot;vector irradiance&quot;. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="downwelling_shortwave_flux_in_air">
    <canonical_units>W m-2</canonical_units>
    <description>&quot;shortwave&quot; means shortwave radiation. Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. When thought of as being incident on a surface, a radiative flux is sometimes called &quot;irradiance&quot;. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called &quot;vector irradiance&quot;. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="downwelling_shortwave_radiance_in_air">
    <canonical_units>W m-2 sr-1</canonical_units>
    <description>&quot;shortwave&quot; means shortwave radiation. Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. Radiance is the radiative flux in a particular direction, per unit of solid angle. The direction from which it is coming must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead.</description>
  </entry>
  <entry id="downwelling_spectral_photon_flux_in_sea_water">
    <canonical_units>mol m-2 s-1 m-1</canonical_units>
    <description>Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. A photon flux is specified in terms of numbers of photons expressed in moles. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="downwelling_spectral_photon_radiance_in_sea_water">
    <canonical_units>mol m-2 s-1 m-1 sr-1</canonical_units>
    <description>Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. Photon radiance is the photon flux in a particular direction, per unit of solid angle. The direction from which it is coming must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead. A photon flux is specified in terms of numbers of photons expressed in moles.</description>
  </entry>
  <entry id="downwelling_spectral_photon_spherical_irradiance_in_sea_water">
    <canonical_units>mol m-2 s-1 m-1</canonical_units>
    <description>Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. &quot;spectral&quot; means per unit wavelength or as a function of wavelength; spectral quantities are sometimes called &quot;monochromatic&quot;. Radiation wavelength has standard name radiation_wavelength. Photon spherical irradiance is the photon flux incident on unit area of a hemispherical (or &quot;2-pi&quot;) collector. A photon flux is specified in terms of numbers of photons expressed in moles.</description>
  </entry>
  <entry id="downwelling_spectral_radiance_in_air">
    <canonical_units>W m-2 m-1 sr-1</canonical_units>
    <description>Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. &quot;spectral&quot; means per unit wavelength or as a function of wavelength; spectral quantities are sometimes called &quot;monochromatic&quot;. Radiation wavelength has standard name radiation_wavelength. Radiance is the radiative flux in a particular direction, per unit of solid angle. The direction from which it is coming must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead.</description>
  </entry>
  <entry id="downwelling_spectral_radiance_in_sea_water">
    <canonical_units>W m-2 m-1 sr-1</canonical_units>
    <description>Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. &quot;spectral&quot; means per unit wavelength or as a function of wavelength; spectral quantities are sometimes called &quot;monochromatic&quot;. Radiation wavelength has standard name radiation_wavelength. Radiance is the radiative flux in a particular direction, per unit of solid angle. The direction from which it is coming must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead.</description>
  </entry>
  <entry id="downwelling_spectral_radiative_flux_in_air">
    <canonical_units>W m-2 m-1</canonical_units>
    <description>Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. &quot;spectral&quot; means per unit wavelength or as a function of wavelength; spectral quantities are sometimes called &quot;monochromatic&quot;. Radiation wavelength has standard name radiation_wavelength. When thought of as being incident on a surface, a radiative flux is sometimes called &quot;irradiance&quot;. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called &quot;vector irradiance&quot;. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="downwelling_spectral_radiative_flux_in_sea_water">
    <canonical_units>W m-2 m-1</canonical_units>
    <description>Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. &quot;spectral&quot; means per unit wavelength or as a function of wavelength; spectral quantities are sometimes called &quot;monochromatic&quot;. Radiation wavelength has standard name radiation_wavelength. When thought of as being incident on a surface, a radiative flux is sometimes called &quot;irradiance&quot;. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called &quot;vector irradiance&quot;. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="downwelling_spectral_spherical_irradiance_in_sea_water">
    <canonical_units>W m-2 m-1</canonical_units>
    <description>Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. &quot;spectral&quot; means per unit wavelength or as a function of wavelength; spectral quantities are sometimes called &quot;monochromatic&quot;. Radiation wavelength has standard name radiation_wavelength. Spherical irradiance is the radiation incident on unit area of a hemispherical (or &quot;2-pi&quot;) collector. It is sometimes called &quot;scalar irradiance&quot;. The direction (up/downwelling) is specified. Radiation incident on a 4-pi collector has standard names of &quot;omnidirectional spherical irradiance&quot;.</description>
  </entry>
  <entry id="downwelling_spherical_irradiance_in_sea_water">
    <canonical_units>W m-2</canonical_units>
    <description>Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. Spherical irradiance is the radiation incident on unit area of a hemispherical (or &quot;2-pi&quot;) collector. It is sometimes called &quot;scalar irradiance&quot;. The direction (up/downwelling) is specified. Radiation incident on a 4-pi collector has standard names of &quot;omnidirectional spherical irradiance&quot;.</description>
  </entry>
  <entry id="dry_energy_content_of_atmosphere_layer">
    <canonical_units>J m-2</canonical_units>
    <description>&quot;Content&quot; indicates a quantity per unit area. &quot;Layer&quot; 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. Dry energy is the sum of dry static energy and kinetic energy. Dry static energy is the sum of enthalpy and potential energy (itself the sum of gravitational and centripetal potential energy). Enthalpy can be written either as (1) CpT, where Cp is heat capacity at constant pressure, T is absolute temperature, or (2) U+pV, where U is internal energy, p is pressure and V is volume.</description>
  </entry>
  <entry id="dry_static_energy_content_of_atmosphere_layer">
    <canonical_units>J m-2</canonical_units>
    <description>&quot;Content&quot; indicates a quantity per unit area. &quot;Layer&quot; 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. Dry static energy is the sum of enthalpy and potential energy (itself the sum of gravitational and centripetal potential energy). Enthalpy can be written either as (1) CpT, where Cp is heat capacity at constant pressure, T is absolute temperature, or (2) U+pV, where U is internal energy, p is pressure and V is volume.</description>
  </entry>
  <entry id="duration_of_sunshine">
    <canonical_units>s</canonical_units>
    <description>The WMO definition of sunshine is that the surface incident radiative flux from the solar beam (i.e. excluding diffuse skylight) exceeds 120 W m-2. &quot;Duration&quot; is the length of time for which a condition holds.</description>
  </entry>
  <entry id="dynamic_tropopause_potential_temperature">
    <canonical_units>K</canonical_units>
    <description>The dynamical tropopause used in interpreting the dynamics of the upper troposphere and lower stratosphere.  There are various definitions of dynamical tropopause in the scientific literature.</description>
  </entry>
<entry id="eastward_atmosphere_dry_static_energy_transport_across_unit_distance">
    <canonical_units>W m-1</canonical_units>
    <description>&quot;Eastward&quot; indicates a vector component which is positive when directed eastward (negative westward). Transport across_unit_distance means expressed per unit distance normal to the direction of transport. Dry static energy is the sum of enthalpy and potential energy (itself the sum of gravitational and centripetal potential energy). Enthalpy can be written either as (1) CpT, where Cp is heat capacity at constant pressure, T is absolute temperature, or (2) U+pV, where U is internal energy, p is pressure and V is volume.</description>
  </entry>
  <entry id="eastward_atmosphere_water_transport_across_unit_distance">
    <canonical_units>kg s-1 m-1</canonical_units>
    <description>&quot;Water&quot; means water in all phases. &quot;Eastward&quot; indicates a vector component which is positive when directed eastward (negative westward). Transport across_unit_distance means expressed per unit distance normal to the direction of transport.</description>
  </entry>
  <entry id="eastward_atmosphere_water_vapor_transport_across_unit_distance">
    <canonical_units>kg m-1 s-1</canonical_units>
    <description>&quot;Eastward&quot; indicates a vector component which is positive when directed eastward (negative westward). Transport across_unit_distance means expressed per unit distance normal to the direction of transport.</description>
  </entry>
  <entry id="eastward_mass_flux_of_air">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;Eastward&quot; indicates a vector component which is positive when directed eastward (negative westward). In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="eastward_momentum_flux_correction">
    <canonical_units>Pa</canonical_units>
    <amip>tauucorr</amip>
    <description>&quot;Eastward&quot; indicates a vector component which is positive when directed eastward (negative westward). Momentum flux is dimensionally equivalent to stress and pressure. It is a tensor quantity. Flux correction is also called &quot;flux adjustment&quot;. A positive flux correction is downward i.e. added to the ocean. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="eastward_sea_ice_velocity">
    <canonical_units>m s-1</canonical_units>
    <grib>95</grib>
    <description>A velocity is a vector quantity. &quot;Eastward&quot; indicates a vector component which is positive when directed eastward (negative westward). Sea ice velocity is defined as a two-dimensional vector, with no vertical component.</description>
  </entry>
  <entry id="eastward_sea_water_velocity">
    <canonical_units>m s-1</canonical_units>
    <grib>49</grib>
    <description>A velocity is a vector quantity. &quot;Eastward&quot; indicates a vector component which is positive when directed eastward (negative westward).</description>
  </entry>
  <entry id="eastward_transformed_eulerian_mean_air_velocity">
    <canonical_units>m s-1</canonical_units>
    <description>&quot;Eastward&quot; indicates a vector component which is positive when directed eastward (negative westward).</description>
  </entry>
  <entry id="eastward_water_vapor_flux">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;Eastward&quot; indicates a vector component which is positive when directed eastward (negative westward). In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="eastward_water_vapor_transport_across_unit_distance_in_atmosphere_layer">
    <canonical_units>kg m-1 s-1</canonical_units>
    <description>&quot;Layer&quot; 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. &quot;Eastward&quot; indicates a vector component which is positive when directed eastward (negative westward). Transport across_unit_distance means expressed per unit distance normal to the direction of transport.</description>
  </entry>
  <entry id="eastward_wind">
    <canonical_units>m s-1</canonical_units>
    <grib>33 E131</grib>
    <amip>ua</amip>
    <description>&quot;Eastward&quot; indicates a vector component which is positive when directed eastward (negative westward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)</description>
  </entry>
  <entry id="eastward_wind_shear">
    <canonical_units>s-1</canonical_units>
    <grib>45</grib>
    <description>&quot;Eastward&quot; indicates a vector component which is positive when directed eastward (negative westward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.) Wind shear is the derivative of wind with respect to height.</description>
  </entry>
  <entry id="enthalpy_content_of_atmosphere_layer">
    <canonical_units>J m-2</canonical_units>
    <description>&quot;Content&quot; indicates a quantity per unit area. &quot;Layer&quot; 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. Enthalpy can be written either as (1) CpT, where Cp is heat capacity at constant pressure, T is absolute temperature, or (2) U+pV, where U is internal energy, p is pressure and V is volume.</description>
  </entry>
  <entry id="equilibrium_line_altitude">
    <canonical_units>m</canonical_units>
    <description>Altitude is the (geometric) height above the geoid, which is the reference geopotential surface. The geoid is similar to mean sea level. The equilibrium line is the locus of points on a land ice surface at which ice accumulation balances ice ablation over the year.</description>
  </entry>
  <entry id="equivalent_potential_temperature">
    <canonical_units>K</canonical_units>
    <description>Potential temperature is the temperature a parcel of air or sea water would have if moved adiabatically to sea level pressure.</description>
  </entry>
  <entry id="equivalent_pressure_of_atmosphere_ozone_content">
    <canonical_units>Pa</canonical_units>
    <description>&quot;Content&quot; indicates a quantity per unit area. The &quot;atmosphere content&quot; of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The equivalent pressure of a particular constituent of the atmosphere is the surface pressure exerted by the weight of that constituent alone.</description>
  </entry>
  <entry id="equivalent_temperature">
    <canonical_units>K</canonical_units>
    <description></description>
  </entry>
  <entry id="equivalent_thickness_at_stp_of_atmosphere_ozone_content">
    <canonical_units>m</canonical_units>
    <grib>10</grib>
    <description>&quot;stp&quot; means standard temperature (0 degC) and pressure (101325 Pa). &quot;Content&quot; indicates a quantity per unit area. The &quot;atmosphere content&quot; of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. The equivalent thickness at STP of a particular constituent of the atmosphere is the thickness of the layer that the gas would occupy if it was separated from the other constituents and gathered together at STP.</description>
  </entry>
  <entry id="ertel_potential_vorticity">
    <canonical_units>K m2 kg-1 s-1</canonical_units>
    <amip>vorpot</amip>
    <description></description>
  </entry>
  <entry id="forecast_period">
    <canonical_units>s</canonical_units>
    <description>Forecast period is the time interval between the forecast reference time and the validity time. A period is an interval of time, or the time-period of an oscillation.</description>
  </entry>
  <entry id="forecast_reference_time">
    <canonical_units>s</canonical_units>
    <description>The forecast reference time in NWP is the &quot;data time&quot;, the time of the analysis from which the forecast was made. It is not the time for which the forecast is valid; the standard name of time should be used for that time.</description>
  </entry>
  <entry id="fractional_saturation_of_oxygen_in_sea_water">
    <canonical_units>1</canonical_units>
    <description>Fractional saturation is the ratio of some measure of concentration to the saturated value of the same quantity.</description>
  </entry>
  <entry id="freezing_level_altitude">
    <canonical_units>m</canonical_units>
    <description>Altitude is the (geometric) height above the geoid, which is the reference geopotential surface. The geoid is similar to mean sea level.</description>
  </entry>
  <entry id="freezing_temperature_of_sea_water">
    <canonical_units>K</canonical_units>
    <description></description>
  </entry>
  <entry id="frozen_water_content_of_soil_layer">
    <canonical_units>kg m-2</canonical_units>
    <description>&quot;frozen_water&quot; means ice. &quot;Content&quot; indicates a quantity per unit area. &quot;Layer&quot; 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. Quantities defined for a soil layer must have a vertical coordinate variable with boundaries indicating the extent of the layer(s).</description>
  </entry>
  <entry id="geoid_height_above_reference_ellipsoid">
    <canonical_units>m</canonical_units>
    <description>The geoid is a surface of constant geopotential with which mean sea level would coincide if the ocean were at rest. (The volume enclosed between the geoid and the sea floor equals the mean volume of water in the ocean.) In an ocean GCM the geoid is the surface of zero depth, or the rigid lid if the model uses that approximation.  A reference ellipsoid is a regular mathematical figure that approximates the irregular shape of the geoid. A number of reference ellipsoids are defined for use in the field of geodesy.</description>
  </entry>
  <entry id="geopotential">
    <canonical_units>m2 s-2</canonical_units>
    <grib>6 E129</grib>
    <description>Geopotential is the sum of the specific gravitational potential energy relative to the geoid and the specific centripetal potential energy.</description>
  </entry>
  <entry id="geopotential_height">
    <canonical_units>m</canonical_units>
    <grib>7 E156</grib>
    <amip>zg</amip>
    <description>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.</description>
  </entry>
  <entry id="geopotential_height_anomaly">
    <canonical_units>m</canonical_units>
    <grib>27</grib>
    <description>&quot;anomaly&quot; means difference from climatology. 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.</description>
  </entry>
  <entry id="geostrophic_eastward_wind">
    <canonical_units>m s-1</canonical_units>
    <description>&quot;Eastward&quot; indicates a vector component which is positive when directed eastward (negative westward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)</description>
  </entry>
  <entry id="geostrophic_northward_wind">
    <canonical_units>m s-1</canonical_units>
    <description>&quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)</description>
  </entry>
  <entry id="global_average_sea_level_change">
    <canonical_units>m</canonical_units>
    <description>Global average sea level change is due to change in volume of the water in the ocean, caused by mass and/or density change, or to change in the volume of the ocean basins, caused by tectonics etc. It is sometimes called &quot;eustatic&quot;, which is a term that also has other definitions. It differs from the change in the global average sea surface height relative to the centre of the Earth by the global average vertical movement of the ocean floor. Zero sea level change is an arbitrary level.</description>
  </entry>
  <entry id="global_average_thermosteric_sea_level_change">
    <canonical_units>m</canonical_units>
    <description>Global average thermosteric sea level change is the part caused by change in density due to change in temperature i.e. thermal expansion. Zero sea level change is an arbitrary level.</description>
  </entry>
  <entry id="grid_latitude">
    <canonical_units>degree</canonical_units>
    <description>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.</description>
  </entry>
  <entry id="grid_longitude">
    <canonical_units>degree</canonical_units>
    <description>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.</description>
  </entry>
  <entry id="gross_primary_productivity_of_carbon">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>Gross primary productivity is the rate of synthesis of biomass per unit area from inorganic precursors by autotrophs, especially by photosynthesising plants using sunlight for energy. The producers also respire some of this biomass and the difference is net_primary_producivity. &quot;Productivity of carbon&quot; refers to the production of biomass expressed as the mass of carbon which it contains.</description>
  </entry>
  <entry id="heat_flux_correction">
    <canonical_units>W m-2</canonical_units>
    <amip>hfcorr</amip>
    <description>Flux correction is also called &quot;flux adjustment&quot;. A positive flux correction is downward i.e. added to the ocean. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="heat_flux_into_sea_water_due_to_newtonian_relaxation">
    <canonical_units>W m-2</canonical_units>
    <description>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.  The heat_flux_into_sea_water_due_to_newtonian_relaxation is the heat flux resulting from the Newtonian relaxation of the sea surface temperature. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="height">
    <canonical_units>m</canonical_units>
    <amip>zh</amip>
    <description>Height is the vertical distance above the surface.</description>
  </entry>
  <entry id="height_above_reference_ellipsoid">
    <canonical_units>m</canonical_units>
    <description>Height is the vertical distance above a surface. 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.</description>
  </entry>
  <entry id="height_above_sea_floor">
    <canonical_units>m</canonical_units>
    <description></description>
  </entry>
  <entry id="height_at_cloud_top">
    <canonical_units>m</canonical_units>
    <description>cloud_top refers to the top of the highest cloud. Height is the vertical distance above the surface.</description>
  </entry>
  <entry id="heterotrophic_respiration_carbon_flux">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;Respiration carbon&quot; refers to the rate at which biomass is respired expressed as the mass of carbon which it contains. Heterotrophic respiration is respiration by heterotrophs (&quot;consumers&quot;), 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 (&quot;producers&quot;) do. Heterotrophic respiration goes on both above and within the soil. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="horizontal_atmosphere_dry_energy_transport">
    <canonical_units>W m-2</canonical_units>
    <description>Dry energy is the sum of dry static energy and kinetic energy. Dry static energy is the sum of enthalpy and potential energy (itself the sum of gravitational and centripetal potential energy). Enthalpy can be written either as (1) CpT, where Cp is heat capacity at constant pressure, T is absolute temperature, or (2) U+pV, where U is internal energy, p is pressure and V is volume.</description>
  </entry>
  <entry id="horizontal_dry_energy_transport_in_atmosphere_layer">
    <canonical_units>W m-2</canonical_units>
    <description>&quot;Layer&quot; 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. Dry energy is the sum of dry static energy and kinetic energy. Dry static energy is the sum of enthalpy and potential energy (itself the sum of gravitational and centripetal potential energy). Enthalpy can be written either as (1) CpT, where Cp is heat capacity at constant pressure, T is absolute temperature, or (2) U+pV, where U is internal energy, p is pressure and V is volume.</description>
  </entry>
  <entry id="humidity_mixing_ratio">
    <canonical_units>1</canonical_units>
    <grib>53</grib>
    <description>Humidity mixing ratio of a parcel of moist air is the ratio of the mass of water vapor to the mass of dry air.</description>
  </entry>
  <entry id="integral_of_air_temperature_deficit_wrt_time">
    <canonical_units>K s</canonical_units>
    <description>&quot;integral_of_Y_wrt_X&quot; means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. &quot;wrt&quot; means with respect to. Air temperature is the bulk temperature of the air, not the surface (skin) temperature. The air temperature deficit is the air temperature threshold minus the air temperature. Its integral with respect to time is often called after its units of &quot;degree-days&quot;.</description>
  </entry>
  <entry id="integral_of_air_temperature_excess_wrt_time">
    <canonical_units>K s</canonical_units>
    <description>&quot;integral_of_Y_wrt_X&quot; means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. &quot;wrt&quot; means with respect to. Air temperature is the bulk temperature of the air, not the surface (skin) temperature. The air temperature excess is the air temperature minus the air temperature threshold. Its integral with respect to time is often called after its units of &quot;degree-days&quot;.</description>
  </entry>
  <entry id="integral_of_sea_water_potential_temperature_wrt_depth_expressed_as_heat_content">
    <canonical_units>J m-2</canonical_units>
    <description>&quot;integral_of_Y_wrt_X&quot; means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds.  &quot;wrt&quot; means with respect to. &quot;expressed_as_heat_content&quot; means that this quantity is calculated as the (assumed constant) specific heat capacity times density of sea water multiplied by the integral, over the specified layer of the ocean, of the sea water potential temperature wrt depth.</description>
  </entry>
  <entry id="integral_of_sea_water_temperature_wrt_depth_in_ocean_layer">
    <canonical_units>K m</canonical_units>
    <description>&quot;integral_of_Y_wrt_X&quot; means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. &quot;wrt&quot; means with respect to. &quot;Layer&quot; 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. Depth is the vertical distance below the surface.</description>
  </entry>
  <entry id="integral_of_surface_downward_latent_heat_flux_wrt_time">
    <canonical_units>W s m-2</canonical_units>
    <description>&quot;integral_of_Y_wrt_X&quot; means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. &quot;wrt&quot; means with respect to.  The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Downward&quot; indicates a vector component which is positive when directed downward (negative upward). 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, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="integral_of_surface_downward_sensible_heat_flux_wrt_time">
    <canonical_units>W s m-2</canonical_units>
    <description>&quot;integral_of_Y_wrt_X&quot; means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. &quot;wrt&quot; means with respect to.  The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Downward&quot; indicates a vector component which is positive when directed downward (negative upward).  The surface sensible heat flux, also called &quot;turbulent&quot; heat flux, is the exchange of heat between the surface and the air by motion of air. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="integral_of_surface_net_downward_longwave_flux_wrt_time">
    <canonical_units>W s m-2</canonical_units>
    <description>&quot;integral_of_Y_wrt_X&quot; means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. &quot;wrt&quot; means with respect to.  The surface called &quot;surface&quot; means the lower boundary of the atmosphere.  &quot;Downward&quot; indicates a vector component which is positive when directed downward (negative upward). Net downward radiation is the difference between radiation from above (downwelling) and radiation from below (upwelling). &quot;Longwave&quot; means longwave radiation.  In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="integral_of_surface_net_downward_shortwave_flux_wrt_time">
    <canonical_units>W s m-2</canonical_units>
    <description>&quot;integral_of_Y_wrt_X&quot; means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. &quot;wrt&quot; means with respect to.  The surface called &quot;surface&quot; means the lower boundary of the atmosphere.  &quot;Downward&quot; indicates a vector component which is positive when directed downward (negative upward). Net downward radiation is the difference between radiation from above (downwelling) and radiation from below (upwelling). &quot;Shortwave&quot; means shortwave radiation.  In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="integral_of_toa_net_downward_shortwave_flux_wrt_time">
    <canonical_units>W s m-2</canonical_units>
    <description>&quot;integral_of_Y_wrt_X&quot; means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. &quot;wrt&quot; means with respect to.  &quot;toa&quot; means top of atmosphere. &quot;Downward&quot; indicates a vector component which is positive when directed downward (negative upward). Net downward radiation is the difference between radiation from above (downwelling) and radiation from below (upwelling).  &quot;Shortwave&quot; means shortwave radiation.  In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="integral_of_toa_outgoing_longwave_flux_wrt_time">
    <canonical_units>W s m-2</canonical_units>
    <description>&quot;integral_of_Y_wrt_X&quot; means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. &quot;wrt&quot; means with respect to.  &quot;toa&quot; means top of atmosphere.  &quot;Longwave&quot; means longwave radiation.  The TOA outgoing longwave flux is the upwelling thermal radiative flux, often called the &quot;outgoing longwave radiation&quot; or &quot;OLR&quot;. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="isccp_cloud_area_fraction">
    <canonical_units>1</canonical_units>
    <amip>clisccp</amip>
    <description>&quot;X_area_fraction&quot; means the fraction of horizontal area occupied by X. &quot;X_area&quot; means the horizontal area occupied by X within the grid cell. Cloud area fraction is also called &quot;cloud amount&quot; and &quot;cloud cover&quot;. The cloud area fraction is for the whole atmosphere column, as seen from the surface or the top of the atmosphere. The cloud area fraction in a layer of the atmosphere has the standard name cloud_area_fraction_in_atmosphere_layer. The ISCCP cloud area fraction is diagnosed from atmosphere model output by the ISCCP simulator software in such a way as to be comparable with the observational diagnostics of ISCCP (the International Satellite Cloud Climatology Project).</description>
  </entry>
  <entry id="isotropic_longwave_radiance_in_air">
    <canonical_units>W m-2 sr-1</canonical_units>
    <description>&quot;longwave&quot; means longwave radiation. Radiance is the radiative flux in a particular direction, per unit of solid angle. If radiation is isotropic, the radiance is independent of direction, so the direction should not be specified. If the radiation is directionally dependent, a standard name of upwelling or downwelling radiance should be chosen instead.</description>
  </entry>
  <entry id="isotropic_shortwave_radiance_in_air">
    <canonical_units>W m-2 sr-1</canonical_units>
    <description>&quot;shortwave&quot; means shortwave radiation. Radiance is the radiative flux in a particular direction, per unit of solid angle. If radiation is isotropic, the radiance is independent of direction, so the direction should not be specified. If the radiation is directionally dependent, a standard name of upwelling or downwelling radiance should be chosen instead.</description>
  </entry>
  <entry id="isotropic_spectral_radiance_in_air">
    <canonical_units>W m-2 m-1 sr-1</canonical_units>
    <description>&quot;spectral&quot; means per unit wavelength or as a function of wavelength; spectral quantities are sometimes called &quot;monochromatic&quot;. Radiation wavelength has standard name radiation_wavelength. Radiance is the radiative flux in a particular direction, per unit of solid angle. If radiation is isotropic, the radiance is independent of direction, so the direction should not be specified. If the radiation is directionally dependent, a standard name of upwelling or downwelling radiance should be chosen instead.</description>
  </entry>
  <entry id="kinetic_energy_content_of_atmosphere_layer">
    <canonical_units>J m-2</canonical_units>
    <description>&quot;Content&quot; indicates a quantity per unit area. &quot;Layer&quot; 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.</description>
  </entry>
  <entry id="lagrangian_tendency_of_air_pressure">
    <canonical_units>Pa s-1</canonical_units>
    <grib>39 E135</grib>
    <amip>wap</amip>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time. The Lagrangian tendency of a quantity is its rate of change following the motion of the fluid, also called the &quot;material derivative&quot; or &quot;convective derivative&quot;. The Lagrangian tendency of air pressure, often called &quot;omega&quot;, plays the role of the upward component of air velocity when air pressure is being used as the vertical coordinate. If the vertical air velocity is upwards, it is negative when expressed as a tendency of air pressure; downwards is positive.</description>
  </entry>
  <entry id="lagrangian_tendency_of_atmosphere_sigma_coordinate">
    <canonical_units>s-1</canonical_units>
    <grib>38</grib>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time. The Lagrangian tendency of a quantity is its rate of change following the motion of the fluid, also called the &quot;material derivative&quot; or &quot;convective derivative&quot;. The Lagrangian tendency of sigma plays the role of the upward component of air velocity when the atmosphere sigma coordinate (a dimensionless atmosphere vertical coordinate) is being used as the vertical coordinate. If the vertical air velocity is upwards, it is negative when expressed as a tendency of sigma; downwards is positive. See Appendix D of the CF convention for information about dimensionless vertical coordinates.</description>
  </entry>
  <entry id="land_area_fraction">
    <canonical_units>1</canonical_units>
    <grib>81</grib>
    <amip>sftlf</amip>
    <description>&quot;X_area_fraction&quot; means the fraction of horizontal area occupied by X. &quot;X_area&quot; means the horizontal area occupied by X within the grid cell.</description>
  </entry>
  <entry id="land_binary_mask">
    <canonical_units>1</canonical_units>
    <grib>E172</grib>
    <description>X_binary_mask has 1 where condition X is met, 0 elsewhere. 1 = land, 0 = sea.</description>
  </entry>
  <entry id="land_cover">
    <canonical_units>1</canonical_units>
    <description>A variable with the standard name of land_cover contains strings which indicate the nature of the anthropogenic land use or vegetation e.g. urban, grass, needleleaf trees, ice. These strings have not yet been standardised. The alternative standard name of surface_cover is a generalisation of land_cover. Alternatively, the data variable may contain integers which can be translated to strings using flag_values and flag_meanings attributes.</description>
  </entry>
  <entry id="land_ice_area_fraction">
    <canonical_units>1</canonical_units>
    <amip>sftgif</amip>
    <description>&quot;X_area_fraction&quot; means the fraction of horizontal area occupied by X. &quot;X_area&quot; means the horizontal area occupied by X within the grid cell. &quot;Land ice&quot; means glaciers, ice-caps and ice-sheets resting on bedrock.</description>
  </entry>
  <entry id="land_ice_basal_melt_rate">
    <canonical_units>m s-1</canonical_units>
    <description>&quot;Land ice&quot; means glaciers, ice-caps and ice-sheets resting on bedrock. The land ice basal melt rate is the rate at which ice is lost per unit area at the base of the ice.</description>
  </entry>
  <entry id="land_ice_basal_x_velocity">
    <canonical_units>m s-1</canonical_units>
    <description>A velocity is a vector quantity. &quot;x&quot; indicates a vector component along the grid x-axis, when this is not true longitude, positive with increasing x. &quot;Land ice&quot; means glaciers, ice-caps and ice-sheets resting on bedrock.</description>
  </entry>
  <entry id="land_ice_basal_y_velocity">
    <canonical_units>m s-1</canonical_units>
    <description>A velocity is a vector quantity. &quot;y&quot; indicates a vector component along the grid y-axis, when this is not true latitude, positive with increasing y. &quot;Land ice&quot; means glaciers, ice-caps and ice-sheets resting on bedrock.</description>
  </entry>
  <entry id="land_ice_calving_rate">
    <canonical_units>m s-1</canonical_units>
    <description>&quot;Land ice&quot; means glaciers, ice-caps and ice-sheets resting on bedrock. The land ice calving rate is the rate at which ice is lost per unit area through calving into the ocean.</description>
  </entry>
  <entry id="land_ice_lwe_basal_melt_rate">
    <canonical_units>m s-1</canonical_units>
    <description>&quot;lwe&quot; means liquid water equivalent. &quot;Land ice&quot; means glaciers, ice-caps and ice-sheets resting on bedrock. The land ice basal melt rate is the rate at which ice is lost per unit area at the base of the ice.</description>
  </entry>
  <entry id="land_ice_lwe_calving_rate">
    <canonical_units>m s-1</canonical_units>
    <description>&quot;lwe&quot; means liquid water equivalent. &quot;Land ice&quot; means glaciers, ice-caps and ice-sheets resting on bedrock. The land ice calving rate is the rate at which ice is lost per unit area through calving into the ocean.</description>
  </entry>
  <entry id="land_ice_lwe_surface_specific_mass_balance">
    <canonical_units>m s-1</canonical_units>
    <description>&quot;lwe&quot; means liquid water equivalent. &quot;Land ice&quot; means glaciers, ice-caps and ice-sheets resting on bedrock. Specific mass balance means the net rate at which ice is added per unit area at the land ice surface.</description>
  </entry>
  <entry id="land_ice_sigma_coordinate">
    <canonical_units>1</canonical_units>
    <description>&quot;Land ice&quot; means glaciers, ice-caps and ice-sheets resting on bedrock.</description>
  </entry>
  <entry id="land_ice_surface_specific_mass_balance">
    <canonical_units>m s-1</canonical_units>
    <description>&quot;Land ice&quot; means glaciers, ice-caps and ice-sheets resting on bedrock. Specific mass balance means the net rate at which ice is added per unit area at the land ice surface.</description>
  </entry>
  <entry id="land_ice_temperature">
    <canonical_units>K</canonical_units>
    <description>&quot;Land ice&quot; means glaciers, ice-caps and ice-sheets resting on bedrock.</description>
  </entry>
  <entry id="land_ice_thickness">
    <canonical_units>m</canonical_units>
    <description>&quot;Land ice&quot; means glaciers, ice-caps and ice-sheets resting on bedrock.</description>
  </entry>
  <entry id="land_ice_vertical_mean_x_velocity">
    <canonical_units>m s-1</canonical_units>
    <description>A velocity is a vector quantity. &quot;x&quot; indicates a vector component along the grid x-axis, when this is not true longitude, positive with increasing x. &quot;Land ice&quot; means glaciers, ice-caps and ice-sheets resting on bedrock. The vertical mean land ice velocity is the average from the bedrock to the surface of the ice.</description>
  </entry>
  <entry id="land_ice_vertical_mean_y_velocity">
    <canonical_units>m s-1</canonical_units>
    <description>A velocity is a vector quantity. &quot;y&quot; indicates a vector component along the grid y-axis, when this is not true latitude, positive with increasing y. &quot;Land ice&quot; means glaciers, ice-caps and ice-sheets resting on bedrock. The vertical mean land ice velocity is the average from the bedrock to the surface of the ice.</description>
  </entry>
  <entry id="land_ice_x_velocity">
    <canonical_units>m s-1</canonical_units>
    <description>A velocity is a vector quantity. &quot;x&quot; indicates a vector component along the grid x-axis, when this is not true longitude, positive with increasing x. &quot;Land ice&quot; means glaciers, ice-caps and ice-sheets resting on bedrock.</description>
  </entry>
  <entry id="land_ice_y_velocity">
    <canonical_units>m s-1</canonical_units>
    <description>A velocity is a vector quantity. &quot;y&quot; indicates a vector component along the grid y-axis, when this is not true latitude, positive with increasing y. &quot;Land ice&quot; means glaciers, ice-caps and ice-sheets resting on bedrock.</description>
  </entry>
  <entry id="large_scale_cloud_area_fraction">
    <canonical_units>1</canonical_units>
    <description>&quot;X_area_fraction&quot; means the fraction of horizontal area occupied by X. &quot;X_area&quot; means the horizontal area occupied by X within the grid cell. Cloud area fraction is also called &quot;cloud amount&quot; and &quot;cloud cover&quot;. The cloud area fraction is for the whole atmosphere column, as seen from the surface or the top of the atmosphere. The cloud area fraction in a layer of the atmosphere has the standard name cloud_area_fraction_in_atmosphere_layer.</description>
  </entry>
  <entry id="large_scale_precipitation_amount">
    <canonical_units>kg m-2</canonical_units>
    <grib>62</grib>
    <description>&quot;Amount&quot; means mass per unit area.</description>
  </entry>
  <entry id="large_scale_precipitation_flux">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="large_scale_rainfall_amount">
    <canonical_units>kg m-2</canonical_units>
    <description>&quot;Amount&quot; means mass per unit area.</description>
  </entry>
  <entry id="large_scale_rainfall_flux">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="large_scale_rainfall_rate">
    <canonical_units>m s-1</canonical_units>
    <description></description>
  </entry>
  <entry id="large_scale_snowfall_amount">
    <canonical_units>kg m-2</canonical_units>
    <grib>79</grib>
    <description>&quot;Amount&quot; means mass per unit area.</description>
  </entry>
  <entry id="large_scale_snowfall_flux">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="latitude">
    <canonical_units>degree_north</canonical_units>
    <amip>latitude</amip>
    <description>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.</description>
  </entry>
  <entry id="leaf_area_index">
    <canonical_units>1</canonical_units>
    <description>&quot;X_area&quot; means the horizontal area occupied by X within the grid cell.</description>
  </entry>
  <entry id="liquid_water_content_of_snow_layer">
    <canonical_units>kg m-2</canonical_units>
    <description>&quot;Content&quot; indicates a quantity per unit area.</description>
  </entry>
  <entry id="liquid_water_content_of_soil_layer">
    <canonical_units>kg m-2</canonical_units>
    <description>&quot;Content&quot; indicates a quantity per unit area. &quot;Layer&quot; 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. Quantities defined for a soil layer must have a vertical coordinate variable with boundaries indicating the extent of the layer(s).</description>
  </entry>
  <entry id="litter_carbon_content">
    <canonical_units>kg m-2</canonical_units>
    <description>&quot;Content&quot; indicates a quantity per unit area. &quot;Litter carbon&quot; is dead inorganic material in or above the soil quantified as the mass of carbon which it contains.</description>
  </entry>
  <entry id="litter_carbon_flux">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;Litter carbon&quot; is dead inorganic material in or above the soil quantified as the mass of carbon which it contains. The litter carbon flux is the rate of production of litter. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="longitude">
    <canonical_units>degree_east</canonical_units>
    <amip>longitude</amip>
    <description>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.</description>
  </entry>
  <entry id="lwe_convective_precipitation_rate">
    <canonical_units>m s-1</canonical_units>
    <description>&quot;lwe&quot; means liquid water equivalent.</description>
  </entry>
  <entry id="lwe_convective_snowfall_rate">
    <canonical_units>m s-1</canonical_units>
    <description>&quot;lwe&quot; means liquid water equivalent.</description>
  </entry>
  <entry id="lwe_large_scale_precipitation_rate">
    <canonical_units>m s-1</canonical_units>
    <description>&quot;lwe&quot; means liquid water equivalent.</description>
  </entry>
  <entry id="lwe_large_scale_snowfall_rate">
    <canonical_units>m s-1</canonical_units>
    <description>&quot;lwe&quot; means liquid water equivalent.</description>
  </entry>
  <entry id="lwe_precipitation_rate">
    <canonical_units>m s-1</canonical_units>
    <description>&quot;lwe&quot; means liquid water equivalent.</description>
  </entry>
  <entry id="lwe_snowfall_rate">
    <canonical_units>m s-1</canonical_units>
    <description>&quot;lwe&quot; means liquid water equivalent.</description>
  </entry>
  <entry id="lwe_thickness_of_atmosphere_water_vapor_content">
    <canonical_units>m</canonical_units>
    <grib>E137</grib>
    <description>&quot;lwe&quot; means liquid water equivalent. 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. &quot;Content&quot; indicates a quantity per unit area. The &quot;atmosphere content&quot; of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. Atmosphere water vapor content is sometimes referred to as &quot;precipitable water&quot;, although this term does not imply the water could all be precipitated.</description>
  </entry>
  <entry id="lwe_thickness_of_canopy_water_amount">
    <canonical_units>m</canonical_units>
    <description>&quot;lwe&quot; means liquid water equivalent. &quot;Amount&quot; 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. &quot;Water&quot; means water in all phases, including frozen i.e. ice and snow. &quot;Canopy&quot; means the plant or vegetation canopy. The canopy water is the water on the canopy.</description>
  </entry>
  <entry id="lwe_thickness_of_convective_precipitation_amount">
    <canonical_units>m</canonical_units>
    <grib>E143</grib>
    <description>&quot;lwe&quot; means liquid water equivalent. &quot;Amount&quot; 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.</description>
  </entry>
  <entry id="lwe_thickness_of_convective_snowfall_amount">
    <canonical_units>m</canonical_units>
    <description>&quot;lwe&quot; means liquid water equivalent. &quot;Amount&quot; 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.</description>
  </entry>
  <entry id="lwe_thickness_of_frozen_water_content_of_soil_layer">
    <canonical_units>m</canonical_units>
    <description>&quot;frozen_water&quot; means ice. &quot;lwe&quot; means liquid water equivalent. 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. &quot;Content&quot; indicates a quantity per unit area. &quot;Layer&quot; 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. Quantities defined for a soil layer must have a vertical coordinate variable with boundaries indicating the extent of the layer(s).</description>
  </entry>
  <entry id="lwe_thickness_of_large_scale_precipitation_amount">
    <canonical_units>m</canonical_units>
    <grib>E142</grib>
    <description>&quot;lwe&quot; means liquid water equivalent. &quot;Amount&quot; 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.</description>
  </entry>
  <entry id="lwe_thickness_of_large_scale_snowfall_amount">
    <canonical_units>m</canonical_units>
    <description>&quot;lwe&quot; means liquid water equivalent. &quot;Amount&quot; 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.</description>
  </entry>
  <entry id="lwe_thickness_of_moisture_content_of_soil_layer">
    <canonical_units>m</canonical_units>
    <description>&quot;lwe&quot; means liquid water equivalent. &quot;moisture&quot; means water in all phases contained in soil. 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. &quot;Content&quot; indicates a quantity per unit area. &quot;Layer&quot; 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. Quantities defined for a soil layer must have a vertical coordinate variable with boundaries indicating the extent of the layer(s).</description>
  </entry>
  <entry id="lwe_thickness_of_precipitation_amount">
    <canonical_units>m</canonical_units>
    <description>&quot;lwe&quot; means liquid water equivalent. &quot;Amount&quot; 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.</description>
  </entry>
  <entry id="lwe_thickness_of_snowfall_amount">
    <canonical_units>m</canonical_units>
    <grib>E144</grib>
    <description>&quot;lwe&quot; means liquid water equivalent. &quot;Amount&quot; 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.</description>
  </entry>
  <entry id="lwe_thickness_of_soil_moisture_content">
    <canonical_units>m</canonical_units>
    <grib>E140</grib>
    <description>&quot;lwe&quot; means liquid water equivalent. &quot;moisture&quot; means water in all phases contained in soil. 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. &quot;Content&quot; indicates a quantity per unit area. The &quot;soil content&quot; 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.</description>
  </entry>
  <entry id="lwe_thickness_of_surface_snow_amount">
    <canonical_units>m</canonical_units>
    <grib>E141</grib>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;lwe&quot; means liquid water equivalent. &quot;Amount&quot; 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.</description>
  </entry>
  <entry id="lwe_thickness_of_water_evaporation_amount">
    <canonical_units>m</canonical_units>
    <grib>E182</grib>
    <description>&quot;lwe&quot; means liquid water equivalent. &quot;Amount&quot; 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. &quot;Water&quot; means water in all phases. Evaporation is the conversion of liquid or solid into vapor. (The conversion of solid alone into vapor is called &quot;sublimation&quot;.)</description>
  </entry>
  <entry id="lwe_water_evaporation_rate">
    <canonical_units>m s-1</canonical_units>
    <description>&quot;lwe&quot; means liquid water equivalent. &quot;Water&quot; means water in all phases. Evaporation is the conversion of liquid or solid into vapor. (The conversion of solid alone into vapor is called &quot;sublimation&quot;.)</description>
  </entry>
  <entry id="magnitude_of_derivative_of_position_wrt_model_level_number">
    <canonical_units>m</canonical_units>
    <description>The quantity with standard name magnitude_of_derivative_of_position_wrt_model_level_number (known in differential geometry as a &quot;scale factor&quot;) is | (dr/dk)ij|, where r(i,j,k) is the vector 3D position of the point with coordinate indices (i,j,k). It is a measure of the gridblock spacing in the z-direction.</description>
  </entry>
  <entry id="magnitude_of_derivative_of_position_wrt_x_coordinate_index">
    <canonical_units>m</canonical_units>
    <description>The quantity with standard name magnitude_of_derivative_of_position_wrt_x_coordinate_index (known in differential geometry as a &quot;scale factor&quot;) is | (dr/di)jk|, where r(i,j,k) is the vector 3D position of the point with coordinate indices (i,j,k). It is a measure of the gridblock spacing in the x-direction.</description>
  </entry>
  <entry id="magnitude_of_derivative_of_position_wrt_y_coordinate_index">
    <canonical_units>m</canonical_units>
    <description>The quantity with standard name magnitude_of_derivative_of_position_wrt_y_coordinate_index (known in differential geometry as a &quot;scale factor&quot;) is | (dr/dj)ik|, where r(i,j,k) is the vector 3D position of the point with coordinate indices (i,j,k). It is a measure of the gridblock spacing in the y-direction.</description>
  </entry>
  <entry id="magnitude_of_surface_downward_stress">
    <canonical_units>Pa</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;magnitude_of_X&quot; means magnitude of a vector X. &quot;Downward&quot; indicates a vector component which is positive when directed downward (negative upward).</description>
  </entry>
  <entry id="mass_concentration_of_condensed_water_in_soil">
    <canonical_units>kg m-3</canonical_units>
    <description>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.  Condensed water means liquid and ice.
</description>
  </entry>
  <entry id="mass_concentration_of_oxygen_in_sea_water">
    <canonical_units>kg m-3</canonical_units>
    <description>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.</description>
  </entry>
  <entry id="mass_concentration_of_sulfate_aerosol_in_air">
    <canonical_units>kg m-3</canonical_units>
    <amip>trsul</amip>
    <description>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. &quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets).</description>
  </entry>
  <entry id="mass_fraction_of_ammonium_dry_aerosol_in_air">
    <canonical_units>1</canonical_units>
    <description>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).  &quot;Mass_fraction_of_ammonium&quot; means that the mass is expressed as mass of NH4.  &quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets).  Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. &quot;Dry aerosol&quot; means aerosol without water.</description>
  </entry>
  <entry id="mass_fraction_of_black_carbon_dry_aerosol_in_air">
    <canonical_units>1</canonical_units>
    <description>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).  &quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets).  Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. &quot;Dry aerosol&quot; means aerosol without water.  Black carbon aerosol is composed of elemental carbon.  It is strongly light absorbing.</description>
  </entry>
  <entry id="mass_fraction_of_cloud_condensed_water_in_air">
    <canonical_units>1</canonical_units>
    <description>&quot;condensed_water&quot; means liquid and ice. 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).</description>
  </entry>
  <entry id="mass_fraction_of_cloud_ice_in_air">
    <canonical_units>1</canonical_units>
    <amip>cli</amip>
    <description>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).</description>
  </entry>
  <entry id="mass_fraction_of_cloud_liquid_water_in_air">
    <canonical_units>1</canonical_units>
    <amip>clw</amip>
    <description>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).</description>
  </entry>
  <entry id="mass_fraction_of_convective_cloud_condensed_water_in_air">
    <canonical_units>1</canonical_units>
    <description>&quot;condensed_water&quot; means liquid and ice. 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).</description>
  </entry>
  <entry id="mass_fraction_of_convective_cloud_ice_in_air">
    <canonical_units>1</canonical_units>
    <description>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). Convective cloud is that produced by the convection schemes in an atmosphere model.</description>
  </entry>
  <entry id="mass_fraction_of_convective_cloud_liquid_water_in_air">
    <canonical_units>1</canonical_units>
    <description>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). Convective cloud is that produced by the convection schemes in an atmosphere model.</description>
  </entry>
  <entry id="mass_fraction_of_dimethyl_sulfide_in_air">
    <canonical_units>1</canonical_units>
    <description>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).</description>
  </entry>
  <entry id="mass_fraction_of_dust_dry_aerosol_in_air">
    <canonical_units>1</canonical_units>
    <description>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).  &quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets).  Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. &quot;Dry aerosol&quot; means aerosol without water.</description>
  </entry>
  <entry id="mass_fraction_of_frozen_water_in_soil_moisture">
    <canonical_units>1</canonical_units>
    <description>&quot;frozen_water&quot; means ice. &quot;moisture&quot; means water in all phases contained in soil. 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).</description>
  </entry>
  <entry id="mass_fraction_of_graupel_in_air">
    <canonical_units>1</canonical_units>
    <description>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).</description>
  </entry>
  <entry id="mass_fraction_of_mercury_dry_aerosol_in_air">
    <canonical_units>1</canonical_units>
    <description>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).  &quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets).  Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. &quot;Dry aerosol&quot; means aerosol without water.</description>
  </entry>
  <entry id="mass_fraction_of_nitrate_dry_aerosol_in_air">
    <canonical_units>1</canonical_units>
    <description>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). &quot;Mass_fraction_of_nitrate&quot; means that the mass is expressed as mass of NO3.  &quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets).  Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. &quot;Dry aerosol&quot; means aerosol without water.</description>
  </entry>
  <entry id="mass_fraction_of_ozone_in_air">
    <canonical_units>1</canonical_units>
    <description>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).</description>
  </entry>
  <entry id="mass_fraction_of_particulate_organic_matter_dry_aerosol_in_air">
    <canonical_units>1</canonical_units>
    <description>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).  &quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets).  Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. &quot;Dry aerosol&quot; means aerosol without water.  &quot;particulate_organic_matter_dry_aerosol&quot; means all particulate organic matter dry aerosol except black carbon.  It is the sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol.</description>
  </entry>
  <entry id="mass_fraction_of_pm10_aerosol_in_air">
    <canonical_units>1</canonical_units>
    <description>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).  &quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets). &quot;Pm10 aerosol&quot; is an air pollutant with an aerodynamic diameter of less than or equal to 10 micrometers.  Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol.  To specify the relative humidity and temperature at which the particle size applies, provide scalar coordinate variables with the standard names of, respectively, &quot;relative_humidity&quot; and &quot;air_temperature&quot;.</description>
  </entry>
  <entry id="mass_fraction_of_pm1_aerosol_in_air">
    <canonical_units>1</canonical_units>
    <description>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). &quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets). &quot;Pm1 aerosol&quot; is an air pollutant with an aerodynamic diameter of less than or equal to 1 micrometer.  Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol.  To specify the relative humidity and temperature at which the particle size applies, provide scalar coordinate variables with the standard names of, respectively, &quot;relative_humidity&quot; and &quot;air_temperature&quot;.</description>
  </entry>
  <entry id="mass_fraction_of_pm2p5_aerosol_in_air">
    <canonical_units>1</canonical_units>
    <description>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).  &quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets). &quot;Pm2p5 aerosol&quot; is an air pollutant with an aerodynamic diameter of less than or equal to 2.5 micrometers.  Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol.  To specify the relative humidity and temperature at which the particle size applies, provide scalar coordinate variables with the standard names of, respectively, &quot;relative_humidity&quot; and &quot;air_temperature&quot;.</description>
  </entry>
  <entry id="mass_fraction_of_precipitation_in_air">
    <canonical_units>1</canonical_units>
    <description>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).</description>
  </entry>
  <entry id="mass_fraction_of_primary_particulate_organic_matter_dry_aerosol_in_air">
    <canonical_units>1</canonical_units>
    <description>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).  &quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets).  Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. &quot;Dry aerosol&quot; means aerosol without water.  &quot;Primary particulate organic matter &quot; means all organic matter emitted directly to the atmosphere as particles except black carbon.  The sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol is particulate_organic_matter_dry_aerosol.</description>
  </entry>
  <entry id="mass_fraction_of_rain_in_air">
    <canonical_units>1</canonical_units>
    <description>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).</description>
  </entry>
  <entry id="mass_fraction_of_seasalt_dry_aerosol_in_air">
    <canonical_units>1</canonical_units>
    <description>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).  &quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets).  Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. &quot;Dry aerosol&quot; means aerosol without water.</description>
  </entry>
  <entry id="mass_fraction_of_secondary_particulate_organic_matter_dry_aerosol_in_air">
    <canonical_units>1</canonical_units>
    <description>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).  &quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets).  Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. &quot;Dry aerosol&quot; means aerosol without water.  &quot;Secondary particulate organic matter &quot; means particulate organic matter formed within the atmosphere from gaseous precursors.  The sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol is particulate_organic_matter_dry_aerosol.</description>
  </entry>
  <entry id="mass_fraction_of_snow_in_air">
    <canonical_units>1</canonical_units>
    <description>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).</description>
  </entry>
  <entry id="mass_fraction_of_stratiform_cloud_ice_in_air">
    <canonical_units>1</canonical_units>
    <description>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). In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes).</description>
  </entry>
  <entry id="mass_fraction_of_stratiform_cloud_liquid_water_in_air">
    <canonical_units>1</canonical_units>
    <description>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). In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes).</description>
  </entry>
  <entry id="mass_fraction_of_sulfate_dry_aerosol_in_air">
    <canonical_units>1</canonical_units>
    <description>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).  &quot;Mass_fraction_of_sulfate&quot; means that the mass is expressed as mass of SO4.  &quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets).  Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. &quot;Dry aerosol&quot; means aerosol without water.</description>
  </entry>
  <entry id="mass_fraction_of_sulfur_dioxide_in_air">
    <canonical_units>1</canonical_units>
    <description>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).</description>
  </entry>
  <entry id="mass_fraction_of_unfrozen_water_in_soil_moisture">
    <canonical_units>1</canonical_units>
    <description>&quot;moisture&quot; means water in all phases contained in soil. &quot;unfrozen_water&quot; means liquid and vapour. 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).</description>
  </entry>
  <entry id="mass_fraction_of_water_in_air">
    <canonical_units>1</canonical_units>
    <description>&quot;Water&quot; means water in all phases. 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).</description>
  </entry>
  <entry id="mass_fraction_of_water_in_ambient_aerosol_in_air">
    <canonical_units>1</canonical_units>
    <description>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).  &quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets).  Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol.</description>
  </entry>
  <entry id="minus_one_times_water_flux_into_sea_water_from_rivers">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>The quantity minus_one_times_water_flux_into_sea_water_from_rivers is the quantity with standard name water_flux_into_sea_water_from_rivers multiplied by -1. &quot;Water&quot; means water in all phases. The water flux or volume transport into sea water from rivers is the inflow to the ocean, often applied to the surface in ocean models. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="model_level_number">
    <canonical_units>1</canonical_units>
    <amip>lev</amip>
    <description>Model level number should be understood as equivalent to layer number.</description>
  </entry>
  <entry id="model_level_number_at_base_of_ocean_mixed_layer_defined_by_sigma_theta">
    <canonical_units> 1 </canonical_units>
    <description>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 or vertical diffusivity is the level at which the quantity indicated differs from its surface value by a certain amount. The amount by which the quantity differs can be specified by a scalar coordinate variable. The quantity model_level_number_at_base_of_ocean_mixed_layer_defined_by_sigma_theta is sometimes referred to as the &quot;bowl index&quot;.</description>
  </entry>
  <entry id="model_level_number_at_convective_cloud_base">
    <canonical_units>1</canonical_units>
    <description>cloud_base refers to the base of the lowest cloud. Model level number should be understood as equivalent to layer number. Convective cloud is that produced by the convection schemes in an atmosphere model.</description>
  </entry>
  <entry id="model_level_number_at_convective_cloud_top">
    <canonical_units>1</canonical_units>
    <description>cloud_top refers to the top of the highest cloud. Model level number should be understood as equivalent to layer number. Convective cloud is that produced by the convection schemes in an atmosphere model.</description>
  </entry>
  <entry id="model_level_number_at_sea_floor">
    <canonical_units> 1 </canonical_units>
    <description>The quantity with standard name model_level_number_at_sea_floor is the depth of the ocean expressed in model levels. This could be a non-integer value because some ocean models use partial cells close to the sea floor.  For example, if this field were 23.4 at some location, it would mean the water column at that point comprised 23 full model levels plus 40% occupancy of the lowest (24th) gridcell.</description>
  </entry>
  <entry id="model_level_number_at_top_of_atmosphere_boundary_layer">
    <canonical_units>1</canonical_units>
    <description>Model level number should be understood as equivalent to layer number.</description>
  </entry>
  <entry id="moisture_content_of_soil_layer">
    <canonical_units>kg m-2</canonical_units>
    <amip>mrsos</amip>
    <description>&quot;moisture&quot; means water in all phases contained in soil. &quot;Content&quot; indicates a quantity per unit area. &quot;Layer&quot; 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. Quantities defined for a soil layer must have a vertical coordinate variable with boundaries indicating the extent of the layer(s).</description>
  </entry>
  <entry id="moisture_content_of_soil_layer_at_field_capacity">
    <canonical_units>kg m-2</canonical_units>
    <amip>mrsofcs</amip>
    <description>&quot;moisture&quot; means water in all phases contained in soil. &quot;Content&quot; indicates a quantity per unit area. &quot;Layer&quot; 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. Quantities defined for a soil layer must have a vertical coordinate variable with boundaries indicating the extent of the layer(s). The field capacity of soil is the maximum content of water it can retain against gravitational drainage.</description>
  </entry>
  <entry id="mole_concentration_of_ammonium_in_sea_water">
    <canonical_units>mol m-3</canonical_units>
    <description>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.</description>
  </entry>
  <entry id="mole_concentration_of_diatoms_in_sea_water_expressed_as_nitrogen">
    <canonical_units>mol m-3</canonical_units>
    <description>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.  The construction expressed_as_nitrogen means that the mole concentration is that of nitrogen atoms due to the diatoms.  Diatoms are single-celled phytoplankton with an external skeleton made of silica. Phytoplankton are autotrophic prokaryotic or eukaryotic algae that live near the water surface where there is sufficient light to support photosynthesis.</description>
  </entry>
  <entry id="mole_concentration_of_mesozooplankton_in_sea_water_expressed_as_nitrogen">
    <canonical_units>mol m-3</canonical_units>
    <description>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.  The construction expressed_as_nitrogen means that the mole concentration is that of nitrogen atoms due to the mesozooplankton.  Mesozooplankton are large protozoans (single-celled organisms) and small metazoans (multi-celled organisms) sized between 2x10-4 m and 2x10-2 m that feed on other plankton and telonemia.</description>
  </entry>
  <entry id="mole_concentration_of_microzooplankton_in_sea_water_expressed_as_nitrogen">
    <canonical_units>mol m-3</canonical_units>
    <description>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.  The construction expressed_as_nitrogen means that the mole concentration is that of nitrogen atoms due to the microzooplankton.  Microzooplankton are protozoans (single-celled organisms) sized between 2x10-5 m and 2x10-4 m that feed on other plankton and telonemia.</description>
  </entry>
  <entry id="mole_concentration_of_nitrate_in_sea_water">
    <canonical_units>mol m-3</canonical_units>
    <description>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.</description>
  </entry>
  <entry id="mole_concentration_of_organic_detritus_in_sea_water_expressed_as_nitrogen">
    <canonical_units>mol m-3</canonical_units>
    <description>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.  The construction expressed_as_nitrogen means that the mole concentration is that of nitrogen atoms due to the organic detritus.  Organic detritus are particles of debris from decaying plants and animals.</description>
  </entry>
  <entry id="mole_concentration_of_organic_detritus_in_sea_water_expressed_as_silicon">
    <canonical_units>mol m-3</canonical_units>
    <description>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.  The construction expressed_as_silicon means that the mole concentration is that of silicon atoms due to the organic detritus.  Organic detritus are particles of debris from decaying plants and animals.</description
>
  </entry>
  <entry id="mole_concentration_of_phytoplankton_in_sea_water_expressed_as_nitrogen">
    <canonical_units>mol m-3</canonical_units>
    <description>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.  The construction expressed_as_nitrogen means that the mole concentration is that of nitrogen atoms due to the phytoplankton.  Phytoplankton are autotrophic prokaryotic or eukaryotic algae that live near the water surface where there is sufficient light to support photosynthesis.</description>
  </entry>
  <entry id="mole_concentration_of_silicate_in_sea_water">
    <canonical_units>mol m-3</canonical_units>
    <description>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.</description>
  </entry>
  <entry id="mole_fraction_of_alpha_hexachlorocyclohexane_in_air">
    <canonical_units>1</canonical_units>
    <description>Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.</description>
  </entry>
  <entry id="mole_fraction_of_atomic_bromine_in_air">
    <canonical_units>1</canonical_units>
    <description>Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.  The chemical symbol of atomic bromine is Br.</description>
  </entry>
  <entry id="mole_fraction_of_atomic_chlorine_in_air">
    <canonical_units>1</canonical_units>
    <description>Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.  The chemical symbol of atomic chlorine is Cl.</description>
  </entry>
  <entry id="mole_fraction_of_atomic_nitrogen_in_air">
    <canonical_units>1</canonical_units>
    <description>Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.  The chemical symbol of atomic nitrogen is N.</description>
  </entry>
  <entry id="mole_fraction_of_benzene_in_air">
    <canonical_units>1</canonical_units>
    <description>Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.</description>
  </entry>
  <entry id="mole_fraction_of_bromine_chloride_in_air">
    <canonical_units>1</canonical_units>
    <description>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 bromine chloride is BrCl.</description>
  </entry>
  <entry id="mole_fraction_of_bromine_monoxide_in_air">
    <canonical_units>1</canonical_units>
    <description>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 bromine monoxide is BrO.</description>
  </entry>
  <entry id="mole_fraction_of_bromine_nitrate_in_air">
    <canonical_units>1</canonical_units>
    <description>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 bromine nitrate is BrONO2.</description>
  </entry>
  <entry id="mole_fraction_of_carbon_dioxide_in_air">
    <canonical_units>1</canonical_units>
    <description>Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.</description>
  </entry>
  <entry id="mole_fraction_of_carbon_monoxide_in_air">
    <canonical_units>1</canonical_units>
    <description>Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.</description>
  </entry>
  <entry id="mole_fraction_of_carbon_tetrachloride_in_air">
    <canonical_units>1</canonical_units>
    <description>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 carbon tetrachloride is CCl4.</description>
  </entry>
  <entry id="mole_fraction_of_cfc11_in_air">
    <canonical_units>1</canonical_units>
    <description>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.</description>
  </entry>
  <entry id="mole_fraction_of_cfc113_in_air">
    <canonical_units>1</canonical_units>
    <description>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.</description>
  </entry>
  <entry id="mole_fraction_of_cfc113a_in_air">
    <canonical_units>1</canonical_units>
    <description>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 CFC113a CCl3CF3.  The IUPAC name for CFC113a is 1,1,1-trichloro-2,2,2-trifluoro-ethane.</description>
  </entry>
  <entry id="mole_fraction_of_cfc114_in_air">
    <canonical_units>1</canonical_units>
    <description>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 CFC114 is CClF2CClF2.  The IUPAC name for CFC114 is 1,2-dichloro-1,1,2,2-tetrafluoro-ethane.</description>
  </entry>
  <entry id="mole_fraction_of_cfc115_in_air">
    <canonical_units>1</canonical_units>
    <description>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 CFC115 is CClF2CF3.  The IUPAC name for CFC115 is 1-chloro-1,1,2,2,2-pentafluoro-ethane.</description>
  </entry>
  <entry id="mole_fraction_of_cfc12_in_air">
    <canonical_units>1</canonical_units>
    <description>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.</description>
  </entry>
  <entry id="mole_fraction_of_chlorine dioxide_in_air">
    <canonical_units>1</canonical_units>
    <description>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 chlorine dioxide is OClO.</description>
  </entry>
  <entry id="mole_fraction_of_chlorine monoxide_in_air">
    <canonical_units>1</canonical_units>
    <description>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 chlorine monoxide is ClO.</description>
  </entry>
  <entry id="mole_fraction_of_chlorine_nitrate_in_air">
    <canonical_units>1</canonical_units>
    <description>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 chlorine nitrate is ClONO2.</description>
  </entry>
  <entry id="mole_fraction_of_dichlorine peroxide_in_air">
    <canonical_units>1</canonical_units>
    <description>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 dichlorine peroxide is Cl2O2.</description>
  </entry>
  <entry id="mole_fraction_of_dimethyl_sulfide_in_air">
    <canonical_units>1</canonical_units>
    <description>Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.</description>
  </entry>
  <entry id="mole_fraction_of_dinitrogen_pentoxide_in_air">
    <canonical_units>1</canonical_units>
    <description>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 dinitrogen pentoxide is N2O5.</description>
  </entry>
  <entry id="mole_fraction_of_ethane_in_air">
    <canonical_units>1</canonical_units>
    <description>Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.</description>
  </entry>
  <entry id="mole_fraction_of_ethene_in_air">
    <canonical_units>1</canonical_units>
    <description>Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.</description>
  </entry>
  <entry id="mole_fraction_of_ethyne_in_air">
    <canonical_units>1</canonical_units>
    <description>Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.</description>
  </entry>
  <entry id="mole_fraction_of_formaldehyde_in_air">
    <canonical_units>1</canonical_units>
    <description>Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.</description>
  </entry>
  <entry id="mole_fraction_of_gaseous_divalent_mercury_in_air">
    <canonical_units>1</canonical_units>
    <description>Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.  &quot;Divalent mercury&quot; means all compounds in which the mercury has two binding sites to other ion(s) in a salt or to other atom(s) in a molecule. </description>
  </entry>
  <entry id="mole_fraction_of_gaseous_elemental_mercury_in_air">
    <canonical_units>1</canonical_units>
    <description>Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.</description>
  </entry>
  <entry id="mole_fraction_of_halon1202_in_air">
    <canonical_units>1</canonical_units>
    <description>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  halon1202  is CBr2F2.  The IUPAC name for halon 1202 is dibromo-difluoro-methane.</description>
  </entry>
  <entry id="mole_fraction_of_halon1211_in_air">
    <canonical_units>1</canonical_units>
    <description>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 halon1211 is CBrClF2.  The IUPAC name for halon 1211 is bromo-chloro-difluoro-methane.</description>
  </entry>
  <entry id="mole_fraction_of_halon1301_in_air">
    <canonical_units>1</canonical_units>
    <description>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 halon1301 is CBrF3.  The IUPAC name for halon 1301 is bromo-trifluoro-methane.</description>
  </entry>
  <entry id="mole_fraction_of_halon2402_in_air">
    <canonical_units>1</canonical_units>
    <description>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 halon2402 is C2Br2F4.  The IUPAC name for halon 2402 is 1,2-dibromo-1,1,2,2-tetrafluoro-ethane.</description>
  </entry>
  <entry id="mole_fraction_of_hexachlorobiphenyl_in_air">
    <canonical_units>1</canonical_units>
    <description>Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.</description>
  </entry>
  <entry id="mole_fraction_of_hydrogen_bromide_in_air">
    <canonical_units>1</canonical_units>
    <description>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 bromide is HBr.</description>
  </entry>
  <entry id="mole_fraction_of_hydrogen_chloride_in_air">
    <canonical_units>1</canonical_units>
    <description>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.</description>
  </entry>
  <entry id="mole_fraction_of_hydrogen_cyanide_in_air">
    <canonical_units>1</canonical_units>
    <description>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 cyanide is HCN.</description>
  </entry>
  <entry id="mole_fraction_of_hydrogen_peroxide_in_air">
    <canonical_units>1</canonical_units>
    <description>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 peroxide is H202.</description>
  </entry>
  <entry id="mole_fraction_of_hydroperoxyl_radical_in_air">
    <canonical_units>1</canonical_units>
    <description>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.</description>
  </entry>
  <entry id="mole_fraction_of_hydroxyl_radical_in_air">
    <canonical_units>1</canonical_units>
    <description>Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.</description>
  </entry>
  <entry id="mole_fraction_of_hypobromous_acid_in_air">
    <canonical_units>1</canonical_units>
    <description>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 hypobromous acid is HOBr.</description>
  </entry>
  <entry id="mole_fraction_of_hypochlorous acid_in_air">
    <canonical_units>1</canonical_units>
    <description>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 hypochlorous acid is HOCl.</description>
  </entry>
  <entry id="mole_fraction_of_inorganic_chlorine_in_air">
    <canonical_units>1</canonical_units>
    <description>Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.  "Inorganic chlorine",sometimes referred to as Cly, describes a family of chemical species which result from the degradation of chlorine-containing source gases (CFCs, HCFCs, VSLS) and natural inorganic chlorine sources such as sea-salt and other aerosols.  mole_fraction_of_inorganic_chlorine is the sum of all species belonging to the family that are represented within a given model.</description>
  </entry>
  <entry id="mole_fraction_of_isoprene_in_air">
    <canonical_units>1</canonical_units>
    <description>Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.</description>
  </entry>
  <entry id="mole_fraction_of_methane_in_air">
    <canonical_units>1</canonical_units>
    <description>Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.</description>
  </entry>
  <entry id="mole_fraction_of_methyl_bromide_in_air">
    <canonical_units>1</canonical_units>
    <description>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 methyl bromide is CH3Br.</description>
  </entry>
  <entry id="mole_fraction_of_methyl_chloride_in_air">
    <canonical_units>1</canonical_units>
    <description>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 methyl chloride is CH3Cl.</description>
  </entry>
  <entry id="mole_fraction_of_methyl_hydroperoxide_in_air">
    <canonical_units>1</canonical_units>
    <description>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 methyl hydroperoxide is CH3OOH.</description>
  </entry>
  <entry id="mole_fraction_of_molecular_hydrogen_in_air">
    <canonical_units>1</canonical_units>
    <description>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 molecular hydrogen is H2.</description>
  </entry>
  <entry id="mole_fraction_of_nitric_acid_in_air">
    <canonical_units>1</canonical_units>
    <description>Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.</description>
  </entry>
  <entry id="mole_fraction_of_nitrogen_dioxide_in_air">
    <canonical_units>1</canonical_units>
    <description>Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.</description>
  </entry>
  <entry id="mole_fraction_of_nitrogen_monoxide_in_air">
    <canonical_units>1</canonical_units>
    <description>Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.</description>
  </entry>
  <entry id="mole_fraction_of_nitrous_oxide_in_air">
    <canonical_units>1</canonical_units>
    <description>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.</description>
  </entry>
  <entry id="mole_fraction_of_ozone_in_air">
    <canonical_units>1</canonical_units>
    <amip>tro3</amip>
    <description>Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.</description>
  </entry>
  <entry id="mole_fraction_of_peroxyacetyl_nitrate_in_air">
    <canonical_units>1</canonical_units>
    <description>Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.</description>
  </entry>
  <entry id="mole_fraction_of_peroxynitric_acid_in_air">
    <canonical_units>1</canonical_units>
    <description>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 peroxynitric acid is HNO4.</description>
  </entry>
  <entry id="mole_fraction_of_propane_in_air">
    <canonical_units>1</canonical_units>
    <description>Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.</description>
  </entry>
  <entry id="mole_fraction_of_propene_in_air">
    <canonical_units>1</canonical_units>
    <description>Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.</description>
  </entry>
  <entry id="mole_fraction_of_sulfur_dioxide_in_air">
    <canonical_units>1</canonical_units>
    <description>Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.</description>
  </entry>
  <entry id="mole_fraction_of_toluene_in_air">
    <canonical_units>1</canonical_units>
    <description>Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.</description>
  </entry>
  <entry id="mole_fraction_of_total_inorganic_bromine_in_air">
    <canonical_units>1</canonical_units>
    <description>Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.  "Inorganic bromine",sometimes referred to as Bry, describes a family of chemical species which result from the degradation of bromine-containing source gases (halons, methyl bromide, VSLS) and natural inorganic bromine sources such as volcanoes, sea-salt and other aerosols.  mole_fraction_of_inorganic_bromine is the sum of all species belonging to the family that are represented within a given model.</description>
  </entry>
  <entry id="mole_fraction_of_total_reactive_nitrogen_in_air">
    <canonical_units>1</canonical_units>
    <description>Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.  "Reactive nitrogen", sometimes referred to as Noy, describes a family of chemical species.  The family usually includes atomic nitrogen (N), nitrogen monoxide (NO), nitrogen dioxide (NO2), dinitrogen pentoxide (N2O5), nitric acid (HNO3), peroxynitric acid (HNO4), bromine nitrate (BrONO2) and chlorine nitrate (ClONO2).</description>
  </entry>
  <entry id="mole_fraction_of_water_vapor_in_air">
    <canonical_units>1</canonical_units>
    <description>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 water vapor is H2O.</description>
  </entry>
  <entry id="mole_fraction_of_xylene_in_air">
    <canonical_units>1</canonical_units>
    <description>Mole fraction is used in the construction mole_fraction_of_X_in_Y, where X is a material constituent of Y.</description>
  </entry>
  <entry id="moles_of_carbon_monoxide_in_atmosphere">
    <canonical_units>mol</canonical_units>
    <description>The construction &quot;moles_of_X_in_atmosphere&quot; means the total number of moles of X contained in the entire atmosphere, i.e, summed over the atmospheric column and over the entire globe.  The chemical formula of carbon monoxide is CO.</description>
  </entry>
  <entry id="moles_of_carbon_tetrachloride_in_atmosphere">
    <canonical_units>mol</canonical_units>
    <description>The construction &quot;moles_of_X_in_atmosphere&quot; means the total number of moles of X contained in the entire atmosphere, i.e, summed over the atmospheric column and over the entire globe.  The chemical formula of carbon tetrachloride is CCl4.</description>
  </entry>
  <entry id="moles_of_cfc11_in_atmosphere">
    <canonical_units>mol</canonical_units>
    <description>The construction &quot;moles_of_X_in_atmosphere&quot; means the total number of moles of X contained in the entire atmosphere, i.e, summed over the atmospheric column and over the entire globe.  The chemical formula of CFC11 is CFCl3.  The IUPAC name for CFC11 is trichloro-fluoro-methane.</description>
  </entry>
  <entry id="moles_of_cfc113_in_atmosphere">
    <canonical_units>mol</canonical_units>
    <description>The construction &quot;moles_of_X_in_atmosphere&quot; means the total number of moles of X contained in the entire atmosphere, i.e, summed over the atmospheric column and over the entire globe.  The chemical formula of CFC113 is CCl2FCClF2.  The IUPAC name for CFC113 is 1,1,2-trichloro-1,2,2-trifluoro-ethane.</description>
  </entry>
  <entry id="moles_of_cfc114_in_atmosphere">
    <canonical_units>mol</canonical_units>
    <description>The construction &quot;moles_of_X_in_atmosphere&quot; means the total number of moles of X contained in the entire atmosphere, i.e, summed over the atmospheric column and over the entire globe.  The chemical formula of CFC114 is CClF2CClF2.  The IUPAC name for CFC114 is 1,2-dichloro-1,1,2,2-tetrafluoro-ethane.</description>
  </entry>
  <entry id="moles_of_cfc115_in_atmosphere">
    <canonical_units>mol</canonical_units>
    <description>The construction &quot;moles_of_X_in_atmosphere&quot; means the total number of moles of X contained in the entire atmosphere, i.e, summed over the atmospheric column and over the entire globe.  The chemical formula of CFC115 is CClF2CF3.  The IUPAC name for CFC115 is 1-chloro-1,1,2,2,2-pentafluoro-ethane.</description>
  </entry>
  <entry id="moles_of_cfc12_in_atmosphere">
    <canonical_units>mol</canonical_units>
    <description>The construction &quot;moles_of_X_in_atmosphere&quot; means the total number of moles of X contained in the entire atmosphere, i.e, summed over the atmospheric column and over the entire globe.  The chemical formula of CFC12 is CF2Cl2.  The IUPAC name for CFC12 is dichloro-difluoro-methane.</description>
  </entry>
  <entry id="moles_of_halon1202_in_atmosphere">
    <canonical_units>mol</canonical_units>
    <description>The construction &quot;moles_of_X_in_atmosphere&quot; means the total number of moles of X contained in the entire atmosphere, i.e, summed over the atmospheric column and over the entire globe.  The chemical formula of halon1202 is CBr2F2.  The IUPAC name for halon 1202 is dibromo-difluoro-methane.</description>
  </entry>
  <entry id="moles_of_halon1211_in_atmosphere">
    <canonical_units>mol</canonical_units>
    <description>The construction &quot;moles_of_X_in_atmosphere&quot; means the total number of moles of X contained in the entire atmosphere, i.e, summed over the atmospheric column and over the entire globe.  The chemical formula of halon1211 is CBrClF2.  The IUPAC name for halon 1211 is bromo-chloro-difluoro-methane.</description>
  </entry>
  <entry id="moles_of_halon1301_in_atmosphere">
    <canonical_units>mol</canonical_units>
    <description>The construction &quot;moles_of_X_in_atmosphere&quot; means the total number of moles of X contained in the entire atmosphere, i.e, summed over the atmospheric column and over the entire globe.  The chemical formula of halon1301 is CBrF3.  The IUPAC name for halon 1301 is bromo-trifluoro-methane.</description>
  </entry>
  <entry id="moles_of_halon2402_in_atmosphere">
    <canonical_units>mol</canonical_units>
    <description>The construction &quot;moles_of_X_in_atmosphere&quot; means the total number of moles of X contained in the entire atmosphere, i.e, summed over the atmospheric column and over the entire globe.  The chemical formula of halon2402 is C2Br2F4.  The IUPAC name for halon 2402 is 1,2-dibromo-1,1,2,2-tetrafluoro-ethane.</description>
  </entry>
  <entry id="moles_of_hcc140a_in_atmosphere">
    <canonical_units>mol</canonical_units>
    <description>The construction &quot;moles_of_X_in_atmosphere&quot; means the total number of moles of X contained in the entire atmosphere, i.e, summed over the atmospheric column and over the entire globe.  The chemical formula of HCC140a is CH3CCl3.  The IUPAC name for HCC 140a is 1,1,1-trichloroethane.</description>
  </entry>
  <entry id="moles_of_hcfc22_in_atmosphere">
    <canonical_units>mol</canonical_units>
    <description>The construction &quot;moles_of_X_in_atmosphere&quot; means the total number of moles of X contained in the entire atmosphere, i.e, summed over the atmospheric column and over the entire globe.  The chemical formula of HCFC22 is CHClF2.  The IUPAC name for HCFC 22 is chloro-difluoro-methane.</description>
  </entry>
  <entry id="moles_of_methane_in_atmosphere">
    <canonical_units>mol</canonical_units>
    <description>The construction &quot;moles_of_X_in_atmosphere&quot; means the total number of moles of X contained in the entire atmosphere, i.e, summed over the atmospheric column and over the entire globe.  The chemical formula of methane is CH4.</description>
  </entry>
  <entry id="moles_of_methyl_bromide_in_atmosphere">
    <canonical_units>mol</canonical_units>
    <description>The construction &quot;moles_of_X_in_atmosphere&quot; means the total number of moles of X contained in the entire atmosphere, i.e, summed over the atmospheric column and over the entire globe.  The chemical formula of methyl bromide is CH3Br.</description>
  </entry>
  <entry id="moles_of_methyl_chloride_in_atmosphere">
    <canonical_units>mol</canonical_units>
    <description>The construction &quot;moles_of_X_in_atmosphere&quot; means the total number of moles of X contained in the entire atmosphere, i.e, summed over the atmospheric column and over the entire globe.  The chemical formula of methyl chloride is CH3Cl.</description>
  </entry>
  <entry id="moles_of_molecular_hydrogen_in_atmosphere">
    <canonical_units>mol</canonical_units>
    <description>The construction &quot;moles_of_X_in_atmosphere&quot; means the total number of moles of X contained in the entire atmosphere, i.e, summed over the atmospheric column and over the entire globe.  The chemical formula of molecular hydrogen is H2.</description>
  </entry>
  <entry id="moles_of_nitrate_and_nitrite_per_unit_mass_in_sea_water">
    <canonical_units>mol kg-1</canonical_units>
    <description>moles_of_X_per_unit_mass_inY is also called &quot;molality&quot; of X in Y, where X is a material constituent of Y.</description>
  </entry>
  <entry id="moles_of_nitrate_per_unit_mass_in_sea_water">
    <canonical_units>mol kg-1</canonical_units>
    <description>moles_of_X_per_unit_mass_inY is also called &quot;molality&quot; of X in Y, where X is a material constituent of Y.</description>
  </entry>
  <entry id="moles_of_nitrite_per_unit_mass_in_sea_water">
    <canonical_units>mol kg-1</canonical_units>
    <description>moles_of_X_per_unit_mass_inY is also called &quot;molality&quot; of X in Y, where X is a material constituent of Y.</description>
  </entry>
  <entry id="moles_of_nitrous_oxide_in_atmosphere">
    <canonical_units>mol</canonical_units>
    <description>The construction &quot;moles_of_X_in_atmosphere&quot; means the total number of moles of X contained in the entire atmosphere, i.e, summed over the atmospheric column and over the entire globe.  The chemical formula of nitrous oxide is N2O.</description>
  </entry>
  <entry id="moles_of_oxygen_per_unit_mass_in_sea_water">
    <canonical_units>mol kg-1</canonical_units>
    <description>moles_of_X_per_unit_mass_inY is also called &quot;molality&quot; of X in Y, where X is a material constituent of Y.</description>
  </entry>
  <entry id="moles_of_phosphate_per_unit_mass_in_sea_water">
    <canonical_units>mol kg-1</canonical_units>
    <description>moles_of_X_per_unit_mass_inY is also called &quot;molality&quot; of X in Y, where X is a material constituent of Y.</description>
  </entry>
  <entry id="moles_of_silicate_per_unit_mass_in_sea_water">
    <canonical_units>mol kg-1</canonical_units>
    <description>moles_of_X_per_unit_mass_inY is also called &quot;molality&quot; of X in Y, where X is a material constituent of Y.</description>
  </entry>
  <entry id="net_downward_longwave_flux_in_air">
    <canonical_units>W m-2</canonical_units>
    <description>&quot;longwave&quot; means longwave radiation. &quot;Downward&quot; indicates a vector component which is positive when directed downward (negative upward). Net downward radiation is the difference between radiation from above (downwelling) and radiation from below (upwelling). In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="net_downward_longwave_flux_in_air_assuming_clear_sky">
    <canonical_units>W m-2</canonical_units>
    <description>A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. &quot;longwave&quot; means longwave radiation. &quot;Downward&quot; indicates a vector component which is positive when directed downward (negative upward). Net downward radiation is the difference between radiation from above (downwelling) and radiation from below (upwelling). In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="net_downward_radiative_flux_at_top_of_atmosphere_model">
    <canonical_units>W m-2</canonical_units>
    <amip>rtmt</amip>
    <description>Fluxes at the top_of_atmosphere_model differ from TOA fluxes only if the model TOA fluxes make some allowance for the atmosphere above the top of the model; if not, it is usual to give standard names with toa to the fluxes at the top of the model atmosphere. &quot;Downward&quot; indicates a vector component which is positive when directed downward (negative upward). Net downward radiation is the difference between radiation from above (downwelling) and radiation from below (upwelling). Radiative flux is the sum of shortwave and longwave radiative fluxes. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="net_downward_shortwave_flux_in_air">
    <canonical_units>W m-2</canonical_units>
    <description>&quot;shortwave&quot; means shortwave radiation. &quot;Downward&quot; indicates a vector component which is positive when directed downward (negative upward). Net downward radiation is the difference between radiation from above (downwelling) and radiation from below (upwelling). In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="net_downward_shortwave_flux_in_air_assuming_clear_sky">
    <canonical_units>W m-2</canonical_units>
    <amip>rsntpcs</amip>
    <description>A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. &quot;shortwave&quot; means shortwave radiation. &quot;Downward&quot; indicates a vector component which is positive when directed downward (negative upward). Net downward radiation is the difference between radiation from above (downwelling) and radiation from below (upwelling). In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="net_primary_productivity_of_carbon">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>Net primary productivity is the excess of gross_primary_producivity (rate of synthesis of biomass per unit area from inorganic precursors by autotrophs, or &quot;producers&quot;, especially by photosynthesising plants using sunlight for energy) over the rate at which they themselves respire some of this biomass (plant_respiration, assuming all producers to be plants). &quot;Productivity of carbon&quot; refers to the production of biomass expressed as the mass of carbon which it contains.</description>
  </entry>
  <entry id="net_rate_of_absorption_of_longwave_energy_in_atmosphere_layer">
    <canonical_units>W m-2</canonical_units>
    <description>&quot;longwave&quot; means longwave radiation. &quot;Layer&quot; 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.</description>
  </entry>
  <entry id="net_rate_of_absorption_of_shortwave_energy_in_atmosphere_layer">
    <canonical_units>W m-2</canonical_units>
    <description>&quot;shortwave&quot; means shortwave radiation. &quot;Layer&quot; 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.</description>
  </entry>
  <entry id="net_upward_longwave_flux_in_air">
    <canonical_units>W m-2</canonical_units>
    <grib>115</grib>
    <description>&quot;longwave&quot; means longwave radiation. &quot;Upward&quot; indicates a vector component which is positive when directed upward (negative downward). Net upward radiation is the difference between radiation from below (upwelling) and radiation from above (downwelling). In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="net_upward_longwave_flux_in_air_assuming_clear_sky">
    <canonical_units>W m-2</canonical_units>
    <amip>rlntpcs</amip>
    <description>A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. &quot;longwave&quot; means longwave radiation. &quot;Upward&quot; indicates a vector component which is positive when directed upward (negative downward). Net upward radiation is the difference between radiation from below (upwelling) and radiation from above (downwelling). In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="net_upward_shortwave_flux_in_air">
    <canonical_units>W m-2</canonical_units>
    <grib>116</grib>
    <description>&quot;shortwave&quot; means shortwave radiation. &quot;Upward&quot; indicates a vector component which is positive when directed upward (negative downward). Net upward radiation is the difference between radiation from below (upwelling) and radiation from above (downwelling). In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="net_upward_shortwave_flux_in_air_assuming_clear_sky">
    <canonical_units>W m-2</canonical_units>
    <description>A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. &quot;shortwave&quot; means shortwave radiation. &quot;Upward&quot; indicates a vector component which is positive when directed upward (negative downward). Net upward radiation is the difference between radiation from below (upwelling) and radiation from above (downwelling). In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="normalized_difference_vegetation_index">
    <canonical_units>1</canonical_units>
    <description>&quot;Normalized_difference_vegetation_index&quot;, usually abbreviated to NDVI, is an index calculated from reflectances measured in the visible and near infrared channels.  It is calculated as NDVI = (NIR - R) / (NIR + R) where NIR is the reflectance in the near-infrared band and R is the reflectance in the red visible band.  Reflectance is the ratio of the reflected over the incoming radiation in each spectral band.  The calculated value of NDVI depends on the precise definitions of the spectral bands and these definitions may vary between different models and remote sensing instruments.</description>
  </entry>
  <entry id="northward_atmosphere_dry_static_energy_transport_across_unit_distance">
    <canonical_units>W m-1</canonical_units>
    <description>&quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). Transport across_unit_distance means expressed per unit distance normal to the direction of transport. Dry static energy is the sum of enthalpy and potential energy (itself the sum of gravitational and centripetal potential energy). Enthalpy can be written either as (1) CpT, where Cp is heat capacity at constant pressure, T is absolute temperature, or (2) U+pV, where U is internal energy, p is pressure and V is volume.</description>
  </entry>
  <entry id="northward_atmosphere_heat_transport">
    <canonical_units>W</canonical_units>
    <description>&quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). &quot;Atmosphere heat transport&quot; means total heat transport by the atmosphere by all processes.</description>
  </entry>
  <entry id="northward_atmosphere_water_transport_across_unit_distance">
    <canonical_units>kg s-1 m-1</canonical_units>
    <description>&quot;Water&quot; means water in all phases. &quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). Transport across_unit_distance means expressed per unit distance normal to the direction of transport.</description>
  </entry>
  <entry id="northward_atmosphere_water_vapor_transport_across_unit_distance">
    <canonical_units>kg m-1 s-1</canonical_units>
    <description>&quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). Transport across_unit_distance means expressed per unit distance normal to the direction of transport.</description>
  </entry>
  <entry id="northward_eliassen_palm_flux_in_air">
    <canonical_units>m3 s-2</canonical_units>
    <description>&quot;Eliassen Palm flux&quot; is a widely used vector in the meridional plane, and the divergence of this flux appears as a forcing in the Transformed Eulerian mean formulation of the zonal mean zonal wind equation.  &quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward).</description>
  </entry>
  <entry id="northward_heat_flux_in_air_due_to_eddy_advection">
    <canonical_units>W m-2</canonical_units>
    <description>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. &quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward).  In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="northward_mass_flux_of_air">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="northward_momentum_flux_correction">
    <canonical_units>Pa</canonical_units>
    <amip>tauvcorr</amip>
    <description>&quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). Momentum flux is dimensionally equivalent to stress and pressure. It is a tensor quantity. Flux correction is also called &quot;flux adjustment&quot;. A positive flux correction is downward i.e. added to the ocean. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="northward_ocean_freshwater_transport">
    <canonical_units>kg s-1</canonical_units>
    <description>&quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). Ocean transport means transport by all processes, both sea water and sea ice.</description>
  </entry>
  <entry id="northward_ocean_freshwater_transport_due_to_bolus_advection">
    <canonical_units>kg s-1</canonical_units>
    <description>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. &quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). Northward transport by bolus advection in an ocean model means the part due to a scheme representing eddy-induced effects not included in the velocity field.</description>
  </entry>
  <entry id="northward_ocean_freshwater_transport_due_to_diffusion">
    <canonical_units>kg s-1</canonical_units>
    <description>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. &quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). Northward transport by diffusion means the part due to horizontal or isopyncal diffusion schemes in an ocean model, but not including the &quot;bolus&quot; or Gent-McWilliams velocity.</description>
  </entry>
  <entry id="northward_ocean_freshwater_transport_due_to_gyre">
    <canonical_units>kg s-1</canonical_units>
    <description>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. &quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). Northward transport by the ocean gyre is geometrically defined as being the part due to the vertical integral of the product of deviations of velocity and tracer from their zonal means. The velocity does not include &quot;bolus&quot; or Gent-McWilliams velocity.</description>
  </entry>
  <entry id="northward_ocean_freshwater_transport_due_to_overturning">
    <canonical_units>kg s-1</canonical_units>
    <description>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. &quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). Northward transport by (meridional) overturning is geometrically defined as being the part due to the vertical integral of the product of zonal means of velocity and tracer. The velocity does not include &quot;bolus&quot; or Gent-McWilliams velocity.</description>
  </entry>
  <entry id="northward_ocean_heat_transport">
    <canonical_units>W</canonical_units>
    <description>&quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). Ocean transport means transport by all processes, both sea water and sea ice.</description>
  </entry>
  <entry id="northward_ocean_heat_transport_due_to_bolus_advection">
    <canonical_units>W</canonical_units>
    <description>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. &quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). Northward transport by bolus advection in an ocean model means the part due to a scheme representing eddy-induced effects not included in the velocity field.</description>
  </entry>
  <entry id="northward_ocean_heat_transport_due_to_diffusion">
    <canonical_units>W</canonical_units>
    <amip>htovdiff</amip>
    <description>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. &quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). Northward transport by diffusion means the part due to horizontal or isopyncal diffusion schemes in an ocean model, but not including the &quot;bolus&quot; or Gent-McWilliams velocity.</description>
  </entry>
  <entry id="northward_ocean_heat_transport_due_to_gyre">
    <canonical_units>W</canonical_units>
    <amip>htovgyre</amip>
    <description>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. &quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). Northward transport by the ocean gyre is geometrically defined as being the part due to the vertical integral of the product of deviations of velocity and tracer from their zonal means. The velocity does not include &quot;bolus&quot; or Gent-McWilliams velocity.</description>
  </entry>
  <entry id="northward_ocean_heat_transport_due_to_overturning">
    <canonical_units>W</canonical_units>
    <amip>htovovrt</amip>
    <description>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. &quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). Northward transport by (meridional) overturning is geometrically defined as being the part due to the vertical integral of the product of zonal means of velocity and tracer. The velocity does not include &quot;bolus&quot; or Gent-McWilliams velocity.</description>
  </entry>
  <entry id="northward_ocean_salt_transport">
    <canonical_units>kg s-1</canonical_units>
    <description>&quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). Ocean transport means transport by all processes, both sea water and sea ice.</description>
  </entry>
  <entry id="northward_ocean_salt_transport_due_to_bolus_advection">
    <canonical_units>kg s-1</canonical_units>
    <description>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. &quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). Northward transport by bolus advection in an ocean model means the part due to a scheme representing eddy-induced effects not included in the velocity field.</description>
  </entry>
  <entry id="northward_ocean_salt_transport_due_to_diffusion">
    <canonical_units>kg s-1</canonical_units>
    <amip>sltovdiff</amip>
    <description>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. &quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). Northward transport by diffusion means the part due to horizontal or isopyncal diffusion schemes in an ocean model, but not including the &quot;bolus&quot; or Gent-McWilliams velocity.</description>
  </entry>
  <entry id="northward_ocean_salt_transport_due_to_gyre">
    <canonical_units>kg s-1</canonical_units>
    <amip>sltovgyre</amip>
    <description>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. &quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). Northward transport by the ocean gyre is geometrically defined as being the part due to the vertical integral of the product of deviations of velocity and tracer from their zonal means. The velocity does not include &quot;bolus&quot; or Gent-McWilliams velocity.</description>
  </entry>
  <entry id="northward_ocean_salt_transport_due_to_overturning">
    <canonical_units>kg s-1</canonical_units>
    <amip>sltovovrt</amip>
    <description>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. &quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). Northward transport by (meridional) overturning is geometrically defined as being the part due to the vertical integral of the product of zonal means of velocity and tracer. The velocity does not include &quot;bolus&quot; or Gent-McWilliams velocity.</description>
  </entry>
  <entry id="northward_sea_ice_velocity">
    <canonical_units>m s-1</canonical_units>
    <grib>96</grib>
    <description>A velocity is a vector quantity. &quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). Sea ice velocity is defined as a two-dimensional vector, with no vertical component.</description>
  </entry>
  <entry id="northward_sea_water_velocity">
    <canonical_units>m s-1</canonical_units>
    <grib>50</grib>
    <description>A velocity is a vector quantity. &quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward).</description>
  </entry>
  <entry id="northward_transformed_eulerian_mean_air_velocity">
    <canonical_units>m s-1</canonical_units>
    <description>&quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward).</description>
  </entry>
  <entry id="northward_water_vapor_flux">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="northward_water_vapor_transport_across_unit_distance_in_atmosphere_layer">
    <canonical_units>kg m-1 s-1</canonical_units>
    <description>&quot;Layer&quot; 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. &quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). Transport across_unit_distance means expressed per unit distance normal to the direction of transport.</description>
  </entry>
  <entry id="northward_wind">
    <canonical_units>m s-1</canonical_units>
    <grib>34 E132</grib>
    <amip>va</amip>
    <description>&quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)</description>
  </entry>
  <entry id="northward_wind_shear">
    <canonical_units>s-1</canonical_units>
    <grib>46</grib>
    <description>&quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.) Wind shear is the derivative of wind with respect to height.</description>
  </entry>
  <entry id="ocean_barotropic_streamfunction">
    <canonical_units>m3 s-1</canonical_units>
    <amip>stfbaro</amip>
    <description></description>
  </entry>
  <entry id="ocean_integral_of_sea_water_temperature_wrt_depth">
    <canonical_units>K m</canonical_units>
    <description>&quot;integral_of_Y_wrt_X&quot; means int Y dX. The data variable should have an axis for X specifying the limits of the integral as bounds. &quot;wrt&quot; means with respect to. Depth is the vertical distance below the surface.</description>
  </entry>
  <entry id="ocean_isopycnal_layer_thickness_diffusivity">
    <canonical_units>m2 s-1</canonical_units>
    <description></description>
  </entry>
  <entry id="ocean_meridional_overturning_streamfunction">
    <canonical_units>m3 s-1</canonical_units>
    <amip>stfmmcgo</amip>
    <description>The ocean meridional overturning streamfunction should not include not include &quot;bolus&quot; or Gent-McWilliams velocity.</description>
  </entry>
  <entry id="ocean_mixed_layer_thickness">
    <canonical_units>m</canonical_units>
    <grib>67</grib>
    <description>The ocean mixed layer is the upper part of the ocean, regarded as being well-mixed. Various criteria are used to define the mixed layer; this can be specified by using a standard name of ocean_mixed_layer_defined_byX.</description>
  </entry>
  <entry id="ocean_mixed_layer_thickness_defined_by_mixing_scheme">
    <canonical_units>m</canonical_units>
    <description>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.</description>
  </entry>
  <entry id="ocean_mixed_layer_thickness_defined_by_sigma_t">
    <canonical_units>m</canonical_units>
    <description>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 or sigma_theta is the level at which the quantity indicated differs from its surface value by a certain amount.</description>
  </entry>
  <entry id="ocean_mixed_layer_thickness_defined_by_sigma_theta">
    <canonical_units>m</canonical_units>
    <description>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 or sigma_theta is the level at which the quantity indicated differs from its surface value by a certain amount.</description>
  </entry>
  <entry id="ocean_mixed_layer_thickness_defined_by_temperature">
    <canonical_units>m</canonical_units>
    <description>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 or sigma_theta is the level at which the quantity indicated differs from its surface value by a certain amount.</description>
  </entry>
  <entry id="ocean_mixed_layer_thickness_defined_by_vertical_tracer_diffusivity">
    <canonical_units>m</canonical_units>
    <description>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, or vertical diffusivity is the level at which the quantity indicated differs from its surface value by a certain amount. The amount by which the quantity differs can be specified by a scalar coordinate variable.</description>
  </entry>
  <entry id="ocean_rigid_lid_pressure">
    <canonical_units>N m-2</canonical_units>
    <description>&quot;Ocean rigid lid pressure&quot; means the pressure at the surface of an ocean model assuming that it is bounded above by a rigid lid.</description>
  </entry>
  <entry id="ocean_rigid_lid_pressure_expressed_as_sea_surface_height_above_geoid">
    <canonical_units>m</canonical_units>
    <description>&quot;Ocean rigid lid pressure&quot; means the pressure at the surface of an ocean model assuming that it is bounded above by a rigid lid.</description>
  </entry>
  <entry id="ocean_s_coordinate">
    <canonical_units>1</canonical_units>
    <description>See Appendix D of the CF convention for information about dimensionless vertical coordinates.</description>
  </entry>
  <entry id="ocean_sigma_coordinate">
    <canonical_units>1</canonical_units>
    <description>See Appendix D of the CF convention for information about dimensionless vertical coordinates. Note that the ocean sigma coordinate is not the same quantity as sea water sigma (excess of density over 1000 kg m-3), for which there are various other standard names.</description>
  </entry>
  <entry id="ocean_vertical_diffusivity">
    <canonical_units>m2 s-1</canonical_units>
    <description>&quot;Vertical diffusivity&quot; means the vertical component of diffusivity due to motion which is not resolved on the grid scale of the model.</description>
  </entry>
  <entry id="ocean_vertical_heat_diffusivity">
    <canonical_units>m2 s-1</canonical_units>
    <description>&quot;Vertical heat diffusivity&quot; means the vertical component of the diffusivity of heat due to motion which is not resolved on the grid scale of the model.</description>
  </entry>
  <entry id="ocean_vertical_momentum_diffusivity">
    <canonical_units>m2 s-1</canonical_units>
    <description>&quot;Vertical momentum diffusivity&quot; means the vertical component of the diffusivity of momentum due to motion which is not resolved on the grid scale of the model. </description>
  </entry>
  <entry id="ocean_vertical_momentum_diffusivity_due_to_convection">
    <canonical_units>m2 s-1</canonical_units>
    <description>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. &quot;Vertical momentum diffusivity&quot; means the vertical component of the diffusivity of momentum due to motion which is not resolved on the grid scale of the model. Convective mixing in the ocean is somtimes modelled as an enhanced diffusivity.</description>
  </entry>
  <entry id="ocean_vertical_salt_diffusivity">
    <canonical_units>m2 s-1</canonical_units>
    <description>&quot;Vertical salt diffusivity&quot; means the vertical component of the diffusivity of salt due to motion which is not resolved on the grid scale of the model.</description>
  </entry>
  <entry id="ocean_vertical_tracer_diffusivity">
    <canonical_units>m2 s-1</canonical_units>
    <description>&quot;Vertical tracer diffusivity&quot; means the vertical component of the diffusivity of tracers, i.e. heat and salinity, due to motion which is not resolved on the grid scale of the model.</description>
  </entry>
  <entry id="ocean_vertical_tracer_diffusivity_due_to_convection">
    <canonical_units>m2 s-1</canonical_units>
    <description>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. &quot;Vertical tracer diffusivity&quot; means the vertical component of the diffusivity of tracers, i.e. heat and salinity, due to motion which is not resolved on the grid scale of the model.  Convective mixing in the ocean is sometimes modelled as an enhanced diffusivity.</description>
  </entry>
  <entry id="ocean_vertical_tracer_diffusivity_due_to_wind_mixing">
    <canonical_units>m2 s-1</canonical_units>
    <description>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. &quot;Vertical tracer diffusivity&quot; means the vertical component of the diffusivity of tracers, i.e. heat and salinity, due to motion which is not resolved on the grid scale of the model.</description>
  </entry>
  <entry id="ocean_volume">
    <canonical_units>m3</canonical_units>
    <description></description>
  </entry>
  <entry id="ocean_volume_fraction">
    <canonical_units>1</canonical_units>
    <description>&quot;X_volume_fraction&quot; means the fraction of volume occupied by X.</description>
  </entry>
  <entry id="omnidirectional_photosynthetic_spherical_irradiance_in_sea_water">
    <canonical_units>W m-2 </canonical_units>
    <description>&quot;Photosynthetic&quot; radiation is the part of the spectrum which is used in photosynthesis e.g. 300-700 nm. The range of wavelengths could be specified precisely by the bounds of a coordinate of radiation_wavelength. Omnidirectional spherical irradiance is the radiation incident on unit area of a spherical (or &quot;4-pi&quot;) collector. It is sometimes called &quot;scalar irradiance&quot;. Radiation incident on a 2-pi collector has standard names of &quot;spherical irradiance&quot; which specify up/downwelling.</description>
  </entry>
  <entry id="omnidirectional_spectral_spherical_irradiance_in_sea_water">
    <canonical_units>W m-3</canonical_units>
    <description>&quot;spectral&quot; means per unit wavelength or as a function of wavelength; spectral quantities are sometimes called &quot;monochromatic&quot;. Radiation wavelength has standard name radiation_wavelength. Omnidirectional spherical irradiance is the radiation incident on unit area of a spherical (or &quot;4-pi&quot;) collector. It is sometimes called &quot;scalar irradiance&quot;. Radiation incident on a 2-pi collector has standard names of &quot;spherical irradiance&quot; which specify up/downwelling.</description>
  </entry>
  <entry id="optical_thickness_of_atmosphere_layer_due_to_aerosol">
    <canonical_units>1</canonical_units>
    <description>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. &quot;Layer&quot; 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. 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. &quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets).</description>
  </entry>
  <entry id="planetary_albedo">
    <canonical_units>1</canonical_units>
    <description></description>
  </entry>
  <entry id="plant_respiration_carbon_flux">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;Respiration carbon&quot; refers to the rate at which biomass is respired expressed as the mass of carbon which it contains. Plant respiration is the sum of respiration by parts of plants both above and below the soil. Plants which photosynthesise are autotrophs i.e. &quot;producers&quot; of the biomass which they respire from inorganic precursors using sunlight for energy. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="platform_course">
    <canonical_units>degree</canonical_units>
    <description>Standard names for platform describe the motion and orientation of the vehicle from which observations are made e.g. aeroplane or ship. The platform course is the direction in which the platform is travelling (not necessarily the same as the direction in which it is pointing, called platform_orientation).</description>
  </entry>
  <entry id="platform_orientation">
    <canonical_units>degree</canonical_units>
    <description>Standard names for platform describe the motion and orientation of the vehicle from which observations are made e.g. aeroplane or ship. The platform orientation is the direction in which the &quot;front&quot; or longitudinal axis of the platform is pointing (not necessarily the same as the direction in which it is travelling, called platform_course).</description>
  </entry>
  <entry id="platform_pitch_angle">
    <canonical_units>degree</canonical_units>
    <description>Standard names for platform describe the motion and orientation of the vehicle from which observations are made e.g. aeroplane or ship.</description>
  </entry>
  <entry id="platform_pitch_rate">
    <canonical_units>degree s-1</canonical_units>
    <description>Standard names for platform describe the motion and orientation of the vehicle from which observations are made e.g. aeroplane or ship.</description>
  </entry>
  <entry id="platform_roll_angle">
    <canonical_units>degree</canonical_units>
    <description>Standard names for platform describe the motion and orientation of the vehicle from which observations are made e.g. aeroplane or ship.</description>
  </entry>
  <entry id="platform_roll_rate">
    <canonical_units>degree s-1</canonical_units>
    <description>Standard names for platform describe the motion and orientation of the vehicle from which observations are made e.g. aeroplane or ship.</description>
  </entry>
  <entry id="platform_speed_wrt_air">
    <canonical_units>m s-1</canonical_units>
    <description>&quot;wrt&quot; means with respect to. Speed is the magnitude of velocity. Standard names for platform describe the motion and orientation of the vehicle from which observations are made e.g. aeroplane or ship. The platform speed with respect to air is often called the &quot;air speed&quot; of the platform.</description>
  </entry>
  <entry id="platform_speed_wrt_ground">
    <canonical_units>m s-1</canonical_units>
    <description>&quot;wrt&quot; means with respect to. Speed is the magnitude of velocity. Standard names for platform describe the motion and orientation of the vehicle from which observations are made e.g. aeroplane or ship. The platform speed with respect to ground is relative to the solid Earth beneath it i.e. the sea floor for a ship. It is often called the &quot;ground speed&quot; of the platform.</description>
  </entry>
  <entry id="platform_speed_wrt_sea_water">
    <canonical_units>m s-1</canonical_units>
    <description>&quot;wrt&quot; means with respect to. Speed is the magnitude of velocity. Standard names for platform describe the motion and orientation of the vehicle from which observations are made e.g. aeroplane or ship.</description>
  </entry>
  <entry id="platform_yaw_angle">
    <canonical_units>degree</canonical_units>
    <description>Standard names for platform describe the motion and orientation of the vehicle from which observations are made e.g. aeroplane or ship.</description>
  </entry>
  <entry id="platform_yaw_rate">
    <canonical_units>degree s-1</canonical_units>
    <description>Standard names for platform describe the motion and orientation of the vehicle from which observations are made e.g. aeroplane or ship.</description>
  </entry>
  <entry id="potential_energy_content_of_atmosphere_layer">
    <canonical_units>J m-2</canonical_units>
    <description>&quot;Content&quot; indicates a quantity per unit area. &quot;Layer&quot; 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. 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.)</description>
  </entry>
  <entry id="potential_vorticity_of_atmosphere_layer">
    <canonical_units>Pa-1 s-1</canonical_units>
    <description>&quot;Layer&quot; 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. Atmosphere potential vorticity is the vertically averaged absolute vorticity of a layer of the atmosphere divided by the pressure difference from the bottom to the top of the layer.</description>
  </entry>
  <entry id="potential_vorticity_of_ocean_layer">
    <canonical_units>m-1 s-1</canonical_units>
    <description>&quot;Layer&quot; 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. Ocean potential vorticity is the vertically averaged absolute vorticity of a layer of the ocean divided by the thickness of the layer.</description>
  </entry>
  <entry id="precipitation_amount">
    <canonical_units>kg m-2</canonical_units>
    <grib>61</grib>
    <description>&quot;Amount&quot; means mass per unit area.</description>
  </entry>
  <entry id="precipitation_flux">
    <canonical_units>kg m-2 s-1</canonical_units>
    <grib>59</grib>
    <amip>pr</amip>
    <description>In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="precipitation_flux_onto_canopy_where_land">
    <canonical_units>kg m-2 s-1</canonical_units>
    <amip>prveg</amip>
    <description>Unless indicated, a quantity is assumed to apply to the whole area of each horizontal grid box. The qualifier where_type specifies instead that the quantity applies only to the part of the grid box of the named type. &quot;Canopy&quot; means the plant or vegetation canopy. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="product_of_air_temperature_and_omega">
    <canonical_units>K Pa s-1</canonical_units>
    <description>&quot;product_of_X_and_Y&quot; means X*Y. Air temperature is the bulk temperature of the air, not the surface (skin) temperature. &quot;omegaX&quot; is used for brevity to mean &quot;lagrangian_tendency_of_air_pressure in standard names constructed as a combination of omega with some other quantity.</description>
  </entry>
  <entry id="product_of_air_temperature_and_specific_humidity">
    <canonical_units>K</canonical_units>
    <description>&quot;product_of_X_and_Y&quot; means X*Y. &quot;specific&quot; means per unit mass. Air temperature is the bulk temperature of the air, not the surface (skin) temperature. Specific humidity is the mass fraction of water vapor in (moist) air.</description>
  </entry>
  <entry id="product_of_eastward_sea_water_velocity_and_salinity">
    <canonical_units>m s-1</canonical_units>
    <description>&quot;product_of_X_and_Y&quot; means X*Y. A velocity is a vector quantity. &quot;Eastward&quot; indicates a vector component which is positive when directed eastward (negative westward). The unit of salinity is PSU, which is dimensionless. The units attribute should be given as 1e-3 or 0.001 i.e. parts per thousand if salinity is in PSU.</description>
  </entry>
  <entry id="product_of_eastward_sea_water_velocity_and_temperature">
    <canonical_units>K m s-1</canonical_units>
    <description>&quot;product_of_X_and_Y&quot; means X*Y. A velocity is a vector quantity. &quot;Eastward&quot; indicates a vector component which is positive when directed eastward (negative westward).</description>
  </entry>
  <entry id="product_of_eastward_wind_and_air_temperature">
    <canonical_units>K m s-1</canonical_units>
    <description>&quot;product_of_X_and_Y&quot; means X*Y. Air temperature is the bulk temperature of the air, not the surface (skin) temperature. &quot;Eastward&quot; indicates a vector component which is positive when directed eastward (negative westward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)</description>
  </entry>
  <entry id="product_of_eastward_wind_and_geopotential_height">
    <canonical_units>m2 s-1</canonical_units>
    <amip>mpuzga</amip>
    <description>&quot;product_of_X_and_Y&quot; means X*Y. 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. &quot;Eastward&quot; indicates a vector component which is positive when directed eastward (negative westward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)</description>
  </entry>
  <entry id="product_of_eastward_wind_and_northward_wind">
    <canonical_units>m2 s-2</canonical_units>
    <amip>mpuva</amip>
    <description>&quot;product_of_X_and_Y&quot; means X*Y. &quot;Eastward&quot; indicates a vector component which is positive when directed eastward (negative westward). &quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)</description>
  </entry>
  <entry id="product_of_eastward_wind_and_omega">
    <canonical_units>Pa m s-2</canonical_units>
    <description>&quot;product_of_X_and_Y&quot; means X*Y. &quot;Eastward&quot; indicates a vector component which is positive when directed eastward (negative westward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.) &quot;omegaX&quot; is used for brevity to mean &quot;lagrangian_tendency_of_air_pressure in standard names constructed as a combination of omega with some other quantity.</description>
  </entry>
  <entry id="product_of_eastward_wind_and_specific_humidity">
    <canonical_units>m s-1</canonical_units>
    <description>&quot;product_of_X_and_Y&quot; means X*Y. &quot;specific&quot; means per unit mass. &quot;Eastward&quot; indicates a vector component which is positive when directed eastward (negative westward). Specific humidity is the mass fraction of water vapor in (moist) air. Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)</description>
  </entry>
  <entry id="product_of_eastward_wind_and_upward_air_velocity">
    <canonical_units>m2 s-2</canonical_units>
    <description>&quot;product_of_X_and_Y&quot; means X*Y. A velocity is a vector quantity. &quot;Eastward&quot; indicates a vector component which is positive when directed eastward (negative westward). &quot;Upward&quot; indicates a vector component which is positive when directed upward (negative downward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.) Upward air velocity is the vertical component of the 3D air velocity vector.</description>
  </entry>
  <entry id="product_of_geopotential_height_and_omega">
    <canonical_units>Pa m s-1</canonical_units>
    <description>&quot;product_of_X_and_Y&quot; means X*Y. 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. &quot;omegaX&quot; is used for brevity to mean &quot;lagrangian_tendency_of_air_pressure in standard names constructed as a combination of omega with some other quantity.</description>
  </entry>
  <entry id="product_of_northward_sea_water_velocity_and_salinity">
    <canonical_units>m s-1</canonical_units>
    <description>&quot;product_of_X_and_Y&quot; means X*Y. A velocity is a vector quantity. &quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). The unit of salinity is PSU, which is dimensionless. The units attribute should be given as 1e-3 or 0.001 i.e. parts per thousand if salinity is in PSU.</description>
  </entry>
  <entry id="product_of_northward_sea_water_velocity_and_temperature">
    <canonical_units>K m s-1</canonical_units>
    <description>&quot;product_of_X_and_Y&quot; means X*Y. A velocity is a vector quantity. &quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward).</description>
  </entry>
  <entry id="product_of_northward_wind_and_air_temperature">
    <canonical_units>K m s-1</canonical_units>
    <amip>mpvta</amip>
    <description>&quot;product_of_X_and_Y&quot; means X*Y. Air temperature is the bulk temperature of the air, not the surface (skin) temperature. &quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)</description>
  </entry>
  <entry id="product_of_northward_wind_and_geopotential_height">
    <canonical_units>m2 s-1</canonical_units>
    <amip>mpvzga</amip>
    <description>&quot;product_of_X_and_Y&quot; means X*Y. 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. &quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)</description>
  </entry>
  <entry id="product_of_northward_wind_and_omega">
    <canonical_units>Pa m s-2</canonical_units>
    <description>&quot;product_of_X_and_Y&quot; means X*Y. &quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.) &quot;omegaX&quot; is used for brevity to mean &quot;lagrangian_tendency_of_air_pressure in standard names constructed as a combination of omega with some other quantity.</description>
  </entry>
  <entry id="product_of_northward_wind_and_specific_humdity">
    <canonical_units>m s-1</canonical_units>
    <description>&quot;product_of_X_and_Y&quot; means X*Y. &quot;specific&quot; means per unit mass. &quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)</description>
  </entry>
  <entry id="product_of_northward_wind_and_specific_humidity">
    <canonical_units>m s-1</canonical_units>
    <amip>mpvhusa</amip>
    <description>&quot;product_of_X_and_Y&quot; means X*Y. &quot;specific&quot; means per unit mass. &quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). Specific humidity is the mass fraction of water vapor in (moist) air. Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)</description>
  </entry>
  <entry id="product_of_northward_wind_and_upward_air_velocity">
    <canonical_units>m2 s-2</canonical_units>
    <description>&quot;product_of_X_and_Y&quot; means X*Y. A velocity is a vector quantity. &quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). &quot;Upward&quot; indicates a vector component which is positive when directed upward (negative downward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.) Upward air velocity is the vertical component of the 3D air velocity vector.</description>
  </entry>
  <entry id="product_of_omega_and_air_temperature">
    <canonical_units>K Pa s-1</canonical_units>
    <amip>mpwapta</amip>
    <description>&quot;product_of_X_and_Y&quot; means X*Y. Air temperature is the bulk temperature of the air, not the surface (skin) temperature. &quot;omegaX&quot; is used for brevity to mean &quot;lagrangian_tendency_of_air_pressure in standard names constructed as a combination of omega with some other quantity.</description>
  </entry>
  <entry id="product_of_omega_and_specific_humidity">
    <canonical_units>Pa s-1</canonical_units>
    <amip>mpwhusa</amip>
    <description>&quot;product_of_X_and_Y&quot; means X*Y. &quot;specific&quot; means per unit mass. Specific humidity is the mass fraction of water vapor in (moist) air. &quot;omegaX&quot; is used for brevity to mean &quot;lagrangian_tendency_of_air_pressure in standard names constructed as a combination of omega with some other quantity.</description>
  </entry>
  <entry id="product_of_specific_humidity_and_omega">
    <canonical_units>Pa s-1</canonical_units>
    <description>&quot;product_of_X_and_Y&quot; means X*Y. &quot;specific&quot; means per unit mass. Specific humidity is the mass fraction of water vapor in (moist) air. &quot;omegaX&quot; is used for brevity to mean &quot;lagrangian_tendency_of_air_pressure in standard names constructed as a combination of omega with some other quantity.</description>
  </entry>
  <entry id="product_of_upward_air_velocity_and_air_temperature">
    <canonical_units>K m s-1</canonical_units>
    <description>&quot;product_of_X_and_Y&quot; means X*Y. Air temperature is the bulk temperature of the air, not the surface (skin) temperature. A velocity is a vector quantity. &quot;Upward&quot; 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.</description>
  </entry>
  <entry id="product_of_upward_air_velocity_and_specific_humidity">
    <canonical_units>m s-1</canonical_units>
    <description>&quot;product_of_X_and_Y&quot; means X*Y. &quot;specific&quot; means per unit mass. A velocity is a vector quantity. &quot;Upward&quot; indicates a vector component which is positive when directed upward (negative downward). Specific humidity is the mass fraction of water vapor in (moist) air. Upward air velocity is the vertical component of the 3D air velocity vector.</description>
  </entry>
  <entry id="projection_x_coordinate">
    <canonical_units>m</canonical_units>
    <description>&quot;x&quot; indicates a vector component along the grid x-axis, when this is not true longitude, positive with increasing x. Projection coordinates are distances in the x- and y-directions on a plane onto which the surface of the Earth has been projected according to a map projection. The relationship between the projection coordinates and latitude and longitude is described by the grid_mapping.</description>
  </entry>
  <entry id="projection_y_coordinate">
    <canonical_units>m</canonical_units>
    <description>&quot;y&quot; indicates a vector component along the grid y-axis, when this is not true latitude, positive with increasing y. Projection coordinates are distances in the x- and y-directions on a plane onto which the surface of the Earth has been projected according to a map projection. The relationship between the projection coordinates and latitude and longitude is described by the grid_mapping.</description>
  </entry>
  <entry id="pseudo_equivalent_potential_temperature">
    <canonical_units>K</canonical_units>
    <grib>14</grib>
    <description>Potential temperature is the temperature a parcel of air or sea water would have if moved adiabatically to sea level pressure.</description>
  </entry>
  <entry id="pseudo_equivalent_temperature">
    <canonical_units>K</canonical_units>
    <description></description>
  </entry>
  <entry id="radial_velocity_of_scatterers_away_from_instrument">
    <canonical_units>m s-1</canonical_units>
    <description>A velocity is a vector quantity. &quot;Radial velocity away from instrument&quot; means the component of the velocity of the scatterers along the line of sight of the instrument where positive implies movement away from the instrument (i.e. outward). The &quot;instrument&quot; (examples are radar and lidar) is the device used to make the observation, and the &quot;scatterers&quot; are what causes the transmitted signal to be returned to the instrument (examples are aerosols, hydrometeors and refractive index irregularities), of whatever kind the instrument detects.</description>
  </entry>
  <entry id="radiation_wavelength">
    <canonical_units>m</canonical_units>
    <description>The radiation wavelength can refer to any electromagnetic wave, such as light, heat radiation and radio waves.</description>
  </entry>
  <entry id="rainfall_amount">
    <canonical_units>kg m-2</canonical_units>
    <description>&quot;Amount&quot; means mass per unit area.</description>
  </entry>
  <entry id="rainfall_flux">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="rainfall_rate">
    <canonical_units>m s-1</canonical_units>
    <description></description>
  </entry>
  <entry id="realization">
    <canonical_units>1</canonical_units>
    <description>Realization is used to label a dimension that can be thought of asa statistical sample, e.g., labelling members of a model ensemble.</description>
  </entry>
  <entry id="region">
    <canonical_units>string</canonical_units>
    <description>A variable with the standard name of region contains strings which indicate geographical regions. These strings must be chosen from the standard region list.</description>
  </entry>
  <entry id="relative_humidity">
    <canonical_units>1</canonical_units>
    <grib>52 E157</grib>
    <amip>hur</amip>
    <description></description>
  </entry>
  <entry id="richardson_number_in_sea_water">
    <canonical_units> 1 </canonical_units>
    <description>Richardson number is a measure of dynamic stability and can be used to diagnose the existence of turbulent flow.  It is defined as the ratio of the buoyant suppression of turbulence (i.e. how statically stable or unstable the conditions are)  to the kinetic energy available to generate turbulence  in a shear flow.</description>
  </entry>
  <entry id="root_depth">
    <canonical_units>m</canonical_units>
    <description>Depth is the vertical distance below the surface. The root depth is maximum depth of soil reached by plant roots, from which they can extract moisture.</description>
  </entry>
  <entry id="runoff_amount">
    <canonical_units>kg m-2</canonical_units>
    <description>&quot;Amount&quot; means mass per unit area. Runoff is the liquid water which drains from land. If not specified, &quot;runoff&quot; refers to the sum of surface runoff and subsurface drainage.</description>
  </entry>
  <entry id="runoff_amount_excluding_baseflow">
    <canonical_units>kg m-2</canonical_units>
    <description>Runoff is the liquid water which drains from land. &quot;Runoff_excluding_baseflow" is the sum of surface runoff and subsurface runoff excluding baseflow.  Baseflow is subsurface runoff which takes place below the level of the water table.  &quot;Amount&quot; means mass per unit area.</description>
  </entry>
  <entry id="runoff_flux">
    <canonical_units>kg m-2 s-1</canonical_units>
    <amip>mrro</amip>
    <description>Runoff is the liquid water which drains from land. If not specified, &quot;runoff&quot; refers to the sum of surface runoff and subsurface drainage. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="scattering_angle">
    <canonical_units>rad</canonical_units>
    <description>The scattering angle is that between the direction of the beam of incident radiation and the direction into which it is scattered.</description>
  </entry>
  <entry id="sea_area">
    <canonical_units>m2</canonical_units>
    <description>&quot;X_area&quot; means the horizontal area occupied by X within the grid cell.</description>
  </entry>
  <entry id="sea_area_fraction">
    <canonical_units>1</canonical_units>
    <description>&quot;X_area_fraction&quot; means the fraction of horizontal area occupied by X. &quot;X_area&quot; means the horizontal area occupied by X within the grid cell.</description>
  </entry>
  <entry id="sea_floor_depth_below_geoid">
    <canonical_units>m</canonical_units>
    <amip>zobt</amip>
    <description>The geoid is a surface of constant geopotential with which mean sea level would coincide if the ocean were at rest. (The volume enclosed between the geoid and the sea floor equals the mean volume of water in the ocean.) In an ocean GCM the geoid is the surface of zero depth, or the rigid lid if the model uses that approximation.</description>
  </entry>
  <entry id="sea_floor_depth_below_sea_level">
    <canonical_units>m</canonical_units>
    <description>sea_level means mean sea level, which is close to the geoid in sea areas.</description>
  </entry>
  <entry id="sea_ice_albedo">
    <canonical_units> 1 </canonical_units>
    <description>The albedo of sea ice.</description>
  </entry>
  <entry id="sea_ice_amount">
    <canonical_units>kg m-2</canonical_units>
    <description>&quot;Amount&quot; means mass per unit area.</description>
  </entry>
  <entry id="sea_ice_area">
    <canonical_units>m2</canonical_units>
    <description>&quot;X_area&quot; means the horizontal area occupied by X within the grid cell.</description>
  </entry>
  <entry id="sea_ice_area_fraction">
    <canonical_units>1</canonical_units>
    <grib>91</grib>
    <amip>sic</amip>
    <description>&quot;X_area_fraction&quot; means the fraction of horizontal area occupied by X. &quot;X_area&quot; means the horizontal area occupied by X within the grid cell. Sea ice area fraction is area of the sea surface occupied by sea ice. It is also called &quot;sea ice concentration&quot;.</description>
  </entry>
  <entry id="sea_ice_draft">
    <canonical_units>m</canonical_units>
    <description>Sea ice draft is the depth of the sea-ice lower surface below the water surface.</description>
  </entry>
  <entry id="sea_ice_extent">
    <canonical_units>m2</canonical_units>
    <description></description>
  </entry>
  <entry id="sea_ice_freeboard">
    <canonical_units>m</canonical_units>
    <description>Sea ice freeboard is the height of the sea-ice upper surface above the water surface.</description>
  </entry>
  <entry id="sea_ice_mass">
    <canonical_units>kg</canonical_units>
    <description></description>
  </entry>
  <entry id="sea_ice_speed">
    <canonical_units>m s-1</canonical_units>
    <grib>94</grib>
    <description>Speed is the magnitude of velocity.</description>
  </entry>
  <entry id="sea_ice_temperature">
    <canonical_units>K</canonical_units>
    <description></description>
  </entry>
  <entry id="sea_ice_thickness">
    <canonical_units>m</canonical_units>
    <grib>92</grib>
    <amip>sit</amip>
    <description></description>
  </entry>
  <entry id="sea_ice_transport_across_line">
    <canonical_units>kg s-1</canonical_units>
    <description>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.</description>
  </entry>
  <entry id="sea_ice_volume">
    <canonical_units>m3</canonical_units>
    <description></description>
  </entry>
  <entry id="sea_ice_x_velocity">
    <canonical_units>m s-1</canonical_units>
    <description>A velocity is a vector quantity. &quot;x&quot; indicates a vector component along the grid x-axis, when this is not true longitude, positive with increasing x.</description>
  </entry>
  <entry id="sea_ice_y_velocity">
    <canonical_units>m s-1</canonical_units>
    <description>A velocity is a vector quantity. &quot;y&quot; indicates a vector component along the grid y-axis, when this is not true latitude, positive with increasing y.</description>
  </entry>
  <entry id="sea_surface_foundation_temperature">
    <canonical_units>K</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. The sea surface foundation temperature is the water temperature that is not influenced by a thermally stratified layer of diurnal temperature variability (either by daytime warming or nocturnal cooling). The foundation temperature is named to indicate that it is the temperature from which the growth of the diurnal thermocline develops each day, noting that on some occasions with a deep mixed layer there is no clear foundation temperature in the surface layer. In general, sea surface foundation temperature will be similar to a night time minimum or pre-dawn value at depths of between approximately 1 and 5 meters. In the absence of any diurnal signal, the foundation temperature is considered equivalent to the quantity with standard name sea_surface_subskin_temperature. The sea surface foundation temperature defines a level in the upper water column that varies in depth, space, and time depending on the local balance between thermal stratification and turbulent energy and is expected to change slowly over the course of a day. If possible, a data variable with the standard name sea_surface_foundation_temperature should be used with a scalar vertical coordinate variable to specify the depth of the foundation level.

Sea surface foundation temperature is measured at the base of the diurnal thermocline or as close to the water surface as possible in the absence of thermal stratification. Only in situ contact thermometry is able to measure the sea surface foundation temperature. Analysis procedures must be used to estimate sea surface foundation temperature value from radiometric satellite measurements of the quantities with standard names sea_surface_skin_temperature and sea_surface_subskin_temperature.  Sea surface foundation temperature provides a connection with the historical concept of a &quot;bulk&quot; sea surface temperature considered representative of the oceanic mixed layer temperature that is typically represented by any sea temperature measurement within the upper ocean over a depth range of 1 to approximately 20 meters. The general term, &quot;bulk&quot; sea surface temperature, has the standard name sea_surface_temperature with no associated vertical coordinate axis. Sea surface foundation temperature provides a more precise, well-defined quantity than &quot;bulk&quot; sea surface temperature and, consequently, is more representative of the mixed layer temperature.  The temperature of sea water at a particular depth (other than the foundation level) should be reported using the standard name sea_water_temperature and, wherever possible, supplying a vertical coordinate axis or scalar coordinate variable.</description>
  </entry>
  <entry id="sea_surface_height_above_geoid">
    <canonical_units>m</canonical_units>
    <description>The geoid is a surface of constant geopotential with which mean sea level would coincide if the ocean were at rest. (The volume enclosed between the geoid and the sea floor equals the mean volume of water in the ocean.) In an ocean GCM the geoid is the surface of zero depth, or the rigid lid if the model uses that approximation. &quot;Sea surface height&quot; is a time-varying quantity. By definition of the geoid, the global average of the time-mean sea surface height (i.e. mean sea level) above the geoid must be zero. The standard name for the height of the sea surface above mean sea level is sea_surface_height_above_sea_level. The standard name for the height of the sea surface above the reference ellipsoid is sea_surface_height_above_reference_ellipsoid.</description>
  </entry>
  <entry id="sea_surface_height_above_reference_ellipsoid">
    <canonical_units>m</canonical_units>
    <description>&quot;Sea surface height&quot; is a time-varying quantity.  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.  The standard name for the height of the sea surface above the geoid is sea_surface_height_above_geoid.  The standard name for the height of the sea surface above mean sea level is sea_surface_height_above_sea_level.</description>
  </entry>
  <entry id="sea_surface_height_above_sea_level">
    <canonical_units>m</canonical_units>
    <grib>82</grib>
    <description>sea_level means mean sea level, which is close to the geoid in sea areas. &quot;Sea surface height&quot; is a time-varying quantity. The standard name for the height of the sea surface above the geoid is sea_surface_height_above_geoid. The standard name for the height of the sea surface above the reference ellipsoid is sea_surface_height_above_reference_ellipsoid.</description>
  </entry>
  <entry id="sea_surface_height_amplitude_due_to_earth_tide">
    <canonical_units>m</canonical_units>
    <description>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. Tides are a significant contributor to the observed sea surface height; earth tide means the solid earth tide.</description>
  </entry>
  <entry id="sea_surface_height_amplitude_due_to_equilibrium_ocean_tide">
    <canonical_units>m</canonical_units>
    <description>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. Tides are a significant contributor to the observed sea surface height; equilibrium ocean tide refers to the long period ocean tide.</description>
  </entry>
  <entry id="sea_surface_height_amplitude_due_to_geocentric_ocean_tide">
    <canonical_units>m</canonical_units>
    <description>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. Tides are a significant contributor to the observed sea surface height; geocentric ocean tide means the sum total of ocean tide and load tide.</description>
  </entry>
  <entry id="sea_surface_height_amplitude_due_to_non_equilibrium_ocean_tide">
    <canonical_units>m</canonical_units>
    <description>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. Tides are a significant contributor to the observed sea surface height; non equilibrium ocean tide refers to the long period ocean tide.</description>
  </entry>
  <entry id="sea_surface_height_amplitude_due_to_pole_tide">
    <canonical_units>m</canonical_units>
    <description>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. Tides are a significant contributor to the observed sea surface height; the pole tide occurs due to variations in the earth's rotation.</description>
  </entry>
  <entry id="sea_surface_height_bias_due_to_sea_surface_roughness">
    <canonical_units>m</canonical_units>
    <description>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.  Altimeter pulses tend to be more strongly refelected by the troughs of sea surface waves than by the crests leading to a bias in the measured sea surface height. This quantity is commonly known as &quot;sea state bias&quot;.</description>
  </entry>
  <entry id="sea_surface_height_correction_due_to_air_pressure_at_low_frequency">
    <canonical_units>m</canonical_units>
    <description>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. &quot;Air pressure at low frequency&quot; means variations in air pressure with periods longer than 20 days. These give rise to corresponding variations in sea surface topography. The quantity sea_surface_height_correction_due_to_air_pressure_at_low_frequency is commonly called the &quot;inverted barometer effect&quot; and the correction should be applied by adding it to the quantity with standard name altimeter_range.  Additional altimeter range corrections are given by the quantities with standard names altimeter_range_correction_due_to_wet_troposphere, altimeter_range_correction_due_to_dry_troposphere, altimeter_range_correction_due_to_ionosphere and sea_surface_height_correction_due_to_air_pressure_and_wind_at_high_frequency.</description>
  </entry>
  <entry id="sea_surface_height_correction_due_to_air_pressure_and_wind_at_high_frequency">
    <canonical_units>m</canonical_units>
    <description>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. &quot;Air pressure and wind at high frequency&quot; means variations in air pressure with periods shorter  than 20 days. These give rise to corresponding variations in sea surface topography. The quantity sea_surface_height_correction_due_to_air_pressure_and_wind_at_high_frequency  should be applied by adding it to the quantity with standard name altimeter_range.  Additional altimeter range corrections are given by the quantities with standard names altimeter_range_correction_due_to_wet_troposphere, altimeter_range_correction_due_to_dry_troposphere, altimeter_range_correction_due_to_ionosphere and sea_surface_height_correction_due_to_air_pressure_at_low_frequency.</description>
  </entry>
  <entry id="sea_surface_salinity">
    <canonical_units>1e-3</canonical_units>
    <description>The unit of salinity is PSU, which is dimensionless. The units attribute should be given as 1e-3 or 0.001 i.e. parts per thousand if salinity is in PSU. Sea surface salinity is often abbreviated as &quot;SSS&quot;. For the salinity of sea water at a particular depth or layer, a data variable of sea_water_salinity with a vertical coordinate axis should be used.</description>
  </entry>
  <entry id="sea_surface_skin_temperature">
  <canonical_units>K</canonical_units>
  <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. The sea surface skin temperature is the temperature measured by an infrared radiometer typically operating at wavelengths in the range 3.7 - 12 micrometers. It represents the temperature within the conductive diffusion-dominated sub-layer at a depth of approximately 10 - 20 micrometers below the air-sea interface. Measurements of this quantity are subject to a large potential diurnal cycle including cool skin layer effects (especially at night under clear skies and low wind speed conditions) and warm layer effects in the daytime.</description>
  </entry>
  <entry id="sea_surface_subskin_temperature">
    <canonical_units>K</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. The sea surface subskin temperature is the temperature at the base of the conductive laminar sub-layer of the ocean surface, that is, at a depth of approximately 1 - 1.5 millimeters below the air-sea interface. For practical purposes, this quantity can be well approximated to the measurement of surface temperature by a microwave radiometer operating in the 6 - 11 gigahertz frequency range, but the relationship is neither direct nor invariant to changing physical conditions or to the specific geometry of the microwave measurements. Measurements of this quantity are subject to a large potential diurnal cycle due to thermal stratification of the upper ocean layer in low wind speed high solar irradiance conditions.</description>
  </entry>
  <entry id="sea_surface_swell_wave_mean_period_from_variance_spectral_density_first_frequency_moment">
    <canonical_units>s</canonical_units>
    <description>The swell wave directional spectrum can be written as a  five dimensional function S(t,x,y,f,theta) where t is time, x and y are horizontal coordinates (such as longitude and latitude), f is frequency and theta is direction.  S can be integrated over direction to give S1= integral(S dtheta).  Frequency moments, M(n) of S1 can then be calculated as follows: M(n) = integral(S1 f^n df), where f^n is f to the power of n.  The first wave period, T(m1), is calculated as the ratio M(0)/M(1).</description>
  </entry>
  <entry id="sea_surface_swell_wave_mean_period_from_variance_spectral_density_inverse_frequency_moment">
    <canonical_units>s</canonical_units>
    <description>The swell wave directional spectrum can be written as a  five dimensional function S(t,x,y,f,theta) where t is time, x and y are horizontal coordinates (such as longitude and latitude), f is frequency and theta is direction.  S can be integrated over direction to give  S1= integral(S dtheta).  Frequency moments, M(n) of S1 can then be calculated as follows: M(n) = integral(S1 f^n df), where f^n is f to the power of n.  The inverse wave period, T(m-1), is calculated as the ratio M(-1)/M(0).</description>
  </entry>
  <entry id="sea_surface_swell_wave_mean_period_from_variance_spectral_density_second_frequency_moment">
    <canonical_units>s</canonical_units>
    <description>The swell wave directional spectrum can be written as a  five dimensional function S(t,x,y,f,theta) where t is time, x and y are horizontal coordinates (such as longitude and latitude), f is frequency and theta is direction.  S can be integrated over direction to give S1= integral(S dtheta).  Frequency moments, M(n) of S1 can then be calculated as follows: M(n) = integral(S1 f^n df), where f^n is f to the power of n.  The second wave period, T(m2), is calculated as the square root of the ratio M(0)/M(2).</description>
  </entry>
  <entry id="sea_surface_swell_wave_period">
    <canonical_units>s</canonical_units>
    <grib>106</grib>
    <description>A period is an interval of time, or the time-period of an oscillation. Swell waves are waves on the ocean surface.</description>
  </entry>
  <entry id="sea_surface_swell_wave_significant_height">
    <canonical_units>m</canonical_units>
    <grib>105</grib>
    <description>Height is the vertical distance above the surface. Swell waves are waves on the ocean surface.</description>
  </entry>
  <entry id="sea_surface_swell_wave_to_direction">
    <canonical_units>degree</canonical_units>
    <grib>104</grib>
    <description>Swell waves are waves on the ocean surface. &quot;to_direction&quot; is used in the construction X_to_direction and indicates the direction towards which the velocity vector of X is headed.</description>
  </entry>
  <entry id="sea_surface_swell_wave_zero_upcrossing_period">
    <canonical_units>s</canonical_units>
    <description>A period is an interval of time, or the time-period of an oscillation. The zero upcrossing period is defined as the time interval between consecutive occasions on which the surface height passes upward above the mean level. Swell waves are waves on the ocean surface.</description>
  </entry>
  <entry id="sea_surface_temperature">
    <canonical_units>K</canonical_units>
    <description>Sea surface temperature is usually abbreviated as &quot;SST&quot;. It is the temperature of sea water near the surface (including the part under sea-ice, if any), and not the skin temperature, whose standard name is surface_temperature. For the temperature of sea water at a particular depth or layer, a data variable of sea_water_temperature with a vertical coordinate axis should be used.</description>
  </entry>
  <entry id="sea_surface_wave_directional_variance_spectral_density">
    <canonical_units>m2 s rad-1</canonical_units>
    <description>Sea surface wave directional variance spectral density is the variance of the amplitude of the waves within given ranges of direction and wave frequency.</description>
  </entry>
  <entry id="sea_surface_wave_from_direction">
    <canonical_units>degree</canonical_units>
    <description>&quot;from_direction&quot; is used in the construction X_from_direction and indicates the direction from which the velocity vector of X is coming.</description>
  </entry>
  <entry id="sea_surface_wave_mean_period_from_variance_spectral_density_first_frequency_moment">
    <canonical_units>s</canonical_units>
    <description>The wave directional spectrum can be written as a  five dimensional function S(t,x,y,f,theta) where t is time, x and y are horizontal coordinates (such as longitude and latitude), f is frequency and theta is direction.  S has the standard name sea_surface_wave_directional_variance_spectral_density.  S can be integrated over direction to give S1= integral(S dtheta) and this quantity has the standard name sea_surface_wave_variance_spectral_density.  Frequency moments, M(n) of S1 can then be calculated as follows: M(n) = integral(S1 f^n df), where f^n is f to the power of n.  The first wave period, T(m1)  is calculated as the ratio M(0)/M(1).</description>
  </entry>
  <entry id="sea_surface_wave_mean_period_from_variance_spectral_density_inverse_frequency_moment">
    <canonical_units>s</canonical_units>
    <description>The wave directional spectrum can be written as a  five dimensional function S(t,x,y,f,theta) where t is time, x and y are horizontal coordinates (such as longitude and latitude), f is frequency and theta is direction.  S has the standard name sea_surface_wave_directional_variance_spectral_density.  S can be integrated over direction to give S1= integral(S dtheta) and this quantity has the standard name sea_surface_wave_variance_spectral_density.  Frequency moments, M(n) of S1 can then be calculated as follows: M(n) = integral(S1 f^n df), where f^n is f to the power of n.  The inverse wave period, T(m-1), is calculated as the ratio M(-1)/M(0).</description>
  </entry>
  <entry id="sea_surface_wave_mean_period_from_variance_spectral_density_second_frequency_moment">
    <canonical_units>s</canonical_units>
    <description>The wave directional spectrum can be written as a  five dimensional function S(t,x,y,f,theta) where t is time, x and y are horizontal coordinates (such as longitude and latitude), f is frequency and theta is direction.  S has the standard name sea_surface_wave_directional_variance_spectral_density.  S can be integrated over direction to give S1= integral(S dtheta) and this quantity has the standard name sea_surface_wave_variance_spectral_density.  Frequency moments, M(n) of S1 can then be calculated as follows: M(n) = integral(S1 f^n df), where f^n is f to the power of n.  The second wave period, T(m2) is calculated as the square root of the ratio M(0)/M(2).</description>
  </entry>
  <entry id="sea_surface_wave_significant_height">
    <canonical_units>m</canonical_units>
    <grib>100</grib>
    <description>Height is the vertical distance above the surface.</description>
  </entry>
  <entry id="sea_surface_wave_to_direction">
    <canonical_units>degree</canonical_units>
    <description>&quot;to_direction&quot; is used in the construction X_to_direction and indicates the direction towards which the velocity vector of X is headed.</description>
  </entry>
  <entry id="sea_surface_wave_variance_spectral_density">
    <canonical_units>m2 s</canonical_units>
    <description>Sea surface wave variance spectral density is the variance of wave amplitude within a range of wave frequency.</description>
  </entry>
  <entry id="sea_surface_wave_zero_upcrossing_period">
    <canonical_units>s</canonical_units>
    <description>A period is an interval of time, or the time-period of an oscillation. The zero upcrossing period is defined as the time interval between consecutive occasions on which the surface height passes upward above the mean level.</description>
  </entry>
  <entry id="sea_surface_wind_wave_mean_period_from_variance_spectral_density_first_frequency_moment">
    <canonical_units>s</canonical_units>
    <description>The wind wave directional spectrum can be written as a  five dimensional function S(t,x,y,f,theta) where t is time, x and y are horizontal coordinates (such as longitude and latitude), f is frequency and theta is direction.  S can be integrated over direction to give S1= integral(S dtheta) .  Frequency moments, M(n) of S1 can then be calculated as follows: M(n) = integral(S1 f^n df), where f^n is f to the power of n.  The first wave period, T(m1) is calculated as the ratio M(0)/M(1).</description>
  </entry>
  <entry id="sea_surface_wind_wave_mean_period_from_variance_spectral_density_inverse_frequency_moment">
    <canonical_units>s</canonical_units>
    <description>The wind wave directional spectrum can be written as a  five dimensional function S(t,x,y,f,theta) where t is time, x and y are horizontal coordinates (such as longitude and latitude), f is frequency and theta is direction.  S can be integrated over direction to give S1= integral(S dtheta).  Frequency moments, M(n) of S1 can then be calculated as follows: M(n) = integral(S1 f^n df), where f^n is f to the power of n.  The inverse wave period, T(m-1), is calculated as the ratio M(-1)/M(0).</description>
  </entry>
  <entry id="sea_surface_wind_wave_mean_period_from_variance_spectral_density_second_frequency_moment">
    <canonical_units>s</canonical_units>
    <description>The wind wave directional spectrum can be written as a  five dimensional function S(t,x,y,f,theta) where t is time, x and y are horizontal coordinates (such as longitude and latitude), f is frequency and theta is direction.  S can be integrated over direction, thus S1= integral(S dtheta).  Frequency moments, M(n) of S1 can then be calculated as follows: M(n) = integral(S1 f^n df), where f^n is f to the power of n.  The second wave period, T(m2), is calculated as the square root of the ratio M(0)/M(2).</description>
  </entry>
  <entry id="sea_surface_wind_wave_period">
    <canonical_units>s</canonical_units>
    <grib>103</grib>
    <description>A period is an interval of time, or the time-period of an oscillation. Wind waves are waves on the ocean surface. Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)</description>
  </entry>
  <entry id="sea_surface_wind_wave_significant_height">
    <canonical_units>m</canonical_units>
    <grib>102</grib>
    <description>Height is the vertical distance above the surface. Wind waves are waves on the ocean surface. Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)</description>
  </entry>
  <entry id="sea_surface_wind_wave_to_direction">
    <canonical_units>degree</canonical_units>
    <grib>101</grib>
    <description>Wind waves are waves on the ocean surface. Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.) &quot;to_direction&quot; is used in the construction X_to_direction and indicates the direction towards which the velocity vector of X is headed.</description>
  </entry>
  <entry id="sea_surface_wind_wave_zero_upcrossing_period">
    <canonical_units>s</canonical_units>
    <description>A period is an interval of time, or the time-period of an oscillation. The zero upcrossing period is defined as the time interval between consecutive occasions on which the surface height passes upward above the mean level. Wind waves are waves on the ocean surface. Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)</description>
  </entry>
  <entry id="sea_water_density">
    <canonical_units>kg m-3</canonical_units>
    <description>Sea water density is the in-situ density (not the potential density). If 1000 kg m-3 is subtracted, the standard name sea_water_sigma_t should be chosen instead.</description>
  </entry>
  <entry id="sea_water_electrical_conductivity">
    <canonical_units>S m-1</canonical_units>
    <description></description>
  </entry>
  <entry id="sea_water_potential_density">
    <canonical_units>kg m-3</canonical_units>
    <description>Potential density is the density a parcel of air or sea water would have if moved adiabatically to a reference pressure, by default assumed to be sea level pressure. For sea water potential density, if 1000 kg m-3 is subtracted, the standard name sea_water_sigma_theta should be chosen instead.</description>
  </entry>
  <entry id="sea_water_potential_temperature">
    <canonical_units>K</canonical_units>
    <description>Potential temperature is the temperature a parcel of air or sea water would have if moved adiabatically to sea level pressure.</description>
  </entry>
  <entry id="sea_water_pressure">
    <canonical_units>dbar</canonical_units>
    <description></description>
  </entry>
  <entry id="sea_water_salinity">
    <canonical_units>1e-3</canonical_units>
    <grib>88</grib>
    <amip>so</amip>
    <description>The unit of salinity is PSU, which is dimensionless. The units attribute should be given as 1e-3 or 0.001 i.e. parts per thousand if salinity is in PSU.</description>
  </entry>
  <entry id="sea_water_sigma_t">
    <canonical_units>kg m-3</canonical_units>
    <description>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. Note that sea water sigma is not the same quantity as the dimensionless ocean sigma coordinate (see Appendix D of the CF convention), for which there is another standard name.</description>
  </entry>
  <entry id="sea_water_sigma_theta">
    <canonical_units>kg m-3</canonical_units>
    <description>Sigma-theta of sea water is the potential density (i.e. the density when moved adiabatically to a reference pressure) of water having the same temperature and salinity, minus 1000 kg m-3. Note that sea water sigma is not the same quantity as the dimensionless ocean sigma coordinate (see Appendix D of the CF convention), for which there is another standard name.</description>
  </entry>
  <entry id="sea_water_speed">
    <canonical_units>m s-1</canonical_units>
    <grib>48</grib>
    <description>Speed is the magnitude of velocity.</description>
  </entry>
  <entry id="sea_water_temperature">
    <canonical_units>K</canonical_units>
    <grib>80</grib>
    <amip>to</amip>
    <description></description>
  </entry>
  <entry id="sea_water_x_velocity">
    <canonical_units>m s-1</canonical_units>
    <description>A velocity is a vector quantity. &quot;x&quot; indicates a vector component along the grid x-axis, when this is not true longitude, positive with increasing x.</description>
  </entry>
  <entry id="sea_water_y_velocity">
    <canonical_units>m s-1</canonical_units>
    <description>A velocity is a vector quantity. &quot;y&quot; indicates a vector component along the grid y-axis, when this is not true latitude, positive with increasing y.</description>
  </entry>
  <entry id="snow_density">
    <canonical_units>kg m-3</canonical_units>
    <description></description>
  </entry>
  <entry id="snow_grain_size">
    <canonical_units>m</canonical_units>
    <description></description>
  </entry>
  <entry id="snow_soot_content">
    <canonical_units>kg m-2</canonical_units>
    <description>&quot;Content&quot; indicates a quantity per unit area.</description>
  </entry>
  <entry id="snow_temperature">
    <canonical_units>K</canonical_units>
    <grib>E238</grib>
    <description>Snow temperature is the bulk temperature of the snow, not the surface (skin) temperature.</description>
  </entry>
  <entry id="snow_thermal_energy_content">
    <canonical_units>J m-2</canonical_units>
    <description>&quot;Content&quot; indicates a quantity per unit area. Thermal energy is the total vibrational energy, kinetic and potential, of all the molecules and atoms in a substance.</description>
  </entry>
  <entry id="snowfall_amount">
    <canonical_units>kg m-2</canonical_units>
    <description>&quot;Amount&quot; means mass per unit area.</description>
  </entry>
  <entry id="snowfall_flux">
    <canonical_units>kg m-2 s-1</canonical_units>
    <grib>64</grib>
    <amip>prsn</amip>
    <description>In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="soil_albedo">
    <canonical_units>1</canonical_units>
    <description>Soil albedo is the albedo of the soil surface assuming no snow.</description>
  </entry>
  <entry id="soil_carbon_content">
    <canonical_units>kg m-2</canonical_units>
    <description>&quot;Content&quot; indicates a quantity per unit area. The &quot;soil content&quot; 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.</description>
  </entry>
  <entry id="soil_frozen_water_content">
    <canonical_units>kg m-2</canonical_units>
    <amip>mrfso</amip>
    <description>&quot;frozen_water&quot; means ice. &quot;Content&quot; indicates a quantity per unit area. The &quot;soil content&quot; 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.</description>
  </entry>
  <entry id="soil_hydraulic_conductivity_at_saturation">
    <canonical_units>m s-1</canonical_units>
    <description>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).</description>
  </entry>
  <entry id="soil_moisture_content">
    <canonical_units>kg m-2</canonical_units>
    <grib>86</grib>
    <amip>mrso</amip>
    <description>&quot;moisture&quot; means water in all phases contained in soil. &quot;Content&quot; indicates a quantity per unit area. The &quot;soil content&quot; 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.</description>
  </entry>
  <entry id="soil_moisture_content_at_field_capacity">
    <canonical_units>kg m-2</canonical_units>
    <amip>mrsofc</amip>
    <description>&quot;moisture&quot; means water in all phases contained in soil. &quot;Content&quot; indicates a quantity per unit area. The &quot;soil content&quot; 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. The field capacity of soil is the maximum content of water it can retain against gravitational drainage.</description>
  </entry>
  <entry id="soil_porosity">
    <canonical_units>1</canonical_units>
    <description>The soil porosity is the proportion of its total volume not occupied by soil solids.</description>
  </entry>
  <entry id="soil_respiration_carbon_flux">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;Respiration carbon&quot; refers to the rate at which biomass is respired expressed as the mass of carbon which it contains. Soil respiration is the sum of respiration in the soil by animals and decomposers of litter (heterotrophs or &quot;consumers&quot;), which have not produced the biomass they respire, and respiration by the roots of plants (autotrophs or &quot;producers&quot;), which have themselves produced the biomass they respire. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="soil_suction_at_saturation">
    <canonical_units>Pa</canonical_units>
    <description>Soil suction is the tensile stress on water in soil due to molecular forces acting at the water-soil particle boundary. The forces may cause water to be drawn into the spaces within the soil matrix or cause it to be held in the soil without draining. Soil suction occurs in soil above the water table.</description>
  </entry>
  <entry id="soil_temperature">
    <canonical_units>K</canonical_units>
    <grib>85</grib>
    <description>Soil temperature is the bulk temperature of the soil, not the surface (skin) temperature.</description>
  </entry>
  <entry id="soil_thermal_capacity">
    <canonical_units>J kg-1 K-1</canonical_units>
    <description>Thermal capacity, or heat capacity, is the amount of heat energy required to increase the temperature of 1 kg of material by 1 K. It is a property of the material.</description>
  </entry>
  <entry id="soil_thermal_conductivity">
    <canonical_units>W m-1 K-1</canonical_units>
    <description>Thermal conductivity is the constant k in the formula q = -k grad T where q is the heat transfer per unit time per unit area of a surface normal to the direction of transfer and grad T is the temperature gradient. Thermal conductivity is a property of the material.</description>
  </entry>
  <entry id="soil_type">
    <canonical_units>1</canonical_units>
    <description>A variable with the standard name of soil_type contains strings which indicate the character of the soil e.g. clay. These strings have not yet been standardised. Alternatively, the data variable may contain integers which can be translated to strings using flag_values and flag_meanings attributes.</description>
  </entry>
  <entry id="solar_azimuth_angle">
    <canonical_units>degree</canonical_units>
    <description>Solar azimuth angle is the horizontal angle between the line of sight to the sun and a reference direction which is often due north. The angle is measured clockwise.</description>
  </entry>
  <entry id="solar_elevation_angle">
    <canonical_units>degree</canonical_units>
    <description>Solar elevation angle is the angle between the line of sight to the sun and the local horizontal.</description>
  </entry>
  <entry id="solar_zenith_angle">
    <canonical_units>degree</canonical_units>
    <description>Solar zenith angle is the the angle between the line of sight to the sun and the local vertical.</description>
  </entry>
  <entry id="sound_frequency">
    <canonical_units>s-1</canonical_units>
    <description>Frequency is the number of oscillations of a wave per unit time.</description>
  </entry>
  <entry id="sound_intensity_in_air">
    <canonical_units>W m-2</canonical_units>
    <description>Sound intensity is the sound energy per unit time per unit area.</description>
  </entry>
  <entry id="sound_intensity_in_water">
    <canonical_units>W m-2</canonical_units>
    <description>Sound intensity is the sound energy per unit time per unit area.</description>
  </entry>
  <entry id="sound_intensity_level_in_air">
    <canonical_units>dB</canonical_units>
    <description>Sound intensity is the sound energy per unit time per unit area. Sound intensity level in air is expressed on a logarithmic scale with reference to a sound intensity of 1e-12 W m-2. LI = 10 log10(I/I0) where LI is sound intensity level, I is sound intensity and I0 is the reference sound intensity.</description>
  </entry>
  <entry id="sound_intensity_level_in_water">
    <canonical_units>dB</canonical_units>
    <description>Sound intensity is the sound energy per unit time per unit area. Sound intensity level in water is expressed on a logarithmic scale with reference to a sound intensity of 6.7e-19 W m-2. LI = 10 log10(I/I0) where LI is sound intensity level, I is sound intensity and I0 is the reference sound intensity.</description>
  </entry>
  <entry id="sound_pressure_in_air">
    <canonical_units>Pa</canonical_units>
    <description>Sound pressure is the difference from the local ambient pressure caused by a sound wave at a particular location and time.</description>
  </entry>
  <entry id="sound_pressure_in_water">
    <canonical_units>Pa</canonical_units>
    <description>Sound pressure is the difference from the local ambient pressure caused by a sound wave at a particular location and time.</description>
  </entry>
  <entry id="sound_pressure_level_in_air">
    <canonical_units>dB</canonical_units>
    <description>Sound pressure is the difference from the local ambient pressure caused by a sound wave at a particular location and time. Sound pressure level in air is expressed on a logarithmic scale with reference to a sound pressure of 2e-5 Pa. Lp = 20 log10(p/p0) where Lp is the sound pressure level, p is the rms sound pressure and p0 is the reference sound pressure.</description>
  </entry>
  <entry id="sound_pressure_level_in_water">
    <canonical_units>dB</canonical_units>
    <description>Sound pressure is the difference from the local ambient pressure caused by a sound wave at a particular location and time. Sound pressure level in water is expressed on a logarithmic scale with reference to a sound pressure of 1e-6 Pa. Lp = 20 log10(p/p0) where Lp is the sound pressure level, p is the rms sound pressure and p0 is the reference sound pressure.</description>
  </entry>
  <entry id="specific_dry_energy_of_air">
    <canonical_units>m2 s-2</canonical_units>
    <description>&quot;specific&quot; means per unit mass. Dry energy is the sum of dry static energy and kinetic energy. Dry static energy is the sum of enthalpy and potential energy (itself the sum of gravitational and centripetal potential energy). Enthalpy can be written either as (1) CpT, where Cp is heat capacity at constant pressure, T is absolute temperature, or (2) U+pV, where U is internal energy, p is pressure and V is volume.</description>
  </entry>
  <entry id="specific_gravitational_potential_energy">
    <canonical_units>J kg-1</canonical_units>
    <description>&quot;specific&quot; means per unit mass. 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.)</description>
  </entry>
  <entry id="specific_humidity">
    <canonical_units>1</canonical_units>
    <grib>51 E133</grib>
    <amip>hus</amip>
    <description>&quot;specific&quot; means per unit mass. Specific humidity is the mass fraction of water vapor in (moist) air.</description>
  </entry>
  <entry id="specific_kinetic_energy_of_air">
    <canonical_units>m2 s-2</canonical_units>
    <description>&quot;specific&quot; means per unit mass.</description>
  </entry>
  <entry id="specific_kinetic_energy_of_sea_water">
    <canonical_units>m2 s-2</canonical_units>
    <description>&quot;specific&quot; means per unit mass.</description>
  </entry>
  <entry id="speed_of_sound_in_air">
    <canonical_units>m s-1</canonical_units>
    <description>Speed is the magnitude of velocity.</description>
  </entry>
  <entry id="speed_of_sound_in_sea_water">
    <canonical_units>m s-1</canonical_units>
    <description>Speed is the magnitude of velocity.</description>
  </entry>
  <entry id="square_of_air_temperature">
    <canonical_units>K2</canonical_units>
    <amip>mptta</amip>
    <description>&quot;square_of_X&quot; means X*X. Air temperature is the bulk temperature of the air, not the surface (skin) temperature.</description>
  </entry>
  <entry id="square_of_brunt_vaisala_frequency_in_air">
    <canonical_units>s-2</canonical_units>
    <grib>N138</grib>
    <description>&quot;square_of_X&quot; means X*X. Frequency is the number of oscillations of a wave per unit time.</description>
  </entry>
  <entry id="square_of_eastward_wind">
    <canonical_units>m2 s-2</canonical_units>
    <amip>mpuua</amip>
    <description>&quot;square_of_X&quot; means X*X. &quot;Eastward&quot; indicates a vector component which is positive when directed eastward (negative westward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)</description>
  </entry>
  <entry id="square_of_geopotential_height">
    <canonical_units>m2</canonical_units>
    <description>&quot;square_of_X&quot; means X*X. 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.</description>
  </entry>
  <entry id="square_of_lagrangian_tendency_of_air_pressure">
    <canonical_units>Pa2 s-2</canonical_units>
    <description>&quot;square_of_X&quot; means X*X. &quot;tendency_of_X&quot; means derivative of X with respect to time. The Lagrangian tendency of a quantity is its rate of change following the motion of the fluid, also called the &quot;material derivative&quot; or &quot;convective derivative&quot;. The Lagrangian tendency of air pressure, often called &quot;omega&quot;, plays the role of the upward component of air velocity when air pressure is being used as the vertical coordinate. If the vertical air velocity is upwards, it is negative when expressed as a tendency of air pressure; downwards is positive.</description>
  </entry>
  <entry id="square_of_northward_wind">
    <canonical_units>m2 s-2</canonical_units>
    <amip>mpvva</amip>
    <description>&quot;square_of_X&quot; means X*X. &quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)</description>
  </entry>
  <entry id="square_of_upward_air_velocity">
    <canonical_units>m2 s-2</canonical_units>
    <description>&quot;square_of_X&quot; means X*X. A velocity is a vector quantity. &quot;Upward&quot; 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.</description>
  </entry>
  <entry id="stratiform_cloud_area_fraction_in_atmosphere_layer">
    <canonical_units>1</canonical_units>
    <description>&quot;Layer&quot; 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. &quot;X_area_fraction&quot; means the fraction of horizontal area occupied by X. &quot;X_area&quot; means the horizontal area occupied by X within the grid cell. Cloud area fraction is also called &quot;cloud amount&quot; and &quot;cloud cover&quot;. In an atmosphere model, stratiform cloud is that produced by large-scale convergence (not the convection schemes).</description>
  </entry>
  <entry id="subsurface_runoff_amount">
    <canonical_units>kg m-2</canonical_units>
    <description>&quot;Amount&quot; means mass per unit area. Runoff is the liquid water which drains from land. If not specified, &quot;runoff&quot; refers to the sum of surface runoff and subsurface drainage.</description>
  </entry>
  <entry id="subsurface_runoff_flux">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>Runoff is the liquid water which drains from land. If not specified, &quot;runoff&quot; refers to the sum of surface runoff and subsurface drainage. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_air_pressure">
    <canonical_units>Pa</canonical_units>
    <grib>E134</grib>
    <amip>ps</amip>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere.</description>
  </entry>
  <entry id="surface_albedo">
    <canonical_units>1</canonical_units>
    <grib>84 E174</grib>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere.</description>
  </entry>
  <entry id="surface_albedo_assuming_deep_snow">
    <canonical_units>1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition.</description>
  </entry>
  <entry id="surface_albedo_assuming_no_snow">
    <canonical_units>1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition.</description>
  </entry>
  <entry id="surface_altitude">
    <canonical_units>m</canonical_units>
    <amip>orog</amip>
    <description>The surface called &quot;surface&quot; 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.</description>
  </entry>
  <entry id="surface_backwards_scattering_coefficient_of_radar_wave">
    <canonical_units> 1 </canonical_units>
    <description>The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Scattering of radiation is its deflection from its incident path without loss of energy. Backwards scattering refers to the sum of scattering into all backward angles i.e. scattering_angle exceeding pi/2 radians. A scattering_angle should not be specified with this quantity.</description>
  </entry>
  <entry id="surface_brightness_temperature">
    <canonical_units>K</canonical_units>
    <description>The surface called "surface" means the lower boundary of the atmosphere.The brightness temperature of a body is the temperature of a black body which radiates the same power per unit solid angle per unit area.</description>
  </entry>
  <entry id="surface_carbon_dioxide_mole_flux">
    <canonical_units>mol m-2 s-1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_carbon_dioxide_partial_pressure_difference_between_air_and_sea_water">
    <canonical_units>Pa</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Water&quot; means water in all phases, including frozen i.e. ice and snow. 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.</description>
  </entry>
  <entry id="surface_cover">
    <canonical_units>string</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. A variable with the standard name of surface_cover contains strings which indicate the nature of the surface e.g. urban, forest, vegetation, land, sea_ice, open_sea. These strings have not yet been standardised. This standard name is a generalisation of land_cover.</description>
  </entry>
  <entry id="surface_diffuse_downwelling_photosynthetic_radiative_flux_in_air">
    <canonical_units>W m-2</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. Radiative flux is the sum of shortwave and longwave radiative fluxes. &quot;Photosynthetic&quot; radiation is the part of the spectrum which is used in photosynthesis e.g. 300-700 nm. The range of wavelengths could be specified precisely by the bounds of a coordinate of radiation_wavelength. When thought of as being incident on a surface, a radiative flux is sometimes called &quot;irradiance&quot;. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called &quot;vector irradiance&quot;. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_downward_eastward_stress">
    <canonical_units>Pa</canonical_units>
    <grib>E180</grib>
    <amip>tauu</amip>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Eastward&quot; indicates a vector component which is positive when directed eastward (negative westward). &quot;Downward&quot; indicates a vector component which is positive when directed downward (negative upward). &quot;Downward eastward&quot; indicates the ZX component of a tensor. A downward eastward stress is a downward flux of eastward momentum, which accelerates the lower medium eastward and the upper medium westward. The surface downward stress is the windstress on the surface.</description>
  </entry>
  <entry id="surface_downward_heat_flux_in_air">
    <canonical_units>W m-2</canonical_units>
    <amip>hfns</amip>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Downward&quot; 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, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_downward_heat_flux_in_sea_water">
    <canonical_units>W m-2</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Water&quot; means water in all phases, including frozen i.e. ice and snow. &quot;Downward&quot; indicates a vector component which is positive when directed downward (negative upward). In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_downward_latent_heat_flux">
    <canonical_units>W m-2</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Downward&quot; indicates a vector component which is positive when directed downward (negative upward). 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, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_downward_northward_stress">
    <canonical_units>Pa</canonical_units>
    <grib>E181</grib>
    <amip>tauv</amip>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). &quot;Downward&quot; indicates a vector component which is positive when directed downward (negative upward). &quot;Downward northward&quot; indicates the ZY component of a tensor. A downward northward stress is a downward flux of northward momentum, which accelerates the lower medium northward and the upper medium southward. The surface downward stress is the windstress on the surface.</description>
  </entry>
  <entry id="surface_downward_sensible_heat_flux">
    <canonical_units>W m-2</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Downward&quot; indicates a vector component which is positive when directed downward (negative upward). The surface sensible heat flux, also called &quot;turbulent&quot; heat flux, is the exchange of heat between the surface and the air by motion of air. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_downward_water_flux">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Water&quot; means water in all phases, including frozen i.e. ice and snow. &quot;Downward&quot; indicates a vector component which is positive when directed downward (negative upward). The surface water flux is the result of precipitation and evaporation. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_downward_x_stress">
    <canonical_units>Pa</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;x&quot; indicates a vector component along the grid x-axis, when this is not true longitude, positive with increasing x. &quot;Downward&quot; indicates a vector component which is positive when directed downward (negative upward).</description>
  </entry>
  <entry id="surface_downward_y_stress">
    <canonical_units>Pa</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;y&quot; indicates a vector component along the grid y-axis, when this is not true latitude, positive with increasing y. &quot;Downward&quot; indicates a vector component which is positive when directed downward (negative upward).</description>
  </entry>
  <entry id="surface_downwelling_longwave_flux_in_air">
    <canonical_units>W m-2</canonical_units>
    <amip>rlds</amip>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;longwave&quot; means longwave radiation. Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. When thought of as being incident on a surface, a radiative flux is sometimes called &quot;irradiance&quot;. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called &quot;vector irradiance&quot;. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_downwelling_longwave_flux_in_air_assuming_clear_sky">
    <canonical_units>W m-2</canonical_units>
    <amip>rldscs</amip>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. &quot;longwave&quot; means longwave radiation. Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. When thought of as being incident on a surface, a radiative flux is sometimes called &quot;irradiance&quot;. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called &quot;vector irradiance&quot;. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_downwelling_photon_flux_in_sea_water">
    <canonical_units>mol m-2 s-1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Water&quot; means water in all phases, including frozen i.e. ice and snow. Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. A photon flux is specified in terms of numbers of photons expressed in moles. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_downwelling_photon_radiance_in_sea_water">
    <canonical_units>mol m-2 s-1 sr-1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Water&quot; means water in all phases, including frozen i.e. ice and snow. Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. Photon radiance is the photon flux in a particular direction, per unit of solid angle. The direction from which it is coming must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead. A photon flux is specified in terms of numbers of photons expressed in moles.</description>
  </entry>
  <entry id="surface_downwelling_photon_spherical_irradiance_in_sea_water">
    <canonical_units>mol m-2 s-1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Water&quot; means water in all phases, including frozen i.e. ice and snow. Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. Photon spherical irradiance is the photon flux incident on unit area of a hemispherical (or &quot;2-pi&quot;) collector. A photon flux is specified in terms of numbers of photons expressed in moles.</description>
  </entry>
  <entry id="surface_downwelling_photosynthetic_photon_flux_in_air">
    <canonical_units>mol m-2 s-1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. &quot;Photosynthetic&quot; radiation is the part of the spectrum which is used in photosynthesis e.g. 300-700 nm. The range of wavelengths could be specified precisely by the bounds of a coordinate of radiation_wavelength. A photon flux is specified in terms of numbers of photons expressed in moles. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_downwelling_photosynthetic_photon_flux_in_sea_water">
    <canonical_units>mol m-2 s-1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Water&quot; means water in all phases, including frozen i.e. ice and snow. Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. &quot;Photosynthetic&quot; radiation is the part of the spectrum which is used in photosynthesis e.g. 300-700 nm. The range of wavelengths could be specified precisely by the bounds of a coordinate of radiation_wavelength. A photon flux is specified in terms of numbers of photons expressed in moles. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_downwelling_photosynthetic_photon_radiance_in_sea_water">
    <canonical_units>mol m-2 s-1 sr-1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Water&quot; means water in all phases, including frozen i.e. ice and snow. Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. Photon radiance is the photon flux in a particular direction, per unit of solid angle. The direction from which it is coming must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead. &quot;Photosynthetic&quot; radiation is the part of the spectrum which is used in photosynthesis e.g. 300-700 nm. The range of wavelengths could be specified precisely by the bounds of a coordinate of radiation_wavelength. A photon flux is specified in terms of numbers of photons expressed in moles.</description>
  </entry>
  <entry id="surface_downwelling_photosynthetic_photon_spherical_irradiance_in_sea_water">
    <canonical_units>mol m-2 s-1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Water&quot; means water in all phases, including frozen i.e. ice and snow. Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. &quot;Photosynthetic&quot; radiation is the part of the spectrum which is used in photosynthesis e.g. 300-700 nm. The range of wavelengths could be specified precisely by the bounds of a coordinate of radiation_wavelength. Photon spherical irradiance is the photon flux incident on unit area of a hemispherical (or &quot;2-pi&quot;) collector. A photon flux is specified in terms of numbers of photons expressed in moles.</description>
  </entry>
  <entry id="surface_downwelling_photosynthetic_radiance_in_sea_water">
    <canonical_units>W m-2 sr-1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Water&quot; means water in all phases, including frozen i.e. ice and snow. Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. Radiance is the radiative flux in a particular direction, per unit of solid angle. The direction from which it is coming must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead. &quot;Photosynthetic&quot; radiation is the part of the spectrum which is used in photosynthesis e.g. 300-700 nm. The range of wavelengths could be specified precisely by the bounds of a coordinate of radiation_wavelength.</description>
  </entry>
  <entry id="surface_downwelling_photosynthetic_radiative_flux_in_air">
    <canonical_units>W m-2</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. Radiative flux is the sum of shortwave and longwave radiative fluxes. &quot;Photosynthetic&quot; radiation is the part of the spectrum which is used in photosynthesis e.g. 300-700 nm. The range of wavelengths could be specified precisely by the bounds of a coordinate of radiation_wavelength. When thought of as being incident on a surface, a radiative flux is sometimes called &quot;irradiance&quot;. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called &quot;vector irradiance&quot;. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_downwelling_photosynthetic_radiative_flux_in_sea_water">
    <canonical_units>W m-2</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Water&quot; means water in all phases, including frozen i.e. ice and snow. Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. Radiative flux is the sum of shortwave and longwave radiative fluxes. &quot;Photosynthetic&quot; radiation is the part of the spectrum which is used in photosynthesis e.g. 300-700 nm. The range of wavelengths could be specified precisely by the bounds of a coordinate of radiation_wavelength. When thought of as being incident on a surface, a radiative flux is sometimes called &quot;irradiance&quot;. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called &quot;vector irradiance&quot;. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_downwelling_photosynthetic_spherical_irradiance_in_sea_water">
    <canonical_units>W m-2</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Water&quot; means water in all phases, including frozen i.e. ice and snow. Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. &quot;Photosynthetic&quot; radiation is the part of the spectrum which is used in photosynthesis e.g. 300-700 nm. The range of wavelengths could be specified precisely by the bounds of a coordinate of radiation_wavelength. Spherical irradiance is the radiation incident on unit area of a hemispherical (or &quot;2-pi&quot;) collector. It is sometimes called &quot;scalar irradiance&quot;. The direction (up/downwelling) is specified. Radiation incident on a 4-pi collector has standard names of &quot;omnidirectional spherical irradiance&quot;.</description>
  </entry>
  <entry id="surface_downwelling_radiance_in_sea_water">
    <canonical_units>W m-2 sr-1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Water&quot; means water in all phases, including frozen i.e. ice and snow. Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. Radiance is the radiative flux in a particular direction, per unit of solid angle. The direction from which it is coming must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead.</description>
  </entry>
  <entry id="surface_downwelling_radiative_flux_in_sea_water">
    <canonical_units>W m-2</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Water&quot; means water in all phases, including frozen i.e. ice and snow. Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. Radiative flux is the sum of shortwave and longwave radiative fluxes. When thought of as being incident on a surface, a radiative flux is sometimes called &quot;irradiance&quot;. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called &quot;vector irradiance&quot;. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_downwelling_shortwave_flux_in_air">
    <canonical_units>W m-2</canonical_units>
    <grib>117 E169</grib>
    <amip>rsds</amip>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;shortwave&quot; means shortwave radiation. Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. Surface downwelling shortwave is the sum of direct and diffuse solar radiation incident on the surface, and is sometimes called &quot;global radiation&quot;. When thought of as being incident on a surface, a radiative flux is sometimes called &quot;irradiance&quot;. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called &quot;vector irradiance&quot;. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_downwelling_shortwave_flux_in_air_assuming_clear_sky">
    <canonical_units>W m-2</canonical_units>
    <amip>rsdscs</amip>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. &quot;shortwave&quot; means shortwave radiation. Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. Surface downwelling shortwave is the sum of direct and diffuse solar radiation incident on the surface, and is sometimes called &quot;global radiation&quot;. When thought of as being incident on a surface, a radiative flux is sometimes called &quot;irradiance&quot;. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called &quot;vector irradiance&quot;. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_downwelling_spectral_photon_flux_in_sea_water">
    <canonical_units>mol m-2 s-1 m-1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Water&quot; means water in all phases, including frozen i.e. ice and snow. Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. A photon flux is specified in terms of numbers of photons expressed in moles. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_downwelling_spectral_photon_radiance_in_sea_water">
    <canonical_units>mol m-2 s-1 m-1 sr-1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Water&quot; means water in all phases, including frozen i.e. ice and snow. Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. Photon radiance is the photon flux in a particular direction, per unit of solid angle. The direction from which it is coming must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead. A photon flux is specified in terms of numbers of photons expressed in moles.</description>
  </entry>
  <entry id="surface_downwelling_spectral_photon_spherical_irradiance_in_sea_water">
    <canonical_units>mol m-2 s-1 m-1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Water&quot; means water in all phases, including frozen i.e. ice and snow. Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. &quot;spectral&quot; means per unit wavelength or as a function of wavelength; spectral quantities are sometimes called &quot;monochromatic&quot;. Radiation wavelength has standard name radiation_wavelength. Photon spherical irradiance is the photon flux incident on unit area of a hemispherical (or &quot;2-pi&quot;) collector. A photon flux is specified in terms of numbers of photons expressed in moles.</description>
  </entry>
  <entry id="surface_downwelling_spectral_radiance_in_sea_water">
    <canonical_units>W m-2 m-1 sr-1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Water&quot; means water in all phases, including frozen i.e. ice and snow. Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. &quot;spectral&quot; means per unit wavelength or as a function of wavelength; spectral quantities are sometimes called &quot;monochromatic&quot;. Radiation wavelength has standard name radiation_wavelength. Radiance is the radiative flux in a particular direction, per unit of solid angle. The direction from which it is coming must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead.</description>
  </entry>
  <entry id="surface_downwelling_spectral_radiative_flux_in_air">
    <canonical_units>W m-2 m-1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. &quot;spectral&quot; means per unit wavelength or as a function of wavelength; spectral quantities are sometimes called &quot;monochromatic&quot;. Radiation wavelength has standard name radiation_wavelength. When thought of as being incident on a surface, a radiative flux is sometimes called &quot;irradiance&quot;. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called &quot;vector irradiance&quot;. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_downwelling_spectral_radiative_flux_in_sea_water">
    <canonical_units>W m-2 m-1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Water&quot; means water in all phases, including frozen i.e. ice and snow. Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. &quot;spectral&quot; means per unit wavelength or as a function of wavelength; spectral quantities are sometimes called &quot;monochromatic&quot;. Radiation wavelength has standard name radiation_wavelength. When thought of as being incident on a surface, a radiative flux is sometimes called &quot;irradiance&quot;. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called &quot;vector irradiance&quot;. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_downwelling_spectral_spherical_irradiance_in_sea_water">
    <canonical_units>W m-2 m-1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Water&quot; means water in all phases, including frozen i.e. ice and snow. Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. &quot;spectral&quot; means per unit wavelength or as a function of wavelength; spectral quantities are sometimes called &quot;monochromatic&quot;. Radiation wavelength has standard name radiation_wavelength. Spherical irradiance is the radiation incident on unit area of a hemispherical (or &quot;2-pi&quot;) collector. It is sometimes called &quot;scalar irradiance&quot;. The direction (up/downwelling) is specified. Radiation incident on a 4-pi collector has standard names of &quot;omnidirectional spherical irradiance&quot;.</description>
  </entry>
  <entry id="surface_downwelling_spherical_irradiance_in_sea_water">
    <canonical_units>W m-2</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Water&quot; means water in all phases, including frozen i.e. ice and snow. Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. Spherical irradiance is the radiation incident on unit area of a hemispherical (or &quot;2-pi&quot;) collector. It is sometimes called &quot;scalar irradiance&quot;. The direction (up/downwelling) is specified. Radiation incident on a 4-pi collector has standard names of &quot;omnidirectional spherical irradiance&quot;.</description>
  </entry>
  <entry id="surface_drag_coefficient_for_heat_in_air">
    <canonical_units>1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere.</description>
  </entry>
  <entry id="surface_drag_coefficient_for_momentum_in_air">
    <canonical_units>1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere.</description>
  </entry>
  <entry id="surface_drag_coefficient_in_air">
    <canonical_units>1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere.</description>
  </entry>
  <entry id="surface_eastward_sea_water_velocity">
    <canonical_units>m s-1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Water&quot; means water in all phases, including frozen i.e. ice and snow. A velocity is a vector quantity. &quot;Eastward&quot; indicates a vector component which is positive when directed eastward (negative westward).</description>
  </entry>
  <entry id="surface_geopotential">
    <canonical_units>m2 s-2</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. Geopotential is the sum of the specific gravitational potential energy relative to the geoid and the specific centripetal potential energy.</description>
  </entry>
  <entry id="surface_geostrophic_eastward_sea_water_velocity">
    <canonical_units>m s-1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. A velocity is a vector quantity. &quot;Eastward&quot; indicates a vector component which is positive when directed eastward (negative westward). &quot;Geostrophic&quot; indicates that geostrophic balance is assumed. &quot;Water&quot; means water in all phases. surface_geostrophic_eastward_sea_water_velocity is the sum of a variable part, surface_geostrophic_eastward_sea_water_velocity_assuming_sea_level_for_geoid, and a constant part due to the stationary component of ocean circulation.</description>
  </entry>
  <entry id="surface_geostrophic_eastward_sea_water_velocity_assuming_sea_level_for_geoid">
    <canonical_units>m s-1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. A velocity is a vector quantity. &quot;Eastward&quot; indicates a vector component which is positive when directed eastward (negative westward). "Geostrophic" indicates that geostrophic balance is assumed. &quot;Water&quot; means water in all phases. &quot;sea_level&quot; means mean sea level. The geoid is a surface of constant geopotential with which mean sea level would coincide if the ocean were at rest. surface_geostrophic_eastward_sea_water_velocity_assuming_sea_level_for_geoid is the variable part of surface_geostrophic_eastward_sea_water_velocity. The assumption that sea level is equal to the geoid means that the stationary component of ocean circulation is equal to zero.</description>
  </entry>
  <entry id="surface_geostrophic_northward_sea_water_velocity">
    <canonical_units>m s-1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. A velocity is a vector quantity. &quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). &quot;Geostrophic&quot; indicates that geostrophic balance is assumed. &quot;Water&quot; means water in all phases. surface_geostrophic_northward_sea_water_velocity is the sum of a variable part, surface_geostrophic_northward_sea_water_velocity_assuming_sea_level_for_geoid, and a constant part due to the stationary component of ocean circulation.</description>
  </entry>
  <entry id="surface_geostrophic_northward_sea_water_velocity_assuming_sea_level_for_geoid">
    <canonical_units>m s-1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. A velocity is a vector quantity. &quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). &quot;Geostrophic&quot; indicates that geostrophic balance is assumed. &quot;Water&quot; means water in all phases. &quot;sea_level&quot; means mean sea level. The geoid is a surface of constant geopotential with which mean sea level would coincide if the ocean were at rest. surface_geostrophic_northward_sea_water_velocity_assuming_sea_level_for_geoid is the variable part of surface_geostrophic_northward_sea_water_velocity. The assumption that sea level is equal to the geoid means that the stationary component of ocean circulation is equal to zero.</description>
  </entry>
  <entry id="surface_geostrophic_sea_water_x_velocity">
    <canonical_units>m s-1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere.  A velocity is a vector quantity. &quot;x&quot; indicates a vector component along the grid x-axis, when this is not true longitude, positive with increasing x.  &quot;Geostrophic&quot; indicates that geostrophic balance is assumed.  surface_geostrophic_sea_water_x_velocity is the sum of a variable part, surface_geostrophic_sea_water_x_velocity_assuming_sea_level_for_geoid, and a constant part due to the stationary component of ocean circulation.</description>
  </entry>
  <entry id="surface_geostrophic_sea_water_x_velocity_assuming_sea_level_for_geoid">
    <canonical_units>m s-1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere.  A velocity is a vector quantity. &quot;x&quot; indicates a vector component along the grid x-axis, when this is not true longitude, positive with increasing x.  &quot;Geostrophic&quot; indicates that geostrophic balance is assumed.  &quot;sea_level&quot; means mean sea level. The geoid is a surface of constant geopotential with which mean sea level would coincide if the ocean were at rest.  surface_geostrophic_sea_water_x_velocity_assuming_sea_level_for_geoid is the variable part of surface_geostrophic_sea_water_x_velocity.  The assumption that sea level is equal to the geoid means that the stationary component of ocean circulation is equal to zero.</description>
  </entry>
  <entry id="surface_geostrophic_sea_water_y_velocity">
    <canonical_units>m s-1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere.  A velocity is a vector quantity. &quot;y&quot; indicates a vector component along the grid y-axis, when this is not true latitude, positive with increasing y.  &quot;Geostrophic&quot; indicates that geostrophic balance is assumed.  surface_geostrophic_sea_water_y_velocity is the sum of a variable part, surface_geostrophic_sea_water_y_velocity_assuming_sea_level_for_geoid, and a constant part due to the stationary component of ocean circulation.</description>
  </entry>
  <entry id="surface_geostrophic_sea_water_y_velocity_assuming_sea_level_for_geoid">
    <canonical_units>m s-1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere.  A velocity is a vector quantity. &quot;y&quot; indicates a vector component along the grid y-axis, when this is not true latitude, positive with increasing y.  &quot;Geostrophic&quot; indicates that geostrophic balance is assumed.  &quot;sea_level&quot; means mean sea level. The geoid is a surface of constant geopotential with which mean sea level would coincide if the ocean were at rest.  surface_geostrophic_sea_water_x_velocity_assuming_sea_level_for_geoid is the variable part of surface_geostrophic_sea_water_x_velocity.  The assumption that sea level is equal to the geoid means that the stationary component of ocean circulation is equal to zero.</description>
  </entry>
  <entry id="surface_net_downward_longwave_flux">
    <canonical_units>W m-2</canonical_units>
    <amip>rls</amip>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;longwave&quot; means longwave radiation. &quot;Downward&quot; indicates a vector component which is positive when directed downward (negative upward). Net downward radiation is the difference between radiation from above (downwelling) and radiation from below (upwelling). In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_net_downward_longwave_flux_assuming_clear_sky">
    <canonical_units>W m-2</canonical_units>
    <grib>E211</grib>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. &quot;longwave&quot; means longwave radiation. &quot;Downward&quot; indicates a vector component which is positive when directed downward (negative upward). Net downward radiation is the difference between radiation from above (downwelling) and radiation from below (upwelling). In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_net_downward_radiative_flux">
    <canonical_units>W m-2</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Downward&quot; indicates a vector component which is positive when directed downward (negative upward). Net downward radiation is the difference between radiation from above (downwelling) and radiation from below (upwelling). Radiative flux is the sum of shortwave and longwave radiative fluxes. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_net_downward_radiative_flux_where_land">
    <canonical_units>W m-2</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Downward&quot; indicates a vector component which is positive when directed downward (negative upward). Net downward radiation is the difference between radiation from above (downwelling) and radiation from below (upwelling). Radiative flux is the sum of shortwave and longwave radiative fluxes. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics. Unless indicated, a quantity is assumed to apply to the whole area of each horizontal grid box. The qualifier where_type specifies instead that the quantity applies only to the part of the grid box of the named type.</description>
  </entry>
  <entry id="surface_net_downward_shortwave_flux">
    <canonical_units>W m-2</canonical_units>
    <amip>rss</amip>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;shortwave&quot; means shortwave radiation. &quot;Downward&quot; indicates a vector component which is positive when directed downward (negative upward). Net downward radiation is the difference between radiation from above (downwelling) and radiation from below (upwelling). In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_net_downward_shortwave_flux_assuming_clear_sky">
    <canonical_units>W m-2</canonical_units>
    <grib>E210</grib>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. &quot;shortwave&quot; means shortwave radiation. &quot;Downward&quot; indicates a vector component which is positive when directed downward (negative upward). Net downward radiation is the difference between radiation from above (downwelling) and radiation from below (upwelling). In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_net_upward_longwave_flux">
    <canonical_units>W m-2</canonical_units>
    <grib>112 E176</grib>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;longwave&quot; means longwave radiation. &quot;Upward&quot; indicates a vector component which is positive when directed upward (negative downward). Net upward radiation is the difference between radiation from below (upwelling) and radiation from above (downwelling). In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_net_upward_radiative_flux">
    <canonical_units>W m-2</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Upward&quot; indicates a vector component which is positive when directed upward (negative downward). Net upward radiation is the difference between radiation from below (upwelling) and radiation from above (downwelling). Radiative flux is the sum of shortwave and longwave radiative fluxes. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_net_upward_shortwave_flux">
    <canonical_units>W m-2</canonical_units>
    <grib>111 E177</grib>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;shortwave&quot; means shortwave radiation. &quot;Upward&quot; indicates a vector component which is positive when directed upward (negative downward). Net upward radiation is the difference between radiation from below (upwelling) and radiation from above (downwelling). In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_northward_sea_water_velocity">
    <canonical_units>m s-1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Water&quot; means water in all phases, including frozen i.e. ice and snow. A velocity is a vector quantity. &quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward).</description>
  </entry>
  <entry id="surface_partial_pressure_of_carbon_dioxide_in_air">
    <canonical_units>Pa</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. 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.</description>
  </entry>
  <entry id="surface_partial_pressure_of_carbon_dioxide_in_sea_water">
    <canonical_units>Pa</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Water&quot; means water in all phases, including frozen i.e. ice and snow. 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.</description>
  </entry>
  <entry id="surface_roughness_length">
    <canonical_units>m</canonical_units>
    <grib>83 E173</grib>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere.</description>
  </entry>
  <entry id="surface_roughness_length_for_heat_in_air">
    <canonical_units>m</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere.</description>
  </entry>
  <entry id="surface_roughness_length_for_momentum_in_air">
    <canonical_units>m</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere.</description>
  </entry>
  <entry id="surface_runoff_amount">
    <canonical_units>kg m-2</canonical_units>
    <grib>90</grib>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Amount&quot; means mass per unit area. Runoff is the liquid water which drains from land. If not specified, &quot;runoff&quot; refers to the sum of surface runoff and subsurface drainage.</description>
  </entry>
  <entry id="surface_runoff_flux">
    <canonical_units>kg m-2 s-1</canonical_units>
    <amip>mrros</amip>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. Runoff is the liquid water which drains from land. If not specified, &quot;runoff&quot; refers to the sum of surface runoff and subsurface drainage. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_snow_amount">
    <canonical_units>kg m-2</canonical_units>
    <grib>65</grib>
    <amip>snw</amip>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Amount&quot; means mass per unit area. Surface amount refers to the amount on the ground, excluding that on the plant or vegetation canopy.</description>
  </entry>
  <entry id="surface_snow_and_ice_melt_heat_flux">
    <canonical_units>W m-2</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. The snow and ice melt heat flux is the supply of latent heat which is melting snow and ice at freezing point. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_snow_and_ice_sublimation_flux">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. Sublimation is the conversion of solid into vapor. The snow and ice sublimation  flux is the loss of snow and ice mass resulting from their conversion to water vapor. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_snow_area_fraction">
    <canonical_units>1</canonical_units>
    <amip>snc</amip>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;X_area_fraction&quot; means the fraction of horizontal area occupied by X. &quot;X_area&quot; means the horizontal area occupied by X within the grid cell.</description>
  </entry>
  <entry id="surface_snow_melt_amount">
    <canonical_units>kg m-2</canonical_units>
    <grib>99</grib>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Amount&quot; means mass per unit area.</description>
  </entry>
  <entry id="surface_snow_melt_and_sublimation_heat_flux">
    <canonical_units>W m-2 </canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. Sublimation is the conversion of solid into vapor. The snow melt and sublimation heat flux is the supply of latent heat which converting snow to liquid water (melting) and water vapor (sublimation). In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_snow_melt_flux">
    <canonical_units>kg m-2 s-1</canonical_units>
    <amip>snm</amip>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_snow_melt_heat_flux">
    <canonical_units>W m-2</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. The snow melt heat flux is the supply of latent heat which is melting snow at freezing point. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_snow_sublimation_amount">
    <canonical_units>kg m-2</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Amount&quot; means mass per unit area. Sublimation is the conversion of solid into vapor.</description>
  </entry>
  <entry id="surface_snow_sublimation_heat_flux">
    <canonical_units>W m-2</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. Sublimation is the conversion of solid into vapor. The snow sublimation heat flux is the supply of latent heat which is causing evaporation of snow to water vapor. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_snow_thickness">
    <canonical_units>m</canonical_units>
    <grib>66</grib>
    <amip>snd</amip>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere.</description>
  </entry>
  <entry id="surface_snow_thickness_where_sea_ice">
    <canonical_units>m</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. Unless indicated, a quantity is assumed to apply to the whole area of each horizontal grid box. The qualifier where_type specifies instead that the quantity applies only to the part of the grid box of the named type.</description>
  </entry>
  <entry id="surface_specific_humidity">
    <canonical_units>1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;specific&quot; means per unit mass. Specific humidity is the mass fraction of water vapor in (moist) air.</description>
  </entry>
  <entry id="surface_temperature">
    <canonical_units>K</canonical_units>
    <grib>E139</grib>
    <amip>ts</amip>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. The surface temperature is the temperature at the interface, not the bulk temperature of the medium above or below.</description>
  </entry>
  <entry id="surface_temperature_anomaly">
    <canonical_units>K</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;anomaly&quot; means difference from climatology. The surface temperature is the (skin) temperature at the interface, not the bulk temperature of the medium above or below.</description>
  </entry>
  <entry id="surface_temperature_where_land">
    <canonical_units>K</canonical_units>
    <description>Unless indicated, a quantity is assumed to apply to the whole area of each horizontal grid box. The qualifier where_type specifies instead that the quantity applies only to the part of the grid box of the named type. The surface temperature is the (skin) temperature at the interface, not the bulk temperature of the medium above or below.</description>
  </entry>
  <entry id="surface_temperature_where_open_sea">
    <canonical_units>K</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. Unless indicated, a quantity is assumed to apply to the whole area of each horizontal grid box. The qualifier where_type specifies instead that the quantity applies only to the part of the grid box of the named type. The surface temperature is the (skin) temperature at the interface, not the bulk temperature of the medium above or below.</description>
  </entry>
  <entry id="surface_temperature_where_snow">
    <canonical_units>K</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. Unless indicated, a quantity is assumed to apply to the whole area of each horizontal grid box. The qualifier where_type specifies instead that the quantity applies only to the part of the grid box of the named type. The surface temperature is the (skin) temperature at the interface, not the bulk temperature of the medium above or below.</description>
  </entry>
  <entry id="surface_upward_heat_flux_in_air">
    <canonical_units>W m-2</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Upward&quot; indicates a vector component which is positive when directed upward (negative downward). 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, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_upward_latent_heat_flux">
    <canonical_units>W m-2</canonical_units>
    <grib>121 E147</grib>
    <amip>hfls</amip>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Upward&quot; 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, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_upward_sensible_heat_flux">
    <canonical_units>W m-2</canonical_units>
    <grib>122 E146</grib>
    <amip>hfss</amip>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Upward&quot; indicates a vector component which is positive when directed upward (negative downward). The surface sensible heat flux, also called &quot;turbulent&quot; heat flux, is the exchange of heat between the surface and the air by motion of air. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_upward_sensible_heat_flux_where_sea">
    <canonical_units>W m-2</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. Unless indicated, a quantity is assumed to apply to the whole area of each horizontal grid box. The qualifier where_type specifies instead that the quantity applies only to the part of the grid box of the named type. &quot;Upward&quot; indicates a vector component which is positive when directed upward (negative downward). The surface sensible heat flux, also called &quot;turbulent&quot; heat flux, is the exchange of heat between the surface and the air by motion of air. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_upward_water_flux">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Water&quot; means water in all phases, including frozen i.e. ice and snow. &quot;Upward&quot; indicates a vector component which is positive when directed upward (negative downward). The surface water flux is the result of precipitation and evaporation. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_upward_water_vapor_flux_in_air">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere.  &quot;Upward&quot; indicates a vector component which is positive when directed upward (negative downward).  In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_upwelling_longwave_flux_in_air">
    <canonical_units>W m-2</canonical_units>
    <amip>rlus</amip>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;longwave&quot; means longwave radiation. Upwelling radiation is radiation from below. It does not mean &quot;net upward&quot;. When thought of as being incident on a surface, a radiative flux is sometimes called &quot;irradiance&quot;. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called &quot;vector irradiance&quot;. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_upwelling_longwave_flux_in_air_assuming_clear_sky">
    <canonical_units>W m-2</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. &quot;longwave&quot; means longwave radiation. Upwelling radiation is radiation from below. It does not mean &quot;net upward&quot;. When thought of as being incident on a surface, a radiative flux is sometimes called &quot;irradiance&quot;. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called &quot;vector irradiance&quot;. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_upwelling_photosynthetic_photon_flux_in_air">
    <canonical_units>mol m-2 s-1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. Upwelling radiation is radiation from below. It does not mean &quot;net upward&quot;. &quot;Photosynthetic&quot; radiation is the part of the spectrum which is used in photosynthesis e.g. 300-700 nm. The range of wavelengths could be specified precisely by the bounds of a coordinate of radiation_wavelength. A photon flux is specified in terms of numbers of photons expressed in moles. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_upwelling_radiance_in_air">
    <canonical_units>W m-2 sr-1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. Upwelling radiation is radiation from below. It does not mean &quot;net upward&quot;. Radiance is the radiative flux in a particular direction, per unit of solid angle. The direction towards which it is going must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead.</description>
  </entry>
  <entry id="surface_upwelling_radiance_in_air_emerging_from_sea_water">
    <canonical_units>W m-2 sr-1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Water&quot; means water in all phases, including frozen i.e. ice and snow. Upwelling radiation is radiation from below. It does not mean &quot;net upward&quot;. Radiance is the radiative flux in a particular direction, per unit of solid angle. The direction towards which it is going must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead.</description>
  </entry>
  <entry id="surface_upwelling_radiance_in_air_reflected_by_sea_water">
    <canonical_units>W m-2 sr-1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Water&quot; means water in all phases, including frozen i.e. ice and snow. Upwelling radiation is radiation from below. It does not mean &quot;net upward&quot;. Radiance is the radiative flux in a particular direction, per unit of solid angle. The direction towards which it is going must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead.</description>
  </entry>
  <entry id="surface_upwelling_radiance_in_sea_water">
    <canonical_units>W m-2 sr-1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Water&quot; means water in all phases, including frozen i.e. ice and snow. Upwelling radiation is radiation from below. It does not mean &quot;net upward&quot;. Radiance is the radiative flux in a particular direction, per unit of solid angle. The direction towards which it is going must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead.</description>
  </entry>
  <entry id="surface_upwelling_shortwave_flux_in_air">
    <canonical_units>W m-2</canonical_units>
    <amip>rsus</amip>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;shortwave&quot; means shortwave radiation. Upwelling radiation is radiation from below. It does not mean &quot;net upward&quot;. When thought of as being incident on a surface, a radiative flux is sometimes called &quot;irradiance&quot;. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called &quot;vector irradiance&quot;. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_upwelling_shortwave_flux_in_air_assuming_clear_sky">
    <canonical_units>W m-2</canonical_units>
    <amip>rsuscs</amip>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. &quot;shortwave&quot; means shortwave radiation. Upwelling radiation is radiation from below. It does not mean &quot;net upward&quot;. When thought of as being incident on a surface, a radiative flux is sometimes called &quot;irradiance&quot;. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called &quot;vector irradiance&quot;. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_upwelling_spectral_radiance_in_air">
    <canonical_units>W m-2 m-1 sr-1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. Upwelling radiation is radiation from below. It does not mean &quot;net upward&quot;. &quot;spectral&quot; means per unit wavelength or as a function of wavelength; spectral quantities are sometimes called &quot;monochromatic&quot;. Radiation wavelength has standard name radiation_wavelength. Radiance is the radiative flux in a particular direction, per unit of solid angle. The direction towards which it is going must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead.</description>
  </entry>
  <entry id="surface_upwelling_spectral_radiance_in_air_emerging_from_sea_water">
    <canonical_units>W m-2 m-1 sr-1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Water&quot; means water in all phases, including frozen i.e. ice and snow. Upwelling radiation is radiation from below. It does not mean &quot;net upward&quot;. &quot;spectral&quot; means per unit wavelength or as a function of wavelength; spectral quantities are sometimes called &quot;monochromatic&quot;. Radiation wavelength has standard name radiation_wavelength. Radiance is the radiative flux in a particular direction, per unit of solid angle. The direction towards which it is going must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead.</description>
  </entry>
  <entry id="surface_upwelling_spectral_radiance_in_air_reflected_by_sea_water">
    <canonical_units>W m-2 m-1 sr-1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Water&quot; means water in all phases, including frozen i.e. ice and snow. Upwelling radiation is radiation from below. It does not mean &quot;net upward&quot;. &quot;spectral&quot; means per unit wavelength or as a function of wavelength; spectral quantities are sometimes called &quot;monochromatic&quot;. Radiation wavelength has standard name radiation_wavelength. Radiance is the radiative flux in a particular direction, per unit of solid angle. The direction towards which it is going must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead.</description>
  </entry>
  <entry id="surface_upwelling_spectral_radiance_in_sea_water">
    <canonical_units>W m-2 m-1 sr-1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Water&quot; means water in all phases, including frozen i.e. ice and snow. Upwelling radiation is radiation from below. It does not mean &quot;net upward&quot;. &quot;spectral&quot; means per unit wavelength or as a function of wavelength; spectral quantities are sometimes called &quot;monochromatic&quot;. Radiation wavelength has standard name radiation_wavelength. Radiance is the radiative flux in a particular direction, per unit of solid angle. The direction towards which it is going must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead.</description>
  </entry>
  <entry id="surface_upwelling_spectral_radiative_flux_in_air">
    <canonical_units>W m-2 m-1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. Upwelling radiation is radiation from below. It does not mean &quot;net upward&quot;. &quot;spectral&quot; means per unit wavelength or as a function of wavelength; spectral quantities are sometimes called &quot;monochromatic&quot;. Radiation wavelength has standard name radiation_wavelength. When thought of as being incident on a surface, a radiative flux is sometimes called &quot;irradiance&quot;. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called &quot;vector irradiance&quot;. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_upwelling_spectral_radiative_flux_in_sea_water">
    <canonical_units>W m-2 m-1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Water&quot; means water in all phases, including frozen i.e. ice and snow. Upwelling radiation is radiation from below. It does not mean &quot;net upward&quot;. &quot;spectral&quot; means per unit wavelength or as a function of wavelength; spectral quantities are sometimes called &quot;monochromatic&quot;. Radiation wavelength has standard name radiation_wavelength. When thought of as being incident on a surface, a radiative flux is sometimes called &quot;irradiance&quot;. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called &quot;vector irradiance&quot;. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="surface_water_amount">
    <canonical_units>kg m-2</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;Amount&quot; means mass per unit area. &quot;Water&quot; means water in all phases, including frozen i.e. ice and snow. Surface amount refers to the amount on the ground, excluding that on the plant or vegetation canopy.</description>
  </entry>
  <entry id="temperature_of_sensor_for_oxygen_in_sea_water">
    <canonical_units>K</canonical_units>
    <description>Temperature_of_sensor_for_oxygen_in_sea_water is the instrument temperature used in calculating the concentration of oxygen in sea water; it is not a measurement of the ambient water temperature.</description>
  </entry>
  <entry id="tendency_of_air_density">
    <canonical_units>kg m-3 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.</description>
  </entry>
  <entry id="tendency_of_air_pressure">
    <canonical_units>Pa s-1</canonical_units>
    <grib>3</grib>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.</description>
  </entry>
  <entry id="tendency_of_air_temperature">
    <canonical_units>K s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time. Air temperature is the bulk temperature of the air, not the surface (skin) temperature.</description>
  </entry>
  <entry id="tendency_of_air_temperature_due_to_advection">
    <canonical_units>K s-1</canonical_units>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. Air temperature is the bulk temperature of the air, not the surface (skin) temperature.</description>
  </entry>
  <entry id="tendency_of_air_temperature_due_to_diabatic_processes">
    <canonical_units>K s-1</canonical_units>
    <amip>tnt</amip>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. Air temperature is the bulk temperature of the air, not the surface (skin) temperature.</description>
  </entry>
  <entry id="tendency_of_air_temperature_due_to_diffusion">
    <canonical_units>K s-1</canonical_units>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. Air temperature is the bulk temperature of the air, not the surface (skin) temperature.</description>
  </entry>
  <entry id="tendency_of_air_temperature_due_to_dry_convection">
    <canonical_units>K s-1</canonical_units>
    <amip>tntdc</amip>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. Air temperature is the bulk temperature of the air, not the surface (skin) temperature.</description>
  </entry>
  <entry id="tendency_of_air_temperature_due_to_large_scale_precipitation">
    <canonical_units>K s-1</canonical_units>
    <amip>tntlsp</amip>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. Air temperature is the bulk temperature of the air, not the surface (skin) temperature.</description>
  </entry>
  <entry id="tendency_of_air_temperature_due_to_longwave_heating">
    <canonical_units>K s-1</canonical_units>
    <amip>tntlw</amip>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;longwave&quot; means longwave radiation. Air temperature is the bulk temperature of the air, not the surface (skin) temperature.</description>
  </entry>
  <entry id="tendency_of_air_temperature_due_to_longwave_heating_assuming_clear_sky">
    <canonical_units>K s-1</canonical_units>
    <description>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 phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. &quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;longwave&quot; means longwave radiation. Air temperature is the bulk temperature of the air, not the surface (skin) temperature.</description>
  </entry>
  <entry id="tendency_of_air_temperature_due_to_moist_convection">
    <canonical_units>K s-1</canonical_units>
    <amip>tntmc</amip>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. Air temperature is the bulk temperature of the air, not the surface (skin) temperature.</description>
  </entry>
  <entry id="tendency_of_air_temperature_due_to_radiative_heating">
    <canonical_units>K s-1</canonical_units>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. Air temperature is the bulk temperature of the air, not the surface (skin) temperature.</description>
  </entry>
  <entry id="tendency_of_air_temperature_due_to_shortwave_heating">
    <canonical_units>K s-1</canonical_units>
    <amip>tntsw</amip>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;shortwave&quot; means shortwave radiation. Air temperature is the bulk temperature of the air, not the surface (skin) temperature.</description>
  </entry>
  <entry id="tendency_of_air_temperature_due_to_shortwave_heating_assuming_clear_sky">
    <canonical_units>K s-1</canonical_units>
    <description>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 phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. &quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;shortwave&quot; means shortwave radiation. Air temperature is the bulk temperature of the air, not the surface (skin) temperature.</description>
  </entry>
  <entry id="tendency_of_air_temperature_due_to_turbulence">
    <canonical_units>K s-1</canonical_units>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. Air temperature is the bulk temperature of the air, not the surface (skin) temperature.</description>
  </entry>
  <entry id="tendency_of_atmosphere_dry_energy_content">
    <canonical_units>W m-2</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;Content&quot; indicates a quantity per unit area. The &quot;atmosphere content&quot; of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. Dry energy is the sum of dry static energy and kinetic energy. Dry static energy is the sum of enthalpy and potential energy (itself the sum of gravitational and centripetal potential energy). Enthalpy can be written either as (1) CpT, where Cp is heat capacity at constant pressure, T is absolute temperature, or (2) U+pV, where U is internal energy, p is pressure and V is volume.</description>
  </entry>
  <entry id="tendency_of_atmosphere_enthalpy_content_due_to_advection">
    <canonical_units>W m-2</canonical_units>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;Content&quot; indicates a quantity per unit area. The &quot;atmosphere content&quot; of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. Enthalpy can be written either as (1) CpT, where Cp is heat capacity at constant pressure, T is absolute temperature, or (2) U+pV, where U is internal energy, p is pressure and V is volume.</description>
  </entry>
  <entry id="tendency_of_atmosphere_kinetic_energy_content_due_to_advection">
    <canonical_units>W m-2</canonical_units>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;Content&quot; indicates a quantity per unit area. The &quot;atmosphere content&quot; of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_alpha_hexachlorocyclohexane_due_to_dry_deposition">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Dry deposition&quot; means gravitational settling, impact scavenging and turbulent deposition.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_alpha_hexachlorocyclohexane_due_to_emission">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;Content&quot; indicates a quantity per unit area.  &quot;Emission&quot; means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface).  &quot;Emission&quot; is a process entirely distinct from &quot;re-emission&quot; which is used in some standard names.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_alpha_hexachlorocyclohexane_due_to_re_emission">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Re-emission&quot; refers to emission that is not from a primary source; it refers to emission of a species that has previously been deposited and accumulated in soils or water.  &quot;Re-emission&quot; is a process entirely distinct from &quot;emission&quot; which is used in some standard names.
</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_alpha_hexachlorocyclohexane_due_to_wet_deposition">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Wet deposition&quot; means deposition by precipitation.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_ammonia_due_to_dry_deposition">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Dry deposition&quot; means gravitational settling, impact scavenging and turbulent deposition.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_ammonia_due_to_emission">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Emission&quot; means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface).  &quot;Emission&quot; is a process entirely distinct from &quot;re-emission&quot; which is used in some standard names.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_ammonia_due_to_wet_deposition">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Wet deposition&quot; means deposition by precipitation.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_black_carbon_dry_aerosol_due_to_dry_deposition">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets).  Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. &quot;Dry aerosol&quot; means aerosol without water.  Black carbon aerosol is composed of elemental carbon.  It is strongly light absorbing.  &quot;Dry deposition&quot; means gravitational settling, impact scavenging and turbulent deposition.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_black_carbon_dry_aerosol_due_to_emission">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets).  Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. &quot;Dry aerosol&quot; means aerosol without water.  Black carbon aerosol is composed of elemental carbon.  It is strongly light absorbing.  &quot;Emission&quot; means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface).  &quot;Emission&quot; is a process entirely distinct from &quot;re-emission&quot; which is used in some standard names.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_black_carbon_dry_aerosol_due_to_wet_deposition">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets).  Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. &quot;Dry aerosol&quot; means aerosol without water.  Black carbon aerosol is composed of elemental carbon.  It is strongly light absorbing.  &quot;Wet deposition&quot; means deposition by precipitation.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_carbon_monoxide_due_to_emission">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Emission&quot; means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface).  &quot;Emission&quot; is a process entirely distinct from &quot;re-emission&quot; which is used in some standard names.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_dimethyl_sulfide_due_to_dry_deposition">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Dry deposition&quot; means gravitational settling, impact scavenging and turbulent deposition.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_dimethyl_sulfide_due_to_emission">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Emission&quot; means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface).  &quot;Emission&quot; is a process entirely distinct from &quot;re-emission&quot; which is used in some standard names.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_dimethyl_sulfide_due_to_wet_deposition">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Wet deposition&quot; means deposition by precipitation.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_due_to_dry_deposition">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets).  Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. &quot;Dry aerosol&quot; means aerosol without water.  &quot;Dry deposition&quot; means gravitational settling, impact scavenging and turbulent deposition.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_due_to_emission">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets).  Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. &quot;Dry aerosol&quot; means aerosol without water.  &quot;Emission&quot; means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface).  &quot;Emission&quot; is a process entirely distinct from &quot;re-emission&quot; which is used in some standard names.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_dust_dry_aerosol_due_to_wet_deposition">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets).  Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. &quot;Dry aerosol&quot; means aerosol without water.  &quot;Wet deposition&quot; means deposition by precipitation.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_gaseous_divalent_mercury_due_to_dry_deposition">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Divalent mercury&quot; means all compounds in which the mercury has two binding sites to other ion(s) in a salt or to other atom(s) in a molecule.  &quot;Dry deposition&quot; means gravitational settling, impact scavenging and turbulent deposition.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_gaseous_divalent_mercury_due_to_emission">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Divalent mercury&quot; means all compounds in which the mercury has two binding sites to other ion(s) in a salt or to other atom(s) in a molecule.  &quot;Emission&quot; means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface).  &quot;Emission&quot; is a process entirely distinct from &quot;re-emission&quot; which is used in some standard names.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_gaseous_divalent_mercury_due_to_wet_deposition">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Divalent mercury&quot; means all compounds in which the mercury has two binding sites to other ion(s) in a salt or to other atom(s) in a molecule.  &quot;Wet deposition&quot; means deposition by precipitation.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_gaseous_elemental_mercury_due_to_dry_deposition">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Dry deposition&quot; means gravitational settling, impact scavenging and turbulent deposition.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_gaseous_elemental_mercury_due_to_emission">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Emission&quot; means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface).  &quot;Emission&quot; is a process entirely distinct from &quot;re-emission&quot; which is used in some standard names.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_gaseous_elemental_mercury_due_to_wet_deposition">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Wet deposition&quot; means deposition by precipitation.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_hexachlorobiphenyl_due_to_dry_deposition">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Dry deposition&quot; means gravitational settling, impact scavenging and turbulent deposition.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_hexachlorobiphenyl_due_to_emission">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Emission&quot; means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface).  &quot;Emission&quot; is a process entirely distinct from &quot;re-emission&quot; which is used in some standard names.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_hexachlorobiphenyl_due_to_re_emission">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Re-emission&quot; refers to emission that is not from a primary source; it refers to emission of a species that has previously been deposited and accumulated in soils or water.  &quot;Re-emission&quot; is a process entirely distinct from &quot;emission&quot; which is used in some standard names.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_hexachlorobiphenyl_due_to_wet_deposition">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Wet deposition&quot; means deposition by precipitation.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_mercury_dry_aerosol_due_to_dry_deposition">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets).  Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. &quot;Dry aerosol&quot; means aerosol without water.  &quot;Dry deposition&quot; means gravitational settling, impact scavenging and turbulent deposition.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_mercury_dry_aerosol_due_to_emission">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets).  Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. &quot;Dry aerosol&quot; means aerosol without water. &quot;Emission&quot; means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface).  &quot;Emission&quot; is a process entirely distinct from &quot;re-emission&quot; which is used in some standard names.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_mercury_dry_aerosol_due_to_wet_deposition">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets).  Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. &quot;Dry aerosol&quot; means aerosol without water.  &quot;Wet deposition&quot; means deposition by precipitation.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_nitric_acid_due_to_dry_deposition">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Dry deposition&quot; means gravitational settling, impact scavenging and turbulent deposition.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_nitric_acid_due_to_wet_deposition">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Wet deposition&quot; means deposition by precipitation.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_nitrogen_dioxide_due_to_dry_deposition">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Dry deposition&quot; means gravitational settling, impact scavenging and turbulent deposition.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_nox_expressed_as_nitrogen_due_to_emission">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Nox&quot; means nitric oxide (NO) and nitrogen dioxide (NO2). &quot;Emission&quot; means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface).  &quot;Emission&quot; is a process entirely distinct from &quot;re-emission&quot; which is used in some standard names.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_ozone_due_to_dry_deposition">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Dry deposition&quot; means gravitational settling, impact scavenging and turbulent deposition.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_ozone_due_to_dry_deposition_into_stomata">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Dry deposition&quot; means gravitational settling, impact scavenging and turbulent deposition.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_due_to_dry_deposition">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets).  Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. &quot;Dry aerosol&quot; means aerosol without water.  &quot;particulate_organic_matter_dry_aerosol&quot; means all particulate organic matter dry aerosol except black carbon.  It is the sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol.  &quot;Dry deposition&quot; means gravitational settling, impact scavenging and turbulent deposition.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_due_to_net_production_and_emission">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets).  Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. &quot;Dry aerosol&quot; means aerosol without water.  &quot;Net production&quot; means the net result of all chemical reactions within the atmosphere that produce or destroy a particular species. &quot;Emission&quot; means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface).  &quot;Emission&quot; is a process entirely distinct from &quot;re-emission&quot; which is used in some standard names.  &quot;particulate_organic_matter_dry_aerosol&quot; means all particulate organic matter dry aerosol except black carbon.  It is the sum of primary_particulate_organic_matter_dry_aerosol (which is emitted into the atmosphere) and secondary_particulate_organic_matter_dry_aerosol (which is produced within the atmosphere).  </description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_particulate_organic_matter_dry_aerosol_due_to_wet_deposition">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets).  Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. &quot;Dry aerosol&quot; means aerosol without water.  &quot;particulate_organic_matter_dry_aerosol&quot; means all particulate organic matter dry aerosol except black carbon.  It is the sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol.  &quot;Wet deposition&quot; means deposition by precipitation.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_primary_particulate_organic_matter_dry_aerosol_due_to_dry_deposition">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets).  Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. &quot;Dry aerosol&quot; means aerosol without water.  &quot;Primary particulate organic matter &quot; means all organic matter emitted directly to the atmosphere as particles except black carbon.  The sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol is particulate_organic_matter_dry_aerosol.  &quot;Dry deposition&quot; means gravitational settling, impact scavenging and turbulent deposition.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_primary_particulate_organic_matter_dry_aerosol_due_to_emission">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets).  Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. &quot;Dry aerosol&quot; means aerosol without water.  &quot;Primary particulate organic matter &quot; means all organic matter emitted directly to the atmosphere as particles except black carbon.  The sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol is particulate_organic_matter_dry_aerosol.  &quot;Emission&quot; means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface).  &quot;Emission&quot; is a process entirely distinct from &quot;re-emission&quot; which is used in some standard names.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_primary_particulate_organic_matter_dry_aerosol_due_to_wet_deposition">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets).  Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. &quot;Dry aerosol&quot; means aerosol without water.  &quot;Primary particulate organic matter &quot; means all organic matter emitted directly to the atmosphere as particles except black carbon.  The sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol is particulate_organic_matter_dry_aerosol.  &quot;Wet deposition&quot; means deposition by precipitation.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_seasalt_dry_aerosol_due_to_dry_deposition">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets).  Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. &quot;Dry aerosol&quot; means aerosol without water.  &quot;Dry deposition&quot; means gravitational settling, impact scavenging and turbulent deposition.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_seasalt_dry_aerosol_due_to_emission">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets).  Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. &quot;Dry aerosol&quot; means aerosol without water.  located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface).  &quot;Emission&quot; is a process entirely distinct from &quot;re-emission&quot; which is used in some standard names.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_seasalt_dry_aerosol_due_to_wet_deposition">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets).  Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. &quot;Dry aerosol&quot; means aerosol without water.  &quot;Wet deposition&quot; means deposition by precipitation.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_secondary_particulate_organic_matter_dry_aerosol_due_to_dry_deposition">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets).  Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. &quot;Dry aerosol&quot; means aerosol without water.  &quot;Secondary particulate organic matter &quot; means particulate organic matter formed within the atmosphere from gaseous precursors.  The sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol is particulate_organic_matter_dry_aerosol.  &quot;Dry deposition&quot; means gravitational settling, impact scavenging and turbulent deposition.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_secondary_particulate_organic_matter_dry_aerosol_due_to_net_production">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets).  Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. &quot;Dry aerosol&quot; means aerosol without water.  &quot;Secondary particulate organic matter &quot; means particulate organic matter formed within the atmosphere from gaseous precursors.  The sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol is particulate_organic_matter_dry_aerosol.  &quot;Net production&quot; means the net result of all chemical reactions within the atmosphere that produce or destroy a particular species.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_secondary_particulate_organic_matter_dry_aerosol_due_to_wet_deposition">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Aerosol&quot; means the suspended liquid or solid particles in air (except cloud droplets).  Aerosol takes up ambient water (a process known as hygroscopic growth) depending on the relative humidity and the composition of the aerosol. &quot;Dry aerosol&quot; means aerosol without water.  &quot;Secondary particulate organic matter &quot; means particulate organic matter formed within the atmosphere from gaseous precursors.  The sum of primary_particulate_organic_matter_dry_aerosol and secondary_particulate_organic_matter_dry_aerosol is particulate_organic_matter_dry_aerosol.  &quot;Wet deposition&quot; means deposition by precipitation.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_dry_deposition">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Dry deposition&quot; means gravitational settling, impact scavenging and turbulent deposition.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_emission">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Emission&quot; means emission from a primary source located anywhere within the atmosphere, including at the lower boundary (i.e. earth's surface).  &quot;Emission&quot; is a process entirely distinct from &quot;re-emission&quot; which is used in some standard names.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_content_of_sulfur_dioxide_due_to_wet_deposition">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Content&quot; indicates a quantity per unit area.  &quot;Wet deposition&quot; means deposition by precipitation.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_per_unit_area">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;X_area&quot; means the horizontal area occupied by X within the grid cell.</description>
  </entry>
  <entry id="tendency_of_atmosphere_mass_per_unit_area_due_to_advection">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;X_area&quot; means the horizontal area occupied by X within the grid cell.</description>
  </entry>
  <entry id="tendency_of_atmosphere_potential_energy_content_due_to_advection">
    <canonical_units>W m-2</canonical_units>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;Content&quot; indicates a quantity per unit area. The &quot;atmosphere content&quot; of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. 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.)</description>
  </entry>
  <entry id="tendency_of_atmosphere_water_content_due_to_advection">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;Content&quot; indicates a quantity per unit area. The &quot;atmosphere content&quot; of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. &quot;Water&quot; means water in all phases.</description>
  </entry>
  <entry id="tendency_of_atmosphere_water_vapor_content">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;Content&quot; indicates a quantity per unit area. The &quot;atmosphere content&quot; of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. Atmosphere water vapor content is sometimes referred to as &quot;precipitable water&quot;, although this term does not imply the water could all be precipitated.</description>
  </entry>
  <entry id="tendency_of_atmosphere_water_vapor_content_due_to_advection">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;Content&quot; indicates a quantity per unit area. The &quot;atmosphere content&quot; of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. Atmosphere water vapor content is sometimes referred to as &quot;precipitable water&quot;, although this term does not imply the water could all be precipitated.</description>
  </entry>
  <entry id="tendency_of_atmosphere_water_vapor_content_due_to_convection">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;Content&quot; indicates a quantity per unit area. The &quot;atmosphere content&quot; of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. Atmosphere water vapor content is sometimes referred to as &quot;precipitable water&quot;, although this term does not imply the water could all be precipitated.</description>
  </entry>
  <entry id="tendency_of_atmosphere_water_vapor_content_due_to_deep_convection">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;Content&quot; indicates a quantity per unit area. The &quot;atmosphere content&quot; of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. Atmosphere water vapor content is sometimes referred to as &quot;precipitable water&quot;, although this term does not imply the water could all be precipitated.</description>
  </entry>
  <entry id="tendency_of_atmosphere_water_vapor_content_due_to_shallow_convection">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;Content&quot; indicates a quantity per unit area. The &quot;atmosphere content&quot; of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. Atmosphere water vapor content is sometimes referred to as &quot;precipitable water&quot;, although this term does not imply the water could all be precipitated.</description>
  </entry>
  <entry id="tendency_of_atmosphere_water_vapor_content_due_to_turbulence">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;Content&quot; indicates a quantity per unit area. The &quot;atmosphere content&quot; of a quantity refers to the vertical integral from the surface to the top of the atmosphere. For the content between specified levels in the atmosphere, standard names including content_of_atmosphere_layer are used. Atmosphere water vapor content is sometimes referred to as &quot;precipitable water&quot;, although this term does not imply the water could all be precipitated.</description>
  </entry>
  <entry id="tendency_of_bedrock_altitude">
    <canonical_units>m s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time. Altitude is the (geometric) height above the geoid, which is the reference geopotential surface. The geoid is similar to mean sea level. &quot;Bedrock&quot; is the solid Earth surface beneath land ice or ocean water.</description>
  </entry>
  <entry id="tendency_of_dry_energy_content_of_atmosphere_layer">
    <canonical_units>W m-2</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;Content&quot; indicates a quantity per unit area. &quot;Layer&quot; 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. Dry energy is the sum of dry static energy and kinetic energy. Dry static energy is the sum of enthalpy and potential energy (itself the sum of gravitational and centripetal potential energy). Enthalpy can be written either as (1) CpT, where Cp is heat capacity at constant pressure, T is absolute temperature, or (2) U+pV, where U is internal energy, p is pressure and V is volume.</description>
  </entry>
  <entry id="tendency_of_dry_static_energy_content_of_atmosphere_layer">
    <canonical_units>W m-2</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;Content&quot; indicates a quantity per unit area. &quot;Layer&quot; 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. Dry static energy is the sum of enthalpy and potential energy (itself the sum of gravitational and centripetal potential energy). Enthalpy can be written either as (1) CpT, where Cp is heat capacity at constant pressure, T is absolute temperature, or (2) U+pV, where U is internal energy, p is pressure and V is volume.</description>
  </entry>
  <entry id="tendency_of_eastward_wind">
    <canonical_units>m s-2</canonical_units>
    <amip>tnmmutot</amip>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;Eastward&quot; indicates a vector component which is positive when directed eastward (negative westward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)</description>
  </entry>
  <entry id="tendency_of_eastward_wind_due_to_advection">
    <canonical_units>m s-2</canonical_units>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;Eastward&quot; indicates a vector component which is positive when directed eastward (negative westward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)</description>
  </entry>
  <entry id="tendency_of_eastward_wind_due_to_convection">
    <canonical_units>m s-2</canonical_units>
    <amip>tnmmuc</amip>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;Eastward&quot; indicates a vector component which is positive when directed eastward (negative westward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)</description>
  </entry>
  <entry id="tendency_of_eastward_wind_due_to_diffusion">
    <canonical_units>m s-2</canonical_units>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;Eastward&quot; indicates a vector component which is positive when directed eastward (negative westward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)</description>
  </entry>
  <entry id="tendency_of_eastward_wind_due_to_eliassen_palm_flux_divergence">
    <canonical_units>m s-2</canonical_units>
    <description>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. &quot;Eastward&quot; indicates a vector component which is positive when directed eastward (negative westward).  &quot;Eliassen Palm flux&quot; is a widely used vector in the meridional plane, and the divergence of this flux appears as a forcing in the Transformed Eulerian mean formulation of the zonal mean zonal wind equation.  Thus, &quot;eastward_wind&quot; here will generally be the zonally averaged eastward wind.</description>
  </entry>
  <entry id="tendency_of_eastward_wind_due_to_gravity_wave_drag">
    <canonical_units>m s-2</canonical_units>
    <amip>tnmmugwd</amip>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;Eastward&quot; indicates a vector component which is positive when directed eastward (negative westward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)  The quantity named tendency_of_eastward_wind_due_to_gravity_wave_drag is the sum of the tendencies due to orographic and nonorographic gravity waves which have standard names of tendency_of_eastward_wind_due_to_orographic_gravity_wave_drag and tendency_of_eastward_wind_due_to_nonorographic_gravity_wave_drag, respectively.</description>
  </entry>
  <entry id="tendency_of_eastward_wind_due_to_nonorographic_gravity_wave_drag">
    <canonical_units>m s-2</canonical_units>
    <description>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. &quot;Eastward&quot; indicates a vector component which is positive when directed eastward (negative westward).  The total tendency of the eastward wind due to gravity waves has the standard name tendency_of_eastward_wind_due_to_gravity_wave_drag.  It is the sum of the tendencies due to orographic gravity waves and nonorographic waves.  The tendency of eastward wind due to orographic gravity waves has the standard name tendency_of_eastward_wind_due_to_orographic_gravity_wave_drag.</description>
  </entry>
  <entry id="tendency_of_eastward_wind_due_to_numerical_artefacts">
    <canonical_units>m s-2</canonical_units>
    <description>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. &quot;Eastward&quot; indicates a vector component which is positive when directed eastward (negative westward).  The total tendency of the eastward wind will include a variety of numerical and diffusive effects: a variable with this standard name is sometimes needed to allow the momentum budget to be closed.</description>
  </entry>
  <entry id="tendency_of_eastward_wind_due_to_orographic_gravity_wave_drag">
    <canonical_units>m s-2</canonical_units>
    <description>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. &quot;Eastward&quot; indicates a vector component which is positive when directed eastward (negative westward).  The total tendency of the eastward wind due to gravity waves has the standard name tendency_of_eastward_wind_due_to_gravity_wave_drag.  It is the sum of the tendencies due to orographic gravity waves and nonorographic waves.  The tendency of eastward wind due to nonorographic gravity waves has the standard name tendency_of_eastward_wind_due_to_nonorographic_gravity_wave_drag.</description>
  </entry>
  <entry id="tendency_of_enthalpy_content_of_atmosphere_layer_due_to_advection">
    <canonical_units>W m-2</canonical_units>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;Content&quot; indicates a quantity per unit area. &quot;Layer&quot; 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. Enthalpy can be written either as (1) CpT, where Cp is heat capacity at constant pressure, T is absolute temperature, or (2) U+pV, where U is internal energy, p is pressure and V is volume.</description>
  </entry>
  <entry id="tendency_of_kinetic_energy_content_of_atmosphere_layer_due_to_advection">
    <canonical_units>W m-2</canonical_units>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;Content&quot; indicates a quantity per unit area. &quot;Layer&quot; 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.</description>
  </entry>
  <entry id="tendency_of_land_ice_thickness">
    <canonical_units>m s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;Land ice&quot; means glaciers, ice-caps and ice-sheets resting on bedrock.</description>
  </entry>
  <entry id="tendency_of_mass_fraction_of_cloud_condensed_water_in_air">
    <canonical_units>s-1</canonical_units>
    <description>&quot;Tendency_of_X&quot; means derivative of X with respect to time. 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).  &quot;Condensed_water&quot; means liquid and ice.</description>
  </entry>
  <entry id="tendency_of_mass_fraction_of_cloud_condensed_water_in_air_due_to_advection">
    <canonical_units> s-1</canonical_units>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;condensed_water&quot; means liquid and ice. 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).</description>
  </entry>
  <entry id="tendency_of_mass_fraction_of_cloud_ice_in_air">
    <canonical_units>s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time. 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).</description>
  </entry>
  <entry id="tendency_of_mass_fraction_of_cloud_ice_in_air_due_to_advection">
    <canonical_units>s-1</canonical_units>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. 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).</description>
  </entry>
  <entry id="tendency_of_mass_fraction_of_cloud_ice_in_air_due_to_diffusion">
    <canonical_units>s-1</canonical_units>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. 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).</description>
  </entry>
  <entry id="tendency_of_mass_fraction_of_cloud_liquid_water_in_air">
    <canonical_units>s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time. 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).</description>
  </entry>
  <entry id="tendency_of_mass_fraction_of_cloud_liquid_water_in_air_due_to_advection">
    <canonical_units>s-1</canonical_units>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. 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).</description>
  </entry>
  <entry id="tendency_of_mass_fraction_of_cloud_liquid_water_in_air_due_to_diffusion">
    <canonical_units>s-1</canonical_units>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. 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).</description>
  </entry>
  <entry id="tendency_of_moles_of_carbon_monoxide_in_atmosphere">
    <canonical_units>mol s-1</canonical_units>
    <description>t&quot;endency_of_X&quot; means derivative of X with respect to time.  The construction &quot;moles_of_X_in_atmosphere&quot; means the total number of moles of X contained in the entire atmosphere, i.e, summed over the atmospheric column and over the entire globe.  The chemical formula of carbon monoxide is CO.</description>
  </entry>
  <entry id="tendency_of_moles_of_carbon_monoxide_in_middle_atmosphere">
    <canonical_units>mol s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;moles_of_X_in_middle_atmosphere&quot; means the total number of moles of X contained in the troposphere and stratosphere, i.e, summed over that part of the atmospheric column and over the entire globe.  The chemical formula of carbon monoxide is CO.</description>
  </entry>
  <entry id="tendency_of_moles_of_carbon_monoxide_in_troposphere">
    <canonical_units>mol s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;moles_of_X_in_troposphere&quot; means the total number of moles of X contained in the troposphere, i.e, summed over that part of the atmospheric column and over the entire globe.  The chemical formula of carbon monoxide is CO.</description>
  </entry>
  <entry id="tendency_of_moles_of_carbon_tetrachloride_in_atmosphere">
    <canonical_units>mol s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  The construction &quot;moles_of_X_in_atmosphere&quot; means the total number of moles of X contained in the entire atmosphere, i.e, summed over the atmospheric column and over the entire globe.  The chemical formula of carbon tetrachloride is CCl4.</description>
  </entry>
  <entry id="tendency_of_moles_of_cfc11_in_atmosphere">
    <canonical_units>mol s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  The construction &quot;moles_of_X_in_atmosphere&quot; means the total number of moles of X contained in the entire atmosphere, i.e, summed over the atmospheric column and over the entire globe.  The chemical formula of CFC11 is CFCl3.  The IUPAC name for CFC11 is trichloro-fluoro-methane.</description>
  </entry>
  <entry id="tendency_of_moles_of_cfc113_in_atmosphere">
    <canonical_units>mol s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  The construction &quot;moles_of_X_in_atmosphere&quot; means the total number of moles of X contained in the entire atmosphere, i.e, summed over the atmospheric column and over the entire globe.  The chemical formula of CFC113 is CCl2FCClF2.  The IUPAC name for CFC113 is 1,1,2-trichloro-1,2,2-trifluoro-ethane.</description>
  </entry>
  <entry id="tendency_of_moles_of_cfc114_in_atmosphere">
    <canonical_units>mol s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  The construction &quot;moles_of_X_in_atmosphere&quot; means the total number of moles of X contained in the entire atmosphere, i.e, summed over the atmospheric column and over the entire globe.  The chemical formula of CFC114 is CClF2CClF2.  The IUPAC name for CFC114 is 1,2-dichloro-1,1,2,2-tetrafluoro-ethane.</description>
  </entry>
  <entry id="tendency_of_moles_of_cfc115_in_atmosphere">
    <canonical_units>mol s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  The construction &quot;moles_of_X_in_atmosphere&quot; means the total number of moles of X contained in the entire atmosphere, i.e, summed over the atmospheric column and over the entire globe.    The chemical formula of CFC115 is CClF2CF3.  The IUPAC name for CFC115 is 1-chloro-1,1,2,2,2-pentafluoro-ethane.</description>
  </entry>
  <entry id="tendency_of_moles_of_cfc12_in_atmosphere">
    <canonical_units>mol s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  The construction &quot;moles_of_X_in_atmosphere&quot; means the total number of moles of X contained in the entire atmosphere, i.e, summed over the atmospheric column and over the entire globe.  The chemical formula of CFC12 is CF2Cl2.  The IUPAC name for CFC12 is dichloro-difluoro-methane.</description>
  </entry>
  <entry id="tendency_of_moles_of_halon1202_in_atmosphere">
    <canonical_units>mol s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  The construction &quot;moles_of_X_in_atmosphere&quot; means the total number of moles of X contained in the entire atmosphere, i.e, summed over the atmospheric column and over the entire globe.  The chemical formula of halon 1202 is CBr2F2.  The IUPAC name for halon 1202 is dibromo-difluoro-methane.</description>
  </entry>
  <entry id="tendency_of_moles_of_halon1211_in_atmosphere">
    <canonical_units>mol s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  The construction &quot;moles_of_X_in_atmosphere&quot; means the total number of moles of X contained in the entire atmosphere, i.e, summed over the atmospheric column and over the entire globe.  The chemical formula of  halon1211 is CBrClF2.  The IUPAC name for halon 1211 is bromo-chloro-difluoro-methane.</description>
  </entry>
  <entry id="tendency_of_moles_of_halon1301_in_atmosphere">
    <canonical_units>mol s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  The construction &quot;moles_of_X_in_atmosphere&quot; means the total number of moles of X contained in the entire atmosphere, i.e, summed over the atmospheric column and over the entire globe.  The chemical formula of halon1301 is CBrF3.  The IUPAC name for halon 1301 is bromo-trifluoro-methane.</description>
  </entry>
  <entry id="tendency_of_moles_of_halon2402_in_atmosphere">
    <canonical_units>mol s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  The construction &quot;moles_of_X_in_atmosphere&quot; means the total number of moles of X contained in the entire atmosphere, i.e, summed over the atmospheric column and over the entire globe.  The chemical formula of halon2402 is C2Br2F2.  The IUPAC name for halon 2402 is 1,2-dibromo-1,1,2,2-tetrafluoro-ethane.</description>
  </entry>
  <entry id="tendency_of_moles_of_hcc140a_in_atmosphere">
    <canonical_units>mol s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  The construction &quot;moles_of_X_in_atmosphere&quot; means the total number of moles of X contained in the entire atmosphere, i.e, summed over the atmospheric column and over the entire globe.  The chemical formula of HCC140a is CH3CCl3.  The IUPAC name for HCC 140a is 1,1,1-trichloroethane.</description>
  </entry>
  <entry id="tendency_of_moles_of_hcc140a_in_middle_atmosphere">
    <canonical_units>mol s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;moles_of_X_in_middle_atmosphere&quot; means the total number of moles of X contained in the troposphere and stratosphere, i.e, summed over that part of the atmospheric column and over the entire globe.  The chemical formula of HCC140a is CH3CCl3.  The IUPAC name for HCC 140a is 1,1,1-trichloroethane.</description>
  </entry>
  <entry id="tendency_of_moles_of_hcc140a_in_troposphere">
    <canonical_units>mol s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;moles_of_X_in_troposphere&quot; means the total number of moles of X contained in the troposphere, i.e, summed over that part of the atmospheric column and over the entire globe.  The chemical formula of HCC140a is CH3CCl3.  The IUPAC name for HCC 140a is 1,1,1-trichloroethane.</description>
  </entry>
  <entry id="tendency_of_moles_of_hcfc22_in_atmosphere">
    <canonical_units>mol s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  The construction &quot;moles_of_X_in_atmosphere&quot; means the total number of moles of X contained in the entire atmosphere, i.e, summed over the atmospheric column and over the entire globe.  The chemical formula of HCFC22 is CHClF2.  The IUPAC name for HCFC 22 is chloro-difluoro-methane.</description>
  </entry>
  <entry id="tendency_of_moles_of_hcfc22_in_troposphere">
    <canonical_units>mol s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;moles_of_X_in_troposphere&quot; means the total number of moles of X contained in the troposphere, i.e, summed over that part of the atmospheric column and over the entire globe.  The chemical formula of HCFC22 is CHClF2.  The IUPAC name for HCFC 22 is chloro-difluoro-methane.</description>
  </entry>
  <entry id="tendency_of_moles_of_methane_in_atmosphere">
    <canonical_units>mol s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  The construction &quot;moles_of_X_in_atmosphere&quot; means the total number of moles of X contained in the entire atmosphere, i.e, summed over the atmospheric column and over the entire globe.  The chemical formula of methane is CH4.</description>
  </entry>
  <entry id="tendency_of_moles_of_methane_in_middle_atmosphere">
    <canonical_units>mol s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;moles_of_X_in_middle_atmosphere&quot; means the total number of moles of X contained in the troposphere and stratosphere, i.e, summed over that part of the atmospheric column and over the entire globe.  The chemical formula of methane is CH4.</description>
  </entry>
  <entry id="tendency_of_moles_of_methane_in_troposphere">
    <canonical_units>mol s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;moles_of_X_in_troposphere&quot; means the total number of moles of X contained in the troposphere, i.e, summed over that part of the atmospheric column and over the entire globe.  The chemical formula of methane is CH4.</description>
  </entry>
  <entry id="tendency_of_moles_of_methyl_bromide_in_atmosphere">
    <canonical_units>mol s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  The construction &quot;moles_of_X_in_atmosphere&quot; means the total number of moles of X contained in the entire atmosphere, i.e, summed over the atmospheric column and over the entire globe.  The chemical formula of methyl bromide is CH3Br.</description>
  </entry>
  <entry id="tendency_of_moles_of_methyl_bromide_in_middle_atmosphere">
    <canonical_units>mol s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;moles_of_X_in_middle_atmosphere&quot; means the total number of moles of X contained in the troposphere and stratosphere, i.e, summed over that part of the atmospheric column and over the entire globe.  The chemical formula of methyl bromide is CH3Br.</description>
  </entry>
  <entry id="tendency_of_moles_of_methyl_bromide_in_troposphere">
    <canonical_units>mol s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;moles_of_X_in_troposphere&quot; means the total number of moles of X contained in the troposphere, i.e, summed over that part of the atmospheric column and over the entire globe.  The chemical formula of methyl bromide is CH3Br.</description>
  </entry>
  <entry id="tendency_of_moles_of_methyl_chloride_in_atmosphere">
    <canonical_units>mol s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  The construction &quot;moles_of_X_in_atmosphere&quot; means the total number of moles of X contained in the entire atmosphere, i.e, summed over the atmospheric column and over the entire globe.  The chemical formula of methyl chloride is CH3Cl.</description>
  </entry>
  <entry id="tendency_of_moles_of_methyl_chloride_in_middle_atmosphere">
    <canonical_units>mol s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;moles_of_X_in_middle_atmosphere&quot; means the total number of moles of X contained in the troposphere and stratosphere, i.e, summed over that part of the atmospheric column and over the entire globe.  The chemical formula of methyl chloride is CH3Cl.</description>
  </entry>
  <entry id="tendency_of_moles_of_methyl_chloride_in_troposphere">
    <canonical_units>mol s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;moles_of_X_in_troposphere&quot; means the total number of moles of X contained in the troposphere, i.e, summed over that part of the atmospheric column and over the entire globe.  The chemical formula of methyl chloride is CH3Cl.</description>
  </entry>
  <entry id="tendency_of_moles_of_molecular_hydrogen_in_atmosphere">
    <canonical_units>mol s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  The construction &quot;moles_of_X_in_atmosphere&quot; means the total number of moles of X contained in the entire atmosphere, i.e, summed over the atmospheric column and over the entire globe.  The chemical formula of molecular hydrogen is H2.</description>
  </entry>
  <entry id="tendency_of_moles_of_molecular_hydrogen_in_middle_atmosphere">
    <canonical_units>mol s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;moles_of_X_in_middle_atmosphere&quot; means the total number of moles of X contained in the troposphere and stratosphere, i.e, summed over that part of the atmospheric column and over the entire globe.  The chemical formula of molecular hydrogen is H2.</description>
  </entry>
  <entry id="tendency_of_moles_of_molecular_hydrogen_in_troposphere">
    <canonical_units>mol s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;moles_of_X_in_troposphere&quot; means the total number of moles of X contained in the troposphere, i.e, summed over that part of the atmospheric column and over the entire globe.  The chemical formula of molecular hydrogen is H2.</description>
  </entry>
  <entry id="tendency_of_moles_of_nitrous_oxide_in_atmosphere">
    <canonical_units>mol s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  The construction &quot;moles_of_X_in_atmosphere&quot; means the total number of moles of X contained in the entire atmosphere, i.e, summed over the atmospheric column and over the entire globe.  The chemical formula of nitrous oxide is N2O.</description>
  </entry>
  <entry id="tendency_of_northward_wind">
    <canonical_units>m s-2</canonical_units>
    <amip>tnmmvtot</amip>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)</description>
  </entry>
  <entry id="tendency_of_northward_wind_due_to_advection">
    <canonical_units>m s-2</canonical_units>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)</description>
  </entry>
  <entry id="tendency_of_northward_wind_due_to_convection">
    <canonical_units>m s-2</canonical_units>
    <amip>tnmmvc</amip>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)</description>
  </entry>
  <entry id="tendency_of_northward_wind_due_to_diffusion">
    <canonical_units>m s-2</canonical_units>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)</description>
  </entry>
  <entry id="tendency_of_northward_wind_due_to_gravity_wave_drag">
    <canonical_units>m s-2</canonical_units>
    <amip>tnmmvgwd</amip>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)</description>
  </entry>
  <entry id="tendency_of_ocean_barotropic_streamfunction">
    <canonical_units>m3 s-2</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.</description>
  </entry>
  <entry id="tendency_of_potential_energy_content_of_atmosphere_layer_due_to_advection">
    <canonical_units>W m-2</canonical_units>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;Content&quot; indicates a quantity per unit area. &quot;Layer&quot; 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. 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.)</description>
  </entry>
  <entry id="tendency_of_potential_energy_content_of_ocean_layer_due_to_convection">
    <canonical_units>W m-2</canonical_units>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;Content&quot; indicates a quantity per unit area. &quot;Layer&quot; 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. 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.)</description>
  </entry>
  <entry id="tendency_of_potential_energy_content_of_ocean_layer_due_to_diffusion ">
    <canonical_units>W m-2</canonical_units>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;Content&quot; indicates a quantity per unit area. &quot;Layer&quot; 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. 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.)</description>
  </entry>
  <entry id="tendency_of_sea_ice_area_fraction_due_to_dynamics">
    <canonical_units>s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;X_area_fraction&quot; means the fraction of horizontal area occupied by X. Sea ice area fraction is area of the sea surface occupied by sea ice. It is also called &quot;sea ice concentration&quot;.  &quot;Sea ice dynamics&quot; refers to the motion of sea ice.</description>
  </entry>
  <entry id="tendency_of_sea_ice_area_fraction_due_to_thermodynamics">
    <canonical_units>s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;X_area_fraction&quot; means the fraction of horizontal area occupied by X. Sea ice area fraction is area of the sea surface occupied by sea ice. It is also called &quot;sea ice concentration&quot;.  &quot;Sea ice thermodynamics&quot; refers to the addition or subtraction of mass due to surface and basal fluxes.</description>
  </entry>
  <entry id="tendency_of_sea_ice_thickness_due_to_dynamics">
    <canonical_units>m s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Sea ice dynamics&quot; refers to the motion of sea ice.</description>
  </entry>
  <entry id="tendency_of_sea_ice_thickness_due_to_thermodynamics">
    <canonical_units>m s-1</canonical_units>
    <grib>97</grib>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time.</description>
  </entry>
  <entry id="tendency_of_sea_water_salinity_due_to_advection">
    <canonical_units>1e-3 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  The unit of salinity is PSU, which is dimensionless. The units attribute should be given as 1e-3 or 0.001 (parts per thousand) s-1  if salinity is in PSU.</description>
  </entry>
  <entry id="tendency_of_sea_water_salinity_due_to_bolus_advection">
    <canonical_units>1e-3 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  The unit of salinity is PSU, which is dimensionless. The units attribute should be given as 1e-3 or 0.001 (parts per thousand) s-1  if salinity is in PSU.  Bolus advection in an ocean model means the part due to a scheme representing eddy-induced effects not included in the velocity field</description>
  </entry>
  <entry id="tendency_of_sea_water_salinity_due_to_horizontal_mixing">
    <canonical_units>1e-3 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  The unit of salinity is PSU, which is dimensionless. The units attribute should be given as 1e-3 or 0.001 (parts per thousand) s-1  if salinity is in PSU.  &quot;Horizontal mixing&quot; means any horizontal transport other than by advection and bolus advection, usually represented as horizontal diffusion in ocean models.</description>
  </entry>
  <entry id="tendency_of_sea_water_salinity_due_to_sea_ice_thermodynamics">
    <canonical_units>1e-3 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  The unit of salinity is PSU, which is dimensionless. The units attribute should be given as 1e-3 or 0.001 (parts per thousand) s-1  if salinity is in PSU.  &quot;Sea ice thermodynamics&quot; refers to the addition or subtraction of sea ice mass due to surface and basal fluxes.</description>
  </entry>
  <entry id="tendency_of_sea_water_salinity_due_to_vertical_mixing">
    <canonical_units>1e-3 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  The unit of salinity is PSU, which is dimensionless. The units attribute should be given as 1e-3 or 0.001 (parts per thousand) s-1  if salinity is in PSU.  &quot;Vertical mixing&quot; means any vertical transport other than by advection and bolus advection, represented by a combination of vertical diffusion, turbulent mixing and convection in ocean models.</description>
  </entry>
  <entry id="tendency_of_sea_water_temperature_due_to_advection">
    <canonical_units>K s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.</description>
  </entry>
  <entry id="tendency_of_sea_water_temperature_due_to_bolus_advection">
    <canonical_units>K s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  Bolus advection in an ocean model means the part due to a scheme representing eddy-induced effects not included in the velocity field.</description>
  </entry>
  <entry id="tendency_of_sea_water_temperature_due_to_horizontal_mixing">
    <canonical_units>K s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;Horizontal mixing&quot; means any horizontal transport other than by advection and bolus advection, usually represented as horizontal diffusion in ocean models. </description>
  </entry>
  <entry id="tendency_of_sea_water_temperature_due_to_vertical_mixing">
    <canonical_units>K s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time.  &quot;Vertical mixing&quot; means any vertical transport other than by advection and bolus advection, represented by a combination of vertical diffusion, turbulent mixing and convection in ocean models.</description>
  </entry>
  <entry id="tendency_of_specific_humidity">
    <canonical_units>s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;specific&quot; means per unit mass. Specific humidity is the mass fraction of water vapor in (moist) air.</description>
  </entry>
  <entry id="tendency_of_specific_humidity_due_to_advection">
    <canonical_units>s-1</canonical_units>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;specific&quot; means per unit mass. Specific humidity is the mass fraction of water vapor in (moist) air.</description>
  </entry>
  <entry id="tendency_of_specific_humidity_due_to_convection">
    <canonical_units>s-1</canonical_units>
    <amip>tnmrc</amip>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;specific&quot; means per unit mass. Specific humidity is the mass fraction of water vapor in (moist) air.</description>
  </entry>
  <entry id="tendency_of_specific_humidity_due_to_diffusion">
    <canonical_units>s-1</canonical_units>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;specific&quot; means per unit mass. Specific humidity is the mass fraction of water vapor in (moist) air.</description>
  </entry>
  <entry id="tendency_of_specific_humidity_due_to_large_scale_precipitation">
    <canonical_units>s-1</canonical_units>
    <description>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. &quot;Tendency_of_X&quot; means derivative of X with respect to time. &quot;Specific&quot; means per unit mass. Specific humidity is the mass fraction of water vapor in (moist) air.</description>
  </entry>
  <entry id="tendency_of_specific_humidity_due_to_model_physics">
    <canonical_units>s-1</canonical_units>
    <amip>tnmrd</amip>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;specific&quot; means per unit mass. Specific humidity is the mass fraction of water vapor in (moist) air.</description>
  </entry>
  <entry id="tendency_of_surface_air_pressure">
    <canonical_units>Pa s-1</canonical_units>
    <grib>E158</grib>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;tendency_of_X&quot; means derivative of X with respect to time.</description>
  </entry>
  <entry id="tendency_of_surface_snow_amount">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>The surface called &quot;surface&quot; means the lower boundary of the atmosphere. &quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;Amount&quot; means mass per unit area. Surface amount refers to the amount on the ground, excluding that on the plant or vegetation canopy.</description>
  </entry>
  <entry id="tendency_of_upward_air_velocity">
    <canonical_units>m s-2</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time. A velocity is a vector quantity. &quot;Upward&quot; 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.</description>
  </entry>
  <entry id="tendency_of_upward_air_velocity_due_to_advection">
    <canonical_units>m s-2</canonical_units>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. A velocity is a vector quantity. &quot;Upward&quot; 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.</description>
  </entry>
  <entry id="tendency_of_water_vapor_content_of_atmosphere_layer">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;Content&quot; indicates a quantity per unit area. &quot;Layer&quot; 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.</description>
  </entry>
  <entry id="tendency_of_water_vapor_content_of_atmosphere_layer_due_to_convection">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;Content&quot; indicates a quantity per unit area. &quot;Layer&quot; 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.</description>
  </entry>
  <entry id="tendency_of_water_vapor_content_of_atmosphere_layer_due_to_deep_convection">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;Content&quot; indicates a quantity per unit area. &quot;Layer&quot; 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.</description>
  </entry>
  <entry id="tendency_of_water_vapor_content_of_atmosphere_layer_due_to_shallow_convection">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;Content&quot; indicates a quantity per unit area. &quot;Layer&quot; 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.</description>
  </entry>
  <entry id="tendency_of_water_vapor_content_of_atmosphere_layer_due_to_turbulence">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. &quot;Content&quot; indicates a quantity per unit area. &quot;Layer&quot; 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 variable) as well.</description>
  </entry>
  <entry id="tendency_of_wind_speed_due_to_convection">
    <canonical_units>m s-2</canonical_units>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. Speed is the magnitude of velocity. Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.) The wind speed is the magnitude of the wind velocity.</description>
  </entry>
  <entry id="tendency_of_wind_speed_due_to_gravity_wave_drag">
    <canonical_units>m s-2</canonical_units>
    <description>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. &quot;tendency_of_X&quot; means derivative of X with respect to time. Speed is the magnitude of velocity. Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.) The wind speed is the magnitude of the wind velocity.</description>
  </entry>
  <entry id="thickness_of_convective_rainfall_amount">
    <canonical_units>m</canonical_units>
    <description>&quot;Amount&quot; means mass per unit area. The construction thickness_of_[X_]rainfall_amount means the accumulated &quot;depth&quot; of rainfall i.e. the thickness of a layer of liquid water having the same mass per unit area as the rainfall amount.</description>
  </entry>
  <entry id="thickness_of_convective_snowfall_amount">
    <canonical_units>m</canonical_units>
    <description>&quot;Amount&quot; means mass per unit area. The construction thickness_of_[X_]snowfall_amount means the accumulated &quot;depth&quot; of snow which fell i.e. the thickness of the layer of snow at its own density. There are corresponding standard names for liquid water equivalent (lwe) thickness.</description>
  </entry>
  <entry id="thickness_of_large_scale_rainfall_amount">
    <canonical_units>m</canonical_units>
    <description>&quot;Amount&quot; means mass per unit area. The construction thickness_of_[X_]rainfall_amount means the accumulated &quot;depth&quot; of rainfall i.e. the thickness of a layer of liquid water having the same mass per unit area as the rainfall amount.</description>
  </entry>
  <entry id="thickness_of_large_scale_snowfall_amount">
    <canonical_units>m</canonical_units>
    <description>&quot;Amount&quot; means mass per unit area. The construction thickness_of_[X_]snowfall_amount means the accumulated &quot;depth&quot; of snow which fell i.e. the thickness of the layer of snow at its own density. There are corresponding standard names for liquid water equivalent (lwe) thickness.</description>
  </entry>
  <entry id="thickness_of_rainfall_amount">
    <canonical_units>m</canonical_units>
    <description>&quot;Amount&quot; means mass per unit area. The construction thickness_of_[X_]rainfall_amount means the accumulated &quot;depth&quot; of rainfall i.e. the thickness of a layer of liquid water having the same mass per unit area as the rainfall amount.</description>
  </entry>
  <entry id="thickness_of_snowfall_amount">
    <canonical_units>m</canonical_units>
    <description>&quot;Amount&quot; means mass per unit area. The construction thickness_of_[X_]snowfall_amount means the accumulated &quot;depth&quot; of snow which fell i.e. the thickness of the layer of snow at its own density. There are corresponding standard names for liquid water equivalent (lwe) thickness.</description>
  </entry>
  <entry id="thunderstorm_probability">
    <canonical_units>1</canonical_units>
    <grib>60</grib>
    <description>&quot;probability_of_X&quot; means the chance that X is true or of at least one occurrence of X. Space and time coordinates must be used to indicate the area and time-interval to which a probability applies.</description>
  </entry>
  <entry id="time">
    <canonical_units>s</canonical_units>
    <amip>time</amip>
    <description></description>
  </entry>
  <entry id="toa_adjusted_longwave_forcing">
    <canonical_units>W m-2</canonical_units>
    <description>&quot;longwave&quot; means longwave radiation. &quot;toa&quot; means top of atmosphere. Adjusted forcing is the radiative flux change caused by an imposed change in radiative forcing agent (greenhouse gases, aerosol, solar radiation, etc.) after allowance for stratospheric temperature adjustment.</description>
  </entry>
  <entry id="toa_adjusted_radiative_forcing">
    <canonical_units>W m-2</canonical_units>
    <description>&quot;toa&quot; means top of atmosphere. Adjusted forcing is the radiative flux change caused by an imposed change in radiative forcing agent (greenhouse gases, aerosol, solar radiation, etc.) after allowance for stratospheric temperature adjustment.</description>
  </entry>
  <entry id="toa_adjusted_shortwave_forcing">
    <canonical_units>W m-2</canonical_units>
    <description>&quot;shortwave&quot; means shortwave radiation. &quot;toa&quot; means top of atmosphere. Adjusted forcing is the radiative flux change caused by an imposed change in radiative forcing agent (greenhouse gases, aerosol, solar radiation, etc.) after allowance for stratospheric temperature adjustment.</description>
  </entry>
  <entry id="toa_cloud_radiative_effect">
    <canonical_units>W m-2</canonical_units>
    <description>&quot;toa&quot; means top of atmosphere.  Cloud radiative effect is also commonly known as &quot;cloud radiative forcing&quot;.  It is the sum of the quantities with standard names toa_shortwave_cloud_radiative_effect and toa_longwave_cloud_radiative_effect.</description>
  </entry>
  <entry id="toa_incoming_shortwave_flux">
    <canonical_units>W m-2</canonical_units>
    <amip>rsdt</amip>
    <description>&quot;shortwave&quot; means shortwave radiation. &quot;toa&quot; means top of atmosphere. The TOA incoming shortwave flux is the radiative flux from the sun i.e. the &quot;downwelling&quot; TOA shortwave flux. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="toa_instantaneous_longwave_forcing">
    <canonical_units>W m-2</canonical_units>
    <description>&quot;longwave&quot; means longwave radiation. &quot;toa&quot; means top of atmosphere. Instantaneous forcing is the radiative flux change caused instantaneously by an imposed change in radiative forcing agent (greenhouse gases, aerosol, solar radiation, etc.).</description>
  </entry>
  <entry id="toa_instantaneous_radiative_forcing">
    <canonical_units>W m-2</canonical_units>
    <description>&quot;toa&quot; means top of atmosphere. Instantaneous forcing is the radiative flux change caused instantaneously by an imposed change in radiative forcing agent (greenhouse gases, aerosol, solar radiation, etc.).</description>
  </entry>
  <entry id="toa_instantaneous_shortwave_forcing">
    <canonical_units>W m-2</canonical_units>
    <description>&quot;shortwave&quot; means shortwave radiation. &quot;toa&quot; means top of atmosphere. Instantaneous forcing is the radiative flux change caused instantaneously by an imposed change in radiative forcing agent (greenhouse gases, aerosol, solar radiation, etc.).</description>
  </entry>
  <entry id="toa_longwave_cloud_radiative_effect">
    <canonical_units>W m-2</canonical_units>
    <description>&quot;toa&quot; means top of atmosphere.  &quot;Longwave&quot; means longwave radiation.  Cloud radiative effect is also commonly known as &quot;cloud radiative forcing&quot;.  It is the difference in radiative flux resulting from the presence of clouds, i.e. it is the difference between toa_outgoing_longwave_flux_assuming_clear_sky and toa_outgoing_longwave_flux.</description>
  </entry>
  <entry id="toa_net_downward_longwave_flux">
    <canonical_units>W m-2</canonical_units>
    <description>&quot;longwave&quot; means longwave radiation. &quot;toa&quot; means top of atmosphere.   &quot;Downward&quot; indicates a vector component which is positive when directed downward (negative upward).  Net downward radiation is the difference between radiation from above (downwelling) and radiation from below (upwelling).  In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="toa_net_downward_radiative_flux">
    <canonical_units>W m-2</canonical_units>
    <description>&quot;toa&quot; means top of atmosphere. &quot;Downward&quot; indicates a vector component which is positive when directed downward (negative upward). Net downward radiation is the difference between radiation from above (downwelling) and radiation from below (upwelling). Radiative flux is the sum of shortwave and longwave radiative fluxes. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="toa_net_downward_shortwave_flux">
    <canonical_units>W m-2</canonical_units>
    <amip>rst</amip>
    <description>&quot;shortwave&quot; means shortwave radiation. &quot;toa&quot; means top of atmosphere. &quot;Downward&quot; indicates a vector component which is positive when directed downward (negative upward). Net downward radiation is the difference between radiation from above (downwelling) and radiation from below (upwelling). In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="toa_net_downward_shortwave_flux_assuming_clear_sky">
    <canonical_units>W m-2</canonical_units>
    <description>A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. &quot;shortwave&quot; means shortwave radiation. &quot;toa&quot; means top of atmosphere. &quot;Downward&quot; indicates a vector component which is positive when directed downward (negative upward). Net downward radiation is the difference between radiation from above (downwelling) and radiation from below (upwelling). In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="toa_net_upward_longwave_flux">
    <canonical_units>W m-2</canonical_units>
    <description>&quot;longwave&quot; means longwave radiation. &quot;toa&quot; means top of atmosphere. &quot;Upward&quot; indicates a vector component which is positive when directed upward (negative downward). Net upward radiation is the difference between radiation from below (upwelling) and radiation from above (downwelling). In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="toa_net_upward_longwave_flux_assuming_clear_sky">
    <canonical_units>W m-2</canonical_units>
    <description>A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. &quot;longwave&quot; means longwave radiation. &quot;toa&quot; means top of atmosphere. &quot;Upward&quot; indicates a vector component which is positive when directed upward (negative downward). Net upward radiation is the difference between radiation from below (upwelling) and radiation from above (downwelling). In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="toa_net_upward_shortwave_flux">
    <canonical_units>W m-2</canonical_units>
    <grib>113 E178</grib>
    <description>&quot;shortwave&quot; means shortwave radiation. &quot;toa&quot; means top of atmosphere. &quot;Upward&quot; indicates a vector component which is positive when directed upward (negative downward). Net upward radiation is the difference between radiation from below (upwelling) and radiation from above (downwelling). In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="toa_outgoing_longwave_flux">
    <canonical_units>W m-2</canonical_units>
    <grib>114 E179</grib>
    <amip>rlut</amip>
    <description>&quot;longwave&quot; means longwave radiation. &quot;toa&quot; means top of atmosphere. The TOA outgoing longwave flux is the upwelling thermal radiative flux, often called the &quot;outgoing longwave radiation&quot; or &quot;OLR&quot;. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="toa_outgoing_longwave_flux_assuming_clear_sky">
    <canonical_units>W m-2</canonical_units>
    <amip>rlutcs</amip>
    <description>A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. &quot;longwave&quot; means longwave radiation. &quot;toa&quot; means top of atmosphere. The TOA outgoing longwave flux is the upwelling thermal radiative flux, often called the &quot;outgoing longwave radiation&quot; or &quot;OLR&quot;. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="toa_outgoing_shortwave_flux">
    <canonical_units>W m-2</canonical_units>
    <amip>rsut</amip>
    <description>&quot;shortwave&quot; means shortwave radiation. &quot;toa&quot; means top of atmosphere. The TOA outgoing shortwave flux is the reflected and scattered solar radiative flux i.e. the &quot;upwelling&quot; TOA shortwave flux, sometimes called the &quot;outgoing shortwave radiation&quot; or &quot;OSR&quot;. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="toa_outgoing_shortwave_flux_assuming_clear_sky">
    <canonical_units>W m-2</canonical_units>
    <amip>rsutcs</amip>
    <description>A phrase assuming_condition indicates that the named quantity is the value which would obtain if all aspects of the system were unaltered except for the assumption of the circumstances specified by the condition. &quot;shortwave&quot; means shortwave radiation. &quot;toa&quot; means top of atmosphere. The TOA outgoing shortwave flux is the reflected and scattered solar radiative flux i.e. the &quot;upwelling&quot; TOA shortwave flux, sometimes called the &quot;outgoing shortwave radiation&quot; or &quot;OSR&quot;. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="toa_shortwave_cloud_radiative_effect">
    <canonical_units>W m-2</canonical_units>
    <description>&quot;toa&quot; means top of atmosphere.  &quot;Shortwave&quot; means shortwave radiation.  Cloud radiative effect is also commonly known as &quot;cloud radiative forcing&quot;.  It is the difference in radiative flux resulting from the presence of clouds, i.e.  the difference between toa_net_downward_shortwave_flux and toa_net_downward_shortwave_flux_assuming_clear_sky.</description>
  </entry>
  <entry id="transpiration_amount">
    <canonical_units>kg m-2</canonical_units>
    <description>&quot;Amount&quot; means mass per unit area.</description>
  </entry>
  <entry id="transpiration_flux">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="tropopause_adjusted_longwave_forcing">
    <canonical_units>W m-2</canonical_units>
    <description>&quot;longwave&quot; means longwave radiation. Adjusted forcing is the radiative flux change caused by an imposed change in radiative forcing agent (greenhouse gases, aerosol, solar radiation, etc.) after allowance for stratospheric temperature adjustment.</description>
  </entry>
  <entry id="tropopause_adjusted_radiative_forcing">
    <canonical_units>W m-2</canonical_units>
    <description>Adjusted forcing is the radiative flux change caused by an imposed change in radiative forcing agent (greenhouse gases, aerosol, solar radiation, etc.) after allowance for stratospheric temperature adjustment.</description>
  </entry>
  <entry id="tropopause_adjusted_shortwave_forcing">
    <canonical_units>W m-2</canonical_units>
    <description>&quot;shortwave&quot; means shortwave radiation. Adjusted forcing is the radiative flux change caused by an imposed change in radiative forcing agent (greenhouse gases, aerosol, solar radiation, etc.) after allowance for stratospheric temperature adjustment.</description>
  </entry>
  <entry id="tropopause_air_pressure">
    <canonical_units>Pa</canonical_units>
    <description></description>
  </entry>
  <entry id="tropopause_air_temperature">
    <canonical_units>K</canonical_units>
    <description>Air temperature is the bulk temperature of the air, not the surface (skin) temperature.</description>
  </entry>
  <entry id="tropopause_altitude">
    <canonical_units>m</canonical_units>
    <description>Altitude is the (geometric) height above the geoid, which is the reference geopotential surface. The geoid is similar to mean sea level.</description>
  </entry>
  <entry id="tropopause_downwelling_longwave_flux">
    <canonical_units>W m-2</canonical_units>
    <description>&quot;longwave&quot; means longwave radiation. Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. When thought of as being incident on a surface, a radiative flux is sometimes called &quot;irradiance&quot;. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called &quot;vector irradiance&quot;. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="tropopause_instantaneous_longwave_forcing">
    <canonical_units>W m-2</canonical_units>
    <description>&quot;longwave&quot; means longwave radiation. Instantaneous forcing is the radiative flux change caused instantaneously by an imposed change in radiative forcing agent (greenhouse gases, aerosol, solar radiation, etc.).</description>
  </entry>
  <entry id="tropopause_instantaneous_radiative_forcing">
    <canonical_units>W m-2</canonical_units>
    <description>Instantaneous forcing is the radiative flux change caused instantaneously by an imposed change in radiative forcing agent (greenhouse gases, aerosol, solar radiation, etc.).</description>
  </entry>
  <entry id="tropopause_instantaneous_shortwave_forcing">
    <canonical_units>W m-2</canonical_units>
    <description>&quot;shortwave&quot; means shortwave radiation. Instantaneous forcing is the radiative flux change caused instantaneously by an imposed change in radiative forcing agent (greenhouse gases, aerosol, solar radiation, etc.).</description>
  </entry>
  <entry id="tropopause_net_downward_longwave_flux">
    <canonical_units>W m-2</canonical_units>
    <description>&quot;longwave&quot; means longwave radiation. &quot;Downward&quot; indicates a vector component which is positive when directed downward (negative upward). Net downward radiation is the difference between radiation from above (downwelling) and radiation from below (upwelling). In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="tropopause_net_downward_shortwave_flux">
    <canonical_units>W m-2</canonical_units>
    <description>&quot;shortwave&quot; means shortwave radiation. &quot;Downward&quot; indicates a vector component which is positive when directed downward (negative upward). Net downward radiation is the difference between radiation from above (downwelling) and radiation from below (upwelling). In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="tropopause_upwelling_shortwave_flux">
    <canonical_units>W m-2</canonical_units>
    <description>&quot;shortwave&quot; means shortwave radiation. Upwelling radiation is radiation from below. It does not mean &quot;net upward&quot;. When thought of as being incident on a surface, a radiative flux is sometimes called &quot;irradiance&quot;. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called &quot;vector irradiance&quot;. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="upward_air_velocity">
    <canonical_units>m s-1</canonical_units>
    <grib>40</grib>
    <description>A velocity is a vector quantity. &quot;Upward&quot; 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.</description>
  </entry>
  <entry id="upward_dry_static_energy_flux_due_to_diffusion">
    <canonical_units>W m-2</canonical_units>
    <description>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. &quot;Upward&quot; indicates a vector component which is positive when directed upward (negative downward). Dry static energy is the sum of enthalpy and potential energy (itself the sum of gravitational and centripetal potential energy). Enthalpy can be written either as (1) CpT, where Cp is heat capacity at constant pressure, T is absolute temperature, or (2) U+pV, where U is internal energy, p is pressure and V is volume. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="upward_eastward_stress_at_sea_ice_base">
    <canonical_units>Pa</canonical_units>
    <description>&quot;Eastward&quot; indicates a vector component which is positive when directed eastward (negative westward). &quot;Upward&quot; indicates a vector component which is positive when directed upward (negative downward). &quot;Upward eastward&quot; indicates the ZX component of a tensor. An upward eastward stress is an upward flux of eastward momentum, which accelerates the upper medium eastward and the lower medium westward.</description>
  </entry>
  <entry id="upward_eastward_momentum_flux_in_air_due_to_nonorographic_eastward_gravity_waves">
    <canonical_units>Pa</canonical_units>
    <description>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. "Upward" indicates a vector component which is positive when directed upward (negative downward). "Eastward" indicates a vector component which is positive when directed eastward (negative westward). "Upward eastward" indicates the ZX component of a tensor. An upward eastward momentum flux is an upward flux of eastward momentum, which accelerates the upper medium eastward and the lower medium westward.  Momentum flux is dimensionally equivalent to stress and pressure.  In accordance with common usage in geophysical disciplines, "flux" implies per unit area, called "flux density" in physics. The total upward eastward momentum flux due to gravity waves is the sum of the fluxes due to orographic gravity waves and nonorographic waves. The upward eastward momentum flux due to orographic gravity waves has the standard name upward_eastward_momentum_flux_in_air_due_to_orographic_gravity_waves. The total upward eastward momentum flux due to nonorographic gravity waves is the sum of the fluxes due to eastward and westward propagating waves. The latter has the standard name upward_eastward_momentum_flux_in_air_due_to_nonorographic_westward_gravity_waves.</description>
  </entry>
  <entry id="upward_eastward_momentum_flux_in_air_due_to_nonorographic_westward_gravity_waves">
    <canonical_units>Pa</canonical_units>
    <description>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. "Upward" indicates a vector component which is positive when directed upward (negative downward).  "Eastward" indicates a vector component which is positive when directed eastward (negative westward).  "Upward eastward" indicates the ZX component of a tensor. An upward eastward momentum flux is an upward flux of eastward momentum, which accelerates the upper medium eastward and the lower medium westward.  Momentum flux is dimensionally equivalent to stress and pressure.  In accordance with common usage in geophysical disciplines, "flux" implies per unit area, called "flux density" in physics. The total upward eastward momentum flux due to gravity waves is the sum of the fluxes due to orographic gravity waves and nonorographic waves. The upward eastward momentum flux due to orographic gravity waves has the standard name upward_eastward_momentum_flux_in_air_due_to_orographic_gravity_waves. The total upward eastward momentum flux due to nonorographic gravity waves is the sum of the fluxes due to eastward and westward propagating waves. The former has the standard name upward_eastward_momentum_flux_in_air_due_to_nonorographic_eastward _gravity_waves.</description>
  </entry>
  <entry id="upward_eastward_momentum_flux_in_air_due_to_orographic_gravity_waves">
    <canonical_units>Pa</canonical_units>
    <description>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. "Upward" indicates a vector component which is positive when directed upward (negative downward).  "Eastward" indicates a vector component which is positive when directed eastward (negative westward).  "Upward eastward" indicates the ZX component of a tensor. An upward eastward momentum flux is an upward flux of eastward momentum, which accelerates the upper medium eastward and the lower medium westward.  Momentum flux is dimensionally equivalent to stress and pressure.  In accordance with common usage in geophysical disciplines, "flux" implies per unit area, called "flux density" in physics. The total upward eastward momentum flux due to gravity waves is the sum of the fluxes due to orographic gravity waves and nonorographic waves. The total upward eastward momentum flux due to nonorographic gravity waves is the sum of the fluxes due to eastward and westward propagating waves. These quantities have the standard names upward_eastward_momentum_flux_in_air_due_to_nonorographic_eastward_gravity_waves and upward_eastward_momentum_flux_in_air_due_to_nonorographic_westward_gravity_waves, respectively.</description>
  </entry>
  <entry id="upward_eliassen_palm_flux_in_air">
    <canonical_units>m3 s-2</canonical_units>
    <description>&quot;Eliassen Palm flux&quot; is a widely used vector in the meridional plane, and the divergence of this flux appears as a forcing in the Transformed Eulerian mean formulation of the zonal mean zonal wind equation.  &quot;Upward&quot; indicates a vector component which is positive when directed upward (negative downward).</description>
  </entry>
  <entry id="upward_heat_flux_at_ground_level_in_snow">
    <canonical_units>W m-2</canonical_units>
    <description>ground_level means the land surface (beneath the snow and surface water, if any). &quot;Upward&quot; indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="upward_heat_flux_at_ground_level_in_soil">
    <canonical_units>W m-2</canonical_units>
    <description>ground_level means the land surface (beneath the snow and surface water, if any). &quot;Upward&quot; indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="upward_heat_flux_in_air">
    <canonical_units>W m-2</canonical_units>
    <description>&quot;Upward&quot; indicates a vector component which is positive when directed upward (negative downward). 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, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="upward_mass_flux_of_air">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;Upward&quot; indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="upward_northward_stress_at_sea_ice_base">
    <canonical_units>Pa</canonical_units>
    <description>&quot;Northward&quot; indicates a vector component which is positive when directed northward (negative southward). &quot;Upward&quot; indicates a vector component which is positive when directed upward (negative downward). &quot;Upward northward&quot; indicates the ZY component of a tensor. An upward northward stress is an upward flux of northward momentum, which accelerates the upper medium northward and the lower medium southward.</description>
  </entry>
  <entry id="upward_sea_ice_basal_heat_flux">
    <canonical_units>W m-2</canonical_units>
    <description>&quot;Upward&quot; indicates a vector component which is positive when directed upward (negative downward). The sea ice basal heat flux is the vertical heat flux (apart from radiation i.e. &quot;diffusive&quot;) in sea water at the base of the sea ice. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="upward_sea_water_velocity">
    <canonical_units>m s-1</canonical_units>
    <description>A velocity is a vector quantity. &quot;Upward&quot; indicates a vector component which is positive when directed upward (negative downward).</description>
  </entry>
  <entry id="upward_water_vapor_flux_in_air">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;Upward&quot; indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="upward_water_vapor_flux_in_air_due_to_diffusion">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>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. &quot;Upward&quot; indicates a vector component which is positive when directed upward (negative downward). In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="upwelling_longwave_flux_in_air">
    <canonical_units>W m-2</canonical_units>
    <description>&quot;longwave&quot; means longwave radiation. Upwelling radiation is radiation from below. It does not mean &quot;net upward&quot;. When thought of as being incident on a surface, a radiative flux is sometimes called &quot;irradiance&quot;. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called &quot;vector irradiance&quot;. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="upwelling_longwave_radiance_in_air">
    <canonical_units>W m-2 sr-1</canonical_units>
    <description>&quot;longwave&quot; means longwave radiation. Upwelling radiation is radiation from below. It does not mean &quot;net upward&quot;. Radiance is the radiative flux in a particular direction, per unit of solid angle. The direction towards which it is going must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead.</description>
  </entry>
  <entry id="upwelling_shortwave_flux_in_air">
    <canonical_units>W m-2</canonical_units>
    <description>&quot;shortwave&quot; means shortwave radiation. Upwelling radiation is radiation from below. It does not mean &quot;net upward&quot;. When thought of as being incident on a surface, a radiative flux is sometimes called &quot;irradiance&quot;. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called &quot;vector irradiance&quot;. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="upwelling_shortwave_radiance_in_air">
    <canonical_units>W m-2 sr-1</canonical_units>
    <description>&quot;shortwave&quot; means shortwave radiation. Upwelling radiation is radiation from below. It does not mean &quot;net upward&quot;. Radiance is the radiative flux in a particular direction, per unit of solid angle. The direction towards which it is going must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead.</description>
  </entry>
  <entry id="upwelling_spectral_radiance_in_air">
    <canonical_units>W m-2 m-1 sr-1</canonical_units>
    <description>Upwelling radiation is radiation from below. It does not mean &quot;net upward&quot;. &quot;spectral&quot; means per unit wavelength or as a function of wavelength; spectral quantities are sometimes called &quot;monochromatic&quot;. Radiation wavelength has standard name radiation_wavelength. Radiance is the radiative flux in a particular direction, per unit of solid angle. The direction towards which it is going must be specified, for instance with a coordinate of zenith_angle. If the radiation does not depend on direction, a standard name of isotropic radiance should be chosen instead.</description>
  </entry>
  <entry id="upwelling_spectral_radiative_flux_in_air">
    <canonical_units>W m-2 m-1</canonical_units>
    <description>Upwelling radiation is radiation from below. It does not mean &quot;net upward&quot;. &quot;spectral&quot; means per unit wavelength or as a function of wavelength; spectral quantities are sometimes called &quot;monochromatic&quot;. Radiation wavelength has standard name radiation_wavelength. When thought of as being incident on a surface, a radiative flux is sometimes called &quot;irradiance&quot;. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called &quot;vector irradiance&quot;. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="upwelling_spectral_radiative_flux_in_sea_water">
    <canonical_units>W m-2 m-1</canonical_units>
    <description>Upwelling radiation is radiation from below. It does not mean &quot;net upward&quot;. &quot;spectral&quot; means per unit wavelength or as a function of wavelength; spectral quantities are sometimes called &quot;monochromatic&quot;. Radiation wavelength has standard name radiation_wavelength. When thought of as being incident on a surface, a radiative flux is sometimes called &quot;irradiance&quot;. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called &quot;vector irradiance&quot;. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="vegetation_area_fraction">
    <canonical_units>1</canonical_units>
    <grib>87</grib>
    <description>&quot;X_area_fraction&quot; means the fraction of horizontal area occupied by X. &quot;X_area&quot; means the horizontal area occupied by X within the grid cell. &quot;Vegetation&quot; means any plants e.g. trees, shrubs, grass.</description>
  </entry>
  <entry id="vegetation_carbon_content">
    <canonical_units>kg m-2</canonical_units>
    <description>&quot;Content&quot; indicates a quantity per unit area. &quot;Vegetation&quot; means any plants e.g. trees, shrubs, grass.</description>
  </entry>
  <entry id="vertical_component_of_ocean_xy_tracer_diffusivity">
    <canonical_units>m2 s-1</canonical_units>
    <description>The vertical_component_of_ocean_xy_tracer_diffusivity means the vertical component of the diffusivity of tracers in the ocean due to lateral mixing. This quantity could appear in formulations of lateral diffusivity in which &quot;lateral&quot; does not mean &quot;iso-level&quot;, e.g. it would not be used for isopycnal diffusivity. &quot;Tracer diffusivity&quot; means the diffusivity of heat and salinity due to motion which is not resolved on the grid scale of the model.</description>
  </entry>
  <entry id="virtual_salt_flux_into_sea_water">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>The virtual_salt_flux_into_sea_water is the salt flux that would have the same effect on the sea surface salinity as the water_flux_out_of_sea_water. It includes the effects of precipitation, evaporation, river outflow, sea-ice and any water flux relaxation(s) and correction(s) that may have been applied. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="virtual_salt_flux_into_sea_water_due_to_newtonian_relaxation">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>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. The virtual_salt_flux_into_sea_water_due_to_newtonian_relaxation is the salt flux that would have the same effect on the sea surface salinity as water_flux_out_of_sea_water_due_to_newtonian_relaxation. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="virtual_temperature">
    <canonical_units>K</canonical_units>
    <grib>12</grib>
    <description>The virtual temperature of air is the temperature at which the dry air constituent of a parcel of moist air would have the same density as the moist air at the same pressure.</description>
  </entry>
  <entry id="visibility_in_air">
    <canonical_units>m</canonical_units>
    <grib>20</grib>
    <description>The visibility is the distance at which something can be seen.</description>
  </entry>
  <entry id="volume_absorption_coefficient_of_radiative_flux_in_sea_water">
    <canonical_units>m-1</canonical_units>
    <description>Radiative flux is the sum of shortwave and longwave radiative fluxes. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics. The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength.</description>
  </entry>
  <entry id="volume_absorption_coefficient_of_radiative_flux_in_sea_water_due_to_dissolved_organic_matter">
    <canonical_units>m-1</canonical_units>
    <description>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. Radiative flux is the sum of shortwave and longwave radiative fluxes. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics. The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength.</description>
  </entry>
  <entry id="volume_attenuation_coefficient_of_downwelling_radiative_flux_in_sea_water">
    <canonical_units>m-1</canonical_units>
    <description>Downwelling radiation is radiation from above. It does not mean &quot;net downward&quot;. Radiative flux is the sum of shortwave and longwave radiative fluxes. When thought of as being incident on a surface, a radiative flux is sometimes called &quot;irradiance&quot;. In addition, it is identical with the quantity measured by a cosine-collector light-meter and sometimes called &quot;vector irradiance&quot;. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics. The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Attenuation is the sum of absorption and scattering. Attenuation is sometimes called &quot;extinction&quot;. Also called &quot;diffuse&quot; attenuation, the attenuation of downwelling radiative flux refers to the decrease with decreasing height or increasing depth of the downwelling component of radiative flux, regardless of incident direction.</description>
  </entry>
  <entry id="volume_backwards_scattering_coefficient_of_radiative_flux_in_sea_water">
    <canonical_units>m-1</canonical_units>
    <description>Radiative flux is the sum of shortwave and longwave radiative fluxes. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics. The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Scattering of radiation is its deflection from its incident path without loss of energy. Backwards scattering refers to the sum of scattering into all backward angles i.e. scattering_angle exceeding pi/2 radians. A scattering_angle should not be specified with this quantity.</description>
  </entry>
  <entry id="volume_beam_attenuation_coefficient_of_radiative_flux_in_sea_water">
    <canonical_units>m-1</canonical_units>
    <description>Radiative flux is the sum of shortwave and longwave radiative fluxes. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics. The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Attenuation is the sum of absorption and scattering. Attenuation is sometimes called &quot;extinction&quot;. Beam attenuation refers to the decrease of radiative flux along the direction of the incident path. It is distinguished from attenuation of the downwelling component of radiative flux from any incident direction, also called &quot;diffuse&quot; attenuation.</description>
  </entry>
  <entry id="volume_fraction_of_clay_in_soil">
    <canonical_units>1</canonical_units>
    <description>&quot;Volume fraction&quot; is used in the construction volume_fraction_of_X_in_Y, where X is a material constituent of Y.</description>
  </entry>
  <entry id="volume_fraction_of_condensed_water_in_soil_pores">
    <canonical_units>1</canonical_units>
    <description>&quot;Volume fraction&quot; is used in the construction volume_fraction_of_X_in_Y, where X is a material constituent of Y.  &quot;Condensed water&quot; means liquid and ice.  &quot;Volume_fraction_of_condensed_water_in_soil_pores&quot; is the ratio of the volume of condensed water in soil pores to the volume of the pores themselves.</description>
  </entry>
  <entry id="volume_fraction_of_frozen_water_in_soil">
    <canonical_units>1</canonical_units>
    <description>&quot;frozen_water&quot; means ice. &quot;Volume fraction&quot; is used in the construction volume_fraction_of_X_in_Y, where X is a material constituent of Y.</description>
  </entry>
  <entry id="volume_fraction_of_sand_in_soil">
    <canonical_units>1</canonical_units>
    <description>&quot;Volume fraction&quot; is used in the construction volume_fraction_of_X_in_Y, where X is a material constituent of Y.</description>
  </entry>
  <entry id="volume_fraction_of_silt_in_soil">
    <canonical_units>1</canonical_units>
    <description>&quot;Volume fraction&quot; is used in the construction volume_fraction_of_X_in_Y, where X is a material constituent of Y.</description>
  </entry>
  <entry id="volume_fraction_of_condensed_water_in_soil">
    <canonical_units>1</canonical_units>
    <description>&quot;Condensed water&quot; means liquid and ice. &quot;Volume fraction&quot; is used in the construction volume_fraction_of_X_in_Y, where X is a material constituent of Y.</description>
  </entry>
  <entry id="volume_fraction_of_condensed_water_in_soil_at_critical_point">
    <canonical_units>1</canonical_units>
    <description>&quot;Condensed water&quot; means liquid and ice. &quot;Volume fraction&quot; is used in the construction volume_fraction_of_X_in_Y, where X is a material constituent of Y.  When soil moisture equals or exceeds the critical point evapotranspiration takes place at the potential rate and is controlled by the ambient meteorological conditions (temperature, wind, relative humidity).  Evapotranspiration is the sum of evaporation and plant transpiration.  Potential evapotranspiration is the rate at which evapotranspiration would occur under ambient conditions from a uniformly vegetated area when the water supply is not limiting.</description>
  </entry>
  <entry id="volume_fraction_of_condensed_water_in_soil_at_field_capacity">
    <canonical_units>1</canonical_units>
    <description>&quot;Condensed water&quot; means liquid and ice. &quot;Volume fraction&quot; is used in the construction volume_fraction_of_X_in_Y, where X is a material constituent of Y. The field capacity of soil is the maximum content of water it can retain against gravitational drainage.</description>
  </entry>
  <entry id="volume_fraction_of_condensed_water_in_soil_at_wilting_point">
    <canonical_units>1</canonical_units>
    <description>&quot;Condensed water&quot; means liquid and ice. &quot;Volume fraction&quot; is used in the construction volume_fraction_of_X_in_Y, where X is a material constituent of Y. The wilting point of soil is the water content below which plants cannot extract sufficient water to balance their loss through transpiration.</description>
  </entry>
  <entry id="volume_mixing_ratio_of_oxygen_at_stp_in_sea_water">
    <canonical_units>1 </canonical_units>
    <description>&quot;ratio_of_X_to_Y&quot; means X/Y. &quot;stp&quot; means standard temperature (0 degC) and pressure (101325 Pa).</description>
  </entry>
  <entry id="volume_scattering_coefficient_of_radiative_flux_in_sea_water">
    <canonical_units>m-1</canonical_units>
    <description>Radiative flux is the sum of shortwave and longwave radiative fluxes. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics. The volume scattering/absorption/attenuation coefficient is the fractional change of radiative flux per unit path length due to the stated process. Coefficients with canonical units of m2 s-1 i.e. multiplied by density have standard names with specific_ instead of volume_. The scattering/absorption/attenuation coefficient is assumed to be an integral over all wavelengths, unless a coordinate of radiation_wavelength is included to specify the wavelength. Scattering of radiation is its deflection from its incident path without loss of energy. The (range of) direction(s) of scattering can be specified by a coordinate of scattering_angle.</description>
  </entry>
  <entry id="volume_scattering_function_of_radiative_flux_in_sea_water">
    <canonical_units>m-1 sr-1</canonical_units>
    <description>Radiative flux is the sum of shortwave and longwave radiative fluxes. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics. Scattering of radiation is its deflection from its incident path without loss of energy. The volume scattering function is the fraction of incident radiative flux scattered into unit solid angle per unit path length. The (range of) direction(s) of scattering can be specified by a coordinate of scattering_angle.</description>
  </entry>
  <entry id="water_content_of_atmosphere_layer">
    <canonical_units>kg m-2</canonical_units>
    <description>&quot;Content&quot; indicates a quantity per unit area. &quot;Layer&quot; 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. &quot;Water&quot; means water in all phases.</description>
  </entry>
  <entry id="water_evaporation_amount">
    <canonical_units>kg m-2</canonical_units>
    <grib>57</grib>
    <description>&quot;Amount&quot; means mass per unit area. &quot;Water&quot; means water in all phases. Evaporation is the conversion of liquid or solid into vapor. (The conversion of solid alone into vapor is called &quot;sublimation&quot;.)</description>
  </entry>
  <entry id="water_evaporation_amount_from_canopy">
    <canonical_units>kg m-2</canonical_units>
    <description>&quot;Amount&quot; means mass per unit area. &quot;Water&quot; means water in all phases. &quot;Canopy&quot; 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 &quot;sublimation&quot;.)</description>
  </entry>
  <entry id="water_evaporation_flux">
    <canonical_units>kg m-2 s-1</canonical_units>
    <amip>evspsbl</amip>
    <description>&quot;Water&quot; means water in all phases. Evaporation is the conversion of liquid or solid into vapor. (The conversion of solid alone into vapor is called &quot;sublimation&quot;.) In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="water_evaporation_flux_from_canopy">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;Water&quot; means water in all phases. &quot;Canopy&quot; 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 &quot;sublimation&quot;.) In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="water_evaporation_flux_from_canopy_where_land">
    <canonical_units>kg m-2 s-1</canonical_units>
    <amip>evspsblveg</amip>
    <description>Unless indicated, a quantity is assumed to apply to the whole area of each horizontal grid box. The qualifier where_type specifies instead that the quantity applies only to the part of the grid box of the named type. &quot;Water&quot; means water in all phases. &quot;Canopy&quot; 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 &quot;sublimation&quot;.) In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="water_evaporation_flux_from_soil">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;Water&quot; means water in all phases. Evaporation is the conversion of liquid or solid into vapor. (The conversion of solid alone into vapor is called &quot;sublimation&quot;.) In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="water_evaporation_flux_where_sea_ice">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>Unless indicated, a quantity is assumed to apply to the whole area of each horizontal grid box. The qualifier where_type specifies instead that the quantity applies only to the part of the grid box of the named type. &quot;Water&quot; means water in all phases. Evaporation is the conversion of liquid or solid into vapor. (The conversion of solid alone into vapor is called &quot;sublimation&quot;.) In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="water_flux_correction">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;Water&quot; means water in all phases. Flux correction is also called &quot;flux adjustment&quot;. A positive flux correction is downward i.e. added to the ocean. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="water_flux_into_sea_water">
    <canonical_units>kg m-2 s-1</canonical_units>
    <amip>wfo</amip>
    <description>&quot;Water&quot; means water in all phases. The water flux into sea water is the freshwater entering as a result of precipitation, evaporation, river inflow, sea ice effects and water flux relaxation and correction (if applied). In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="water_flux_into_sea_water_from_rivers">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;Water&quot; means water in all phases. The water flux or volume transport into sea water from rivers is the inflow to the ocean, often applied to the surface in ocean models. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="water_flux_into_sea_water_without_flux_correction">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>Water means water in all phases. The water_flux_into_sea_water_without_flux_correction  is the freshwater entering as a result of precipitation, evaporation, river inflow and sea ice effects.  The total water flux including any flux relaxation(s) or correction(s) is described by the standard name water_flux_into_sea_water.  In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="water_flux_out_of_sea_ice_and_sea_water">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;Water&quot; means water in all phases.  The water_flux_out_of_sea_ice_and_sea_water is the freshwater  leaving the ocean as a result of precipitation, evaporation, river outflow and any water flux relaxation(s) and correction(s) that may have been applied. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="water_flux_out_of_sea_water">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>The quantity water_flux_out_of_sea_water is the quantity with  standard name water_flux_into_sea_water multiplied by -1. &quot;Water&quot; means water in all phases. The water flux out of sea water is the freshwater leaving as a result of precipitation, evaporation, river outflow, sea-ice and any water flux relaxation(s) and correction(s) that may have been applied. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="water_flux_out_of_sea_water_due_to_newtonian_relaxation">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>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. The water_flux_out_of_sea_water_due_to_newtonian_relaxation is the freshwater leaving as a result of the Newtonian relaxation of the sea surface salinity. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
   </entry>
   <entry id="water_flux_out_of_sea_water_due_to_sea_ice_thermodynamics">
     <canonical_units>kg m-2 s-1</canonical_units>
     <description>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. &quot;Water&quot; means water in all phases. The water flux out of sea water is the freshwater leaving the sea water.  &quot;Sea ice thermodynamics&quot; refers to the addition or subtraction of sea ice mass due to surface and basal fluxes. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="water_potential_evaporation_amount">
    <canonical_units>kg m-2</canonical_units>
    <description>&quot;Amount&quot; means mass per unit area. &quot;Water&quot; means water in all phases. Evaporation is the conversion of liquid or solid into vapor. (The conversion of solid alone into vapor is called &quot;sublimation&quot;.) Potential evaporation is the rate at which evaporation would take place under unaltered ambient conditions (temperature, relative humidity, wind, etc.) if the supply of water were unlimited, as if from an open water surface.</description>
  </entry>
  <entry id="water_potential_evaporation_flux">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;Water&quot; means water in all phases. Evaporation is the conversion of liquid or solid into vapor. (The conversion of solid alone into vapor is called &quot;sublimation&quot;.) Potential evaporation is the rate at which evaporation would take place under unaltered ambient conditions (temperature, relative humidity, wind, etc.) if the supply of water were unlimited, as if from an open water surface. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="water_sublimation_flux">
    <canonical_units>kg m-2 s-1</canonical_units>
    <description>&quot;Water&quot; means water in all phases. Sublimation is the conversion of solid into vapor. In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="water_vapor_content_of_atmosphere_layer">
    <canonical_units>kg m-2</canonical_units>
    <description>&quot;Content&quot; indicates a quantity per unit area. &quot;Layer&quot; 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.</description>
  </entry>
  <entry id="water_vapor_pressure">
    <canonical_units>Pa</canonical_units>
    <grib>55</grib>
    <description>Vapor pressure is the partial pressure of a constituent of air, such as water, which exists as liquid or solid under &quot;normal&quot; conditions. &quot;Water&quot; is specified when the term is being applied to water.</description>
  </entry>
  <entry id="water_vapor_saturation_deficit">
    <canonical_units>Pa</canonical_units>
    <grib>56</grib>
    <description>Water vapor saturation deficit is the difference between the saturation water vapor pressure and the actual water vapor pressure.</description>
  </entry>
  <entry id="water_volume_transport_into_sea_water_from_rivers">
    <canonical_units>m3 s-1</canonical_units>
    <description>&quot;Water&quot; means water in all phases. The water flux or volume transport into sea water from rivers is the inflow to the ocean, often applied to the surface in ocean models.</description>
  </entry>
  <entry id="wave_frequency">
    <canonical_units>s-1</canonical_units>
    <description>Frequency is the number of oscillations of a wave per unit time.</description>
  </entry>
  <entry id="wet_bulb_temperature">
    <canonical_units>K</canonical_units>
    <description></description>
  </entry>
  <entry id="wind_from_direction">
    <canonical_units>degree</canonical_units>
    <grib>31</grib>
    <description>Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.) In meteorological reports, the direction of the wind vector is usually (but not always) given as the direction from which it is blowing (wind_from_direction) (westerly, northerly, etc.). In other contexts, such as atmospheric modelling, it is often natural to give the direction in the usual manner of vectors as the heading or the direction to which it is blowing (wind_to_direction) (eastward, southward, etc.) &quot;from_direction&quot; is used in the construction X_from_direction and indicates the direction from which the velocity vector of X is coming.</description>
  </entry>
  <entry id="wind_mixing_energy_flux_into_sea_water">
    <canonical_units>W m-2</canonical_units>
    <grib>126</grib>
    <description>Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.) In accordance with common usage in geophysical disciplines, &quot;flux&quot; implies per unit area, called &quot;flux density&quot; in physics.</description>
  </entry>
  <entry id="wind_speed">
    <canonical_units>m s-1</canonical_units>
    <grib>32</grib>
    <description>Speed is the magnitude of velocity. Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.) The wind speed is the magnitude of the wind velocity.</description>
  </entry>
  <entry id="wind_speed_of_gust">
    <canonical_units>m s-1</canonical_units>
    <description>Speed is the magnitude of velocity. Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.) The wind speed is the magnitude of the wind velocity. A gust is a sudden brief period of high wind speed. In an observed timeseries of wind speed, the gust wind speed can be indicated by a cell_methods of maximum for the time-interval. In an atmospheric model which has a parametrised calculation of gustiness, the gust wind speed may be separately diagnosed from the wind speed.</description>
  </entry>
  <entry id="wind_speed_shear">
    <canonical_units>s-1</canonical_units>
    <grib>N136</grib>
    <description>Speed is the magnitude of velocity. Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.) The wind speed is the magnitude of the wind velocity. Wind speed shear is the derivative of wind speed with respect to height.</description>
  </entry>
  <entry id="wind_to_direction">
    <canonical_units>degree</canonical_units>
    <description>Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.) In meteorological reports, the direction of the wind vector is usually (but not always) given as the direction from which it is blowing (wind_from_direction) (westerly, northerly, etc.). In other contexts, such as atmospheric modelling, it is often natural to give the direction in the usual manner of vectors as the heading or the direction to which it is blowing (wind_to_direction) (eastward, southward, etc.) &quot;to_direction&quot; is used in the construction X_to_direction and indicates the direction towards which the velocity vector of X is headed.</description>
  </entry>
  <entry id="x_derivative_of_ocean_rigid_lid_pressure">
    <canonical_units>N m-3</canonical_units>
    <description>&quot;component_derivative_of_X &quot; means the derivative of X with respect to distance in the component direction, which may be northward, southward, eastward, westward, x or y. The last two indicate derivatives along the axes of the grid, in the case where they are not true longitude and latitude. x_derivative_of_ocean_rigid_lid_pressure means (d/dx) of the ocean surface pressure, as derived by a rigid lid approximation, keeping the other horizontal coordinate (y, presumably) constant.</description>
  </entry>
  <entry id="x_wind">
    <canonical_units>m s-1</canonical_units>
    <description>&quot;x&quot; indicates a vector component along the grid x-axis, when this is not true longitude, positive with increasing x. Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)</description>
  </entry>
  <entry id="y_derivative_of_ocean_rigid_lid_pressure">
    <canonical_units>N m-3</canonical_units>
    <description>&quot;component_derivative_of_X &quot; means the derivative of X with respect to distance in the component direction, which may be northward, southward, eastward, westward, x or y. The last two indicate derivatives along the axes of the grid, in the case where they are not true longitude and latitude. y_derivative_of_ocean_rigid_lid_pressure means (d/dy) of the ocean surface pressure, as derived by a rigid lid approximation, keeping the other horizontal coordinate (x, presumably) constant.</description>
  </entry>
  <entry id="y_wind">
    <canonical_units>m s-1</canonical_units>
    <description>&quot;y&quot; indicates a vector component along the grid y-axis, when this is not true latitude, positive with increasing y. Wind is defined as a two-dimensional (horizontal) air velocity vector, with no vertical component. (Vertical motion in the atmosphere has the standard name upward_air_velocity.)</description>
  </entry>
  <entry id="zenith_angle">
    <canonical_units>degree</canonical_units>
    <description>Zenith angle is the angle to the local vertical; a value of zero is directly overhead.</description>
  </entry>
  <alias id="specific_convective_available_potential_energy">
    <entry_id>atmosphere_specific_convective_available_potential_energy</entry_id>
  </alias>
  <alias id="atmosphere_so4_content">
    <entry_id>atmosphere_sulfate_content</entry_id>
  </alias>
  <alias id="chlorophyll_concentration_in_sea_water">
    <entry_id>concentration_of_chlorophyll_in_sea_water</entry_id>
  </alias>
  <alias id="equivalent_thickness_at_stp_of_atmosphere_o3_content">
    <entry_id>equivalent_thickness_at_stp_of_atmosphere_ozone_content</entry_id>
  </alias>
  <alias id="longwave_radiance">
    <entry_id>isotropic_longwave_radiance_in_air</entry_id>
  </alias>
  <alias id="shortwave_radiance">
    <entry_id>isotropic_shortwave_radiance_in_air</entry_id>
  </alias>
  <alias id="spectral_radiance">
    <entry_id>isotropic_spectral_radiance_in_air</entry_id>
  </alias>
  <alias id="omega">
    <entry_id>lagrangian_tendency_of_air_pressure</entry_id>
  </alias>
  <alias id="vertical_air_velocity_expressed_as_tendency_of_pressure">
    <entry_id>lagrangian_tendency_of_air_pressure</entry_id>
  </alias>
  <alias id="upward_air_velocity_expressed_as_tendency_of_sigma">
    <entry_id>lagrangian_tendency_of_atmosphere_sigma_coordinate</entry_id>
  </alias>
  <alias id="vertical_air_velocity_expressed_as_tendency_of_sigma">
    <entry_id>lagrangian_tendency_of_atmosphere_sigma_coordinate</entry_id>
  </alias>
  <alias id="mass_fraction_of_o3_in_air">
    <entry_id>mass_fraction_of_ozone_in_air</entry_id>
  </alias>
  <alias id="mole_fraction_of_o3_in_air">
    <entry_id>mole_fraction_of_ozone_in_air</entry_id>
  </alias>
  <alias id="electromagnetic_wavelength">
    <entry_id>radiation_wavelength</entry_id>
  </alias>
  <alias id="sea_floor_depth">
    <entry_id>sea_floor_depth_below_geoid</entry_id>
  </alias>
  <alias id="sea_surface_elevation">
    <entry_id>sea_surface_height_above_geoid</entry_id>
  </alias>
  <alias id="sea_surface_elevation_anomaly">
    <entry_id>sea_surface_height_above_geoid</entry_id>
  </alias>
  <alias id="sea_surface_height">
    <entry_id>sea_surface_height_above_sea_level</entry_id>
  </alias>
  <alias id="swell_wave_period">
    <entry_id>sea_surface_swell_wave_period</entry_id>
  </alias>
  <alias id="significant_height_of_swell_waves">
    <entry_id>sea_surface_swell_wave_significant_height</entry_id>
  </alias>
  <alias id="direction_of_swell_wave_velocity">
    <entry_id>sea_surface_swell_wave_to_direction</entry_id>
  </alias>
  <alias id="significant_height_of_wind_and_swell_waves">
    <entry_id>sea_surface_wave_significant_height</entry_id>
  </alias>
  <alias id="wind_wave_period">
    <entry_id>sea_surface_wind_wave_period</entry_id>
  </alias>
  <alias id="significant_height_of_wind_waves">
    <entry_id>sea_surface_wind_wave_significant_height</entry_id>
  </alias>
  <alias id="direction_of_wind_wave_velocity">
    <entry_id>sea_surface_wind_wave_to_direction</entry_id>
  </alias>
  <alias id="x_sea_water_velocity">
    <entry_id>sea_water_x_velocity</entry_id>
  </alias>
  <alias id="y_sea_water_velocity">
    <entry_id>sea_water_y_velocity</entry_id>
  </alias>
  <alias id="specific_potential_energy">
    <entry_id>specific_gravitational_potential_energy</entry_id>
  </alias>
  <alias id="surface_downwelling_longwave_flux">
    <entry_id>surface_downwelling_longwave_flux_in_air</entry_id>
  </alias>
  <alias id="surface_downwelling_shortwave_flux">
    <entry_id>surface_downwelling_shortwave_flux_in_air</entry_id>
  </alias>
  <alias id="surface_downwelling_shortwave_flux_assuming_clear_sky">
    <entry_id>surface_downwelling_shortwave_flux_in_air_assuming_clear_sky</entry_id>
  </alias>
  <alias id="atmosphere_surface_drag_coefficient_of_heat">
    <entry_id>surface_drag_coefficient_for_heat_in_air</entry_id>
  </alias>
  <alias id="atmosphere_surface_drag_coefficient_of_momentum">
    <entry_id>surface_drag_coefficient_for_momentum_in_air</entry_id>
  </alias>
  <alias id="atmosphere_surface_drag_coefficient">
    <entry_id>surface_drag_coefficient_in_air</entry_id>
  </alias>
  <alias id="surface_upwelling_longwave_flux">
    <entry_id>surface_upwelling_longwave_flux_in_air</entry_id>
  </alias>
  <alias id="surface_upwelling_longwave_flux_assuming_clear_sky">
    <entry_id>surface_upwelling_longwave_flux_in_air_assuming_clear_sky</entry_id>
  </alias>
  <alias id="surface_upwelling_shortwave_flux">
    <entry_id>surface_upwelling_shortwave_flux_in_air</entry_id>
  </alias>
  <alias id="surface_upwelling_shortwave_flux_assuming_clear_sky">
    <entry_id>surface_upwelling_shortwave_flux_in_air_assuming_clear_sky</entry_id>
  </alias>
  <alias id="water_evaporation_amount_from_canopy_where_land">
    <entry_id>water_evaporation_amount_from_canopy</entry_id>
  </alias>
  <alias id="grid_eastward_wind">
    <entry_id>x_wind</entry_id>
  </alias>
  <alias id="grid_northward_wind">
    <entry_id>y_wind</entry_id>
  </alias>
  <alias id="volume_fraction_of_water_in_soil">
    <entry_id>volume_fraction_of_condensed_water_in_soil</entry_id>
  </alias>
  <alias id="volume_fraction_of_water_in_soil_at_critical_point">
    <entry_id>volume_fraction_of_condensed_water_in_soil_at_critical_point</entry_id>
  </alias>
  <alias id="volume_fraction_of_water_in_soil_at_field_capacity">
    <entry_id>volume_fraction_of_condensed_water_in_soil_at_field_capacity</entry_id>
  </alias>
  <alias id="volume_fraction_of_water_in_soil_at_wilting_point">
    <entry_id>volume_fraction_of_condensed_water_in_soil_at_wilting_point</entry_id>
  </alias>
  <alias id="mass_fraction_of_convective_condensed_water_in_air">
    <entry_id>mass_fraction_of_convective_cloud_condensed_water_in_air</entry_id>
  </alias>
  <alias id="surface_eastward_geostrophic_sea_water_velocity">
    <entry_id>surface_geostrophic_eastward_sea_water_velocity</entry_id>
  </alias>
  <alias id="surface_eastward_geostrophic_sea_water_velocity_assuming_sea_level_for_geoid">
    <entry_id>surface_geostrophic_eastward_sea_water_velocity_assuming_sea_level_for_geoid</entry_id>
  </alias>
  <alias id="surface_northward_geostrophic_sea_water_velocity">
    <entry_id>surface_geostrophic_northward_sea_water_velocity</entry_id>
  </alias>
  <alias id="surface_northward_geostrophic_sea_water_velocity_assuming_sea_level_for_geoid">
    <entry_id>surface_geostrophic_northward_sea_water_velocity_assuming_sea_level_for_geoid</entry_id>
  </alias>
  <alias id="sea_surface_wave_frequency">
    <entry_id>wave_frequency</entry_id>
  </alias>
  <alias id="eastward_transformed_eulerian_mean_velocity">
    <entry_id>eastward_transformed_eulerian_mean_air_velocity</entry_id>
  </alias>
  <alias id="northward_eliassen_palm_flux">
    <entry_id>northward_eliassen_palm_flux_in_air</entry_id>
  </alias>
  <alias id="northward_heat_flux_due_to_eddy_advection">
    <entry_id>northward_heat_flux_in_air_due_to_eddy_advection</entry_id>
  </alias>
  <alias id="northward_transformed_eulerian_mean_velocity">
    <entry_id>northward_transformed_eulerian_mean_air_velocity</entry_id>
  </alias>
  <alias id="upward_eliassen_palm_flux">
    <entry_id>upward_eliassen_palm_flux_in_air</entry_id>
  </alias>
  <alias id="upward_flux_of_eastward_momentum_due_to_nonorographic_eastward_gravity_waves">
    <entry_id>upward_eastward_momentum_flux_in_air_due_to_nonorographic_eastward_gravity_waves</entry_id>
  </alias>
  <alias id="upward_flux_of_eastward_momentum_due_to_nonorographic_westward_gravity_waves">
    <entry_id>upward_eastward_momentum_flux_in_air_due_to_nonorographic_westward_gravity_waves</entry_id>
  </alias>
  <alias id="upward_flux_of_eastward_momentum_due_to_orographic_gravity_waves">
    <entry_id>upward_eastward_momentum_flux_in_air_due_to_orographic_gravity_waves</entry_id>
  </alias>
  <alias id="water_flux_into_ocean">
    <entry_id>water_flux_into_sea_water</entry_id>
  </alias>
  <alias id="water_flux_into_ocean_from_rivers">
    <entry_id>water_flux_into_sea_water_from_rivers</entry_id>
  </alias>
  <alias id="water_volume_transport_into_ocean_from_rivers">
    <entry_id>water_volume_transport_into_sea_water_from_rivers</entry_id>
  </alias>
  <alias id="wind_mixing_energy_flux_into_ocean">
    <entry_id>wind_mixing_energy_flux_into_sea_water</entry_id>
  </alias>
</standard_name_table>