GEOS-5

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__FORCETOC__
===Import States===
 
Sorted 577 states by Component name - within each component, variables are sorted by their short name
{| class="wikitable"
|+ List of GEOS-5 [IM] State variables
! Name !! Component !! Units !! Dim !! Long name
|-
| DOXANA || ARIESg3 || kg kg-1 || xyz || ozone increment from analysis
|-
| DPEDT || ARIESg3 || Pa s-1 || xyz || edge pressure tendency
|-
| DQVANA || ARIESg3 || kg kg-1 || xyz || specific humidity increment from analysis
|-
| DTDT || ARIESg3 || Pa K s-1 || xyz || delta-p weighted temperature tendency
|-
| DUDT || ARIESg3 || m s-2 || xyz || eastward wind tendency
|-
| DVDT || ARIESg3 || m s-2 || xyz || northward wind tendency
|-
| PHIS || ARIESg3 || m+2 sec-2 || xy || surface geopotential height
|-
| TRADV || ARIESg3 || unknown || xy || advected quantities
|-
| DO3DT || Agcm || ppmv || xyz || ozone analysis increment
|-
| DPEDT || Agcm || Pa || xyz || edge pressure analysis increment
|-
| DQVDT || Agcm || kg kg-1 || xyz || specific humidity analysis increment
|-
| DTDT || Agcm || K || xyz || temperature analysis increment
|-
| DTSDT || Agcm || K || xy || skin temperature increment
|-
| DUDT || Agcm || m s-1 || xyz || eastward wind analysis increment
|-
| DVDT || Agcm || m s-1 || xyz || northward wind analysis increment
|-
| AIRDENS || CARMA || kg m-3 || xyz || Air density
|-
| AREA || CARMA || m2 || xy || agrid cell area
|-
| CNV_MFC || CARMA || kg m-2 s-1 || xyz || cumulative mass flux
|-
| CNV_MFD || CARMA || kg m-2 s-1 || xyz || detraining mass flux
|-
| CNV_QC || CARMA || kg kg-1 || xyz || grid mean convective condensate
|-
| CN_PRCP || CARMA || kg m-2 s-1 || xy || Surface Conv. rain flux needed by land
|-
| DQDT || CARMA || kg kg-1 s-1 || xyz || Q tendency - moist physics
|-
| FRACI || CARMA || 1 || xy || Ice  fraction
|-
| FRLAKE || CARMA || 1 || xy || Lake fraction
|-
| FROCEAN || CARMA || 1 || xy || Ocean fraction
|-
| LWI || CARMA || 1 || xy || Land Ocean Ice Mask
|-
| NCN_PRCP || CARMA || kg m-2 s-1 || xy || Non-convective Precipitation
|-
| PLE || CARMA || Pa || xyz || Layer interface pressure
|-
| Q || CARMA || kg kg-1 || xyz || Specific Humidity
|-
| RH2 || CARMA || 1 || xyz || Relative Humidity after Moist
|-
| SH || CARMA || W m-2 || xy || Sensible Heat Flux
|-
| T || CARMA || K || xyz || Air Temperature (from Dynamics)
|-
| U || CARMA || m s-1 || xyz || Eastward (EW) wind
|-
| U10M || CARMA || m s-1 || xy || EW 10-meter wind speed
|-
| USTAR || CARMA || m s-1 || xy || Friction Speed
|-
| V || CARMA || m s-1 || xyz || Northward (NS) wind
|-
| V10M || CARMA || m s-1 || xy || NS 10-meter wind speed
|-
| WET1 || CARMA || 1 || xy || Surface Soil Wetness
|-
| Z0H || CARMA || m || xy || Roughness Length for Heat
|-
| ZLE || CARMA || m || xyz || Layer interface geopot height
|-
| ZPBL || CARMA || m || xy || PBL Height
|-
| ALW || Catch || W m-2 || tile || linearization of surface upwelling longwave flux
|-
| BLW || Catch || W_m-2 K-1 || tile || linearization of surface upwelling longwave flux
|-
| CQATM || Catch || kg m-2 s-1 || tile || surface exchange coefficient for moisture
|-
| CTATM || Catch || kg m-2 s-1 || tile || surface exchange coefficient for heat
|-
| DEVAP || Catch || kg m-2 s-1 || tile || derivative of evaporation wrt QS
|-
| DFNIR || Catch || W m-2 || tile || surface downwelling nir diffuse flux
|-
| DFPAR || Catch || W m-2 || tile || surface downwelling par diffuse flux
|-
| DFUVR || Catch || W m-2 || tile || surface downwelling uvr diffuse flux
|-
| DRNIR || Catch || W m-2 || tile || surface downwelling nir beam flux
|-
| DRPAR || Catch || W m-2 || tile || surface downwelling par beam flux
|-
| DRUVR || Catch || W m-2 || tile || surface downwelling uvr beam flux
|-
| DSH || Catch || W m-2 K-1 || tile || derivative of sensible heat wrt Ts
|-
| DZ || Catch || m || tile || surface layer height
|-
| EVAP || Catch || kg m-2 s-1 || tile || evaporation
|-
| GRN || Catch || 1 || tile || greeness fraction
|-
| ITY || Catch || 1 || tile || vegetation type
|-
| LAI || Catch || 1 || tile || leaf area index
|-
| LWDNSRF || Catch || W m-2 || tile || surface downwelling longwave flux
|-
| PCU || Catch || kg m-2 s-1 || tile || liquid water convective precipitation
|-
| PLS || Catch || kg m-2 s-1 || tile || liquid water large scale precipitation
|-
| PS || Catch || Pa || tile || surface pressure
|-
| QA || Catch || kg kg-1 || tile || surface air specific humidity
|-
| QHATM || Catch || kg kg-1 || tile || effective surface specific humidity
|-
| ROOTL || Catch || m || tile || vegetation root length
|-
| SH || Catch || W m-2 || tile || upward sensible heat flux
|-
| SNO || Catch || kg m-2 s-1 || tile || snowfall
|-
| TA || Catch || K || tile || surface air temperature
|-
| THATM || Catch || K || tile || effective surface skin temperature
|-
| UU || Catch || m s-1 || tile || surface wind speed
|-
| UWINDLMTILE || Catch || m s-1 || tile || levellm uwind
|-
| VWINDLMTILE || Catch || m s-1 || tile || levellm vwind
|-
| Z2CH || Catch || m || tile || canopy height
|-
| CN_PRCP || ChemEnv || kg m-2 s-1 || xy || Surface Conv. rain flux needed by land
|-
| FRACI || ChemEnv || 1 || xy || ice covered fraction of tile
|-
| FRLAND || ChemEnv || 1 || xy || fraction of land
|-
| FRLANDICE || ChemEnv || 1 || xy || fraction of land ice
|-
| FROCEAN || ChemEnv || 1 || xy || fraction of ocean
|-
| PLE || ChemEnv || Pa || xyz || air pressure
|-
| Q || ChemEnv || kg kg-1 || xyz || specific humidity
|-
| TH || ChemEnv || K || xyz || potential temperature
|-
| TPREC || ChemEnv || kg m-2 s-1 || xy || total precipitation
|-
| TS || ChemEnv || K || xy || TS
|-
| OX || DFI || ppmv || xyz || molecular oxigen
|-
| PE || DFI || Pa || xyz || air pressure
|-
| PT || DFI || K Pa$^{-\kappa}$ || xyz || scaled potential temperature
|-
| Q || DFI || kg kg^${-1}$ || xyz || specific humidity
|-
| U_DGRID || DFI || m s-1 || xyz || eastward wind
|-
| V_DGRID || DFI || m s-1 || xyz || northward wind
|-
| HW || DataSea || m || xy || water skin layer depth
|-
| SW || DataSea || psu || xy || water skin salinity
|-
| SWHEAT || DataSea || W m-2 || xyz || solar heating rate
|-
| TW || DataSea || K || xy || water skin temperature
|-
| HI || DataSeaIce || m || xy || seaice skin layer depth
|-
| HW || DataSeaIce || kg m-2 || xy || water skin layer mass
|-
| SI || DataSeaIce || psu || xy || seaice skin salinity
|-
| SW || DataSeaIce || psu || xy || water skin salinity
|-
| TI || DataSeaIce || K || xy || seaice skin temperature
|-
| TW || DataSeaIce || K || xy || water skin temperature
|-
| DOXANA || DatmoDyn || kg kg-1 || xyz || ozone increment from analysis
|-
| DPEDT || DatmoDyn || Pa || xyz || air pressure
|-
| DQVANA || DatmoDyn || kg kg-1 || xyz || specific humidity increment from analysis
|-
| DTDT || DatmoDyn || K s-1 || xyz || T tendency
|-
| DUDT || DatmoDyn || m s-1 s-1 || xyz || later
|-
| DVDT || DatmoDyn || m s-1 s-1 || xyz || later
|-
| PHIS || DatmoDyn || m+2 sec-2 || xy || surface geopotential height
|-
| TRADV || DatmoDyn || unknown || xy || advected quantities
|-
| DOXANA || DynCore || kg kg-1 || xyz || ozone increment from analysis
|-
| DPEDT || DynCore || Pa s-1 || xyz || edge pressure tendency
|-
| DQVANA || DynCore || kg kg-1 || xyz || specific humidity increment from analysis
|-
| DTDT || DynCore || Pa K s-1 || xyz || delta-p weighted temperature tendency
|-
| DUDT || DynCore || m s-2 || xyz || eastward wind tendency
|-
| DVDT || DynCore || m s-2 || xyz || northward wind tendency
|-
| PHIS || DynCore || m+2 s-2 || xy || surface geopotential height
|-
| TRADV || DynCore || unknown || xy || advected quantities
|-
| DOXANA || FVdycore || kg kg-1 || xyz || ozone increment from analysis
|-
| DPEDT || FVdycore || Pa s-1 || xyz || edge pressure tendency
|-
| DQVANA || FVdycore || kg kg-1 || xyz || specific humidity increment from analysis
|-
| DTDT || FVdycore || Pa K s-1 || xyz || delta-p weighted temperature tendency
|-
| DUDT || FVdycore || m s-2 || xyz || eastward wind tendency
|-
| DVDT || FVdycore || m s-2 || xyz || northward wind tendency
|-
| PHIS || FVdycore || m+2 s-2 || xy || surface geopotential height
|-
| TRADV || FVdycore || unknown || xy || advected quantities
|-
| BCphilic || GAAS || kgkg || xyz || Hydrophilic Black Carbon Mixing Ratio
|-
| BCphobic || GAAS || kgkg || xyz || Hydrophobic Black Carbon Mixing Ratio
|-
| DELP || GAAS || Pa || xyz || Pressure Thickness
|-
| OCphilic || GAAS || kgkg || xyz || Hydrophilic Organic Carbon Mixing Ratio
|-
| OCphobic || GAAS || kgkg || xyz || Hydrophobic Organic Carbon Mixing Ratio
|-
| RH2 || GAAS || 1 || xyz || Relative Humidity
|-
| SO4 || GAAS || kgkg || xyz || SO4 Mixing Ratio
|-
| du001 || GAAS || kgkg || xyz || Dust Mixing Ratio Bin 1
|-
| du002 || GAAS || kgkg || xyz || Dust Mixing Ratio Bin 2
|-
| du003 || GAAS || kgkg || xyz || Dust Mixing Ratio Bin 3
|-
| du004 || GAAS || kgkg || xyz || Dust Mixing Ratio Bin 4
|-
| du005 || GAAS || kgkg || xyz || Dust Mixing Ratio Bin 5
|-
| ss001 || GAAS || kgkg || xyz || Sea Salt Mixing Ratio Bin 1
|-
| ss002 || GAAS || kgkg || xyz || Sea Salt Mixing Ratio Bin 2
|-
| ss003 || GAAS || kgkg || xyz || Sea Salt Mixing Ratio Bin 3
|-
| ss004 || GAAS || kgkg || xyz || Sea Salt Mixing Ratio Bin 4
|-
| ss005 || GAAS || kgkg || xyz || Sea Salt Mixing Ratio Bin 5
|-
| AIRDENS || GMICHEM || kg m-3 || xyz || air density
|-
| ALBVF || GMICHEM || 1 || xy || surface albedo for visible diffuse
|-
| AREA || GMICHEM || m^2 || xy || agrid cell area
|-
| ASNOW || GMICHEM || 1 || xy || fractional area of land snowcover
|-
| CLDTT || GMICHEM || 1 || xy || total cloud area fraction
|-
| CNV_MFC || GMICHEM || kg m-2 s-1 || xyz || cumulative mass flux
|-
| CNV_MFD || GMICHEM || kg m-2 s-1 || xyz || detraining mass flux
|-
| CN_PRCP || GMICHEM || kg m-2 s-1 || xy || convective precipitation
|-
| DFPAR || GMICHEM || W m-2 || xy || surface downwelling par diffuse flux
|-
| DQDT || GMICHEM || s-1 || xyz || specific humidity tendency due to moist
|-
| DRPAR || GMICHEM || W m-2 || xy || surface downwelling par beam flux
|-
| FCLD || GMICHEM || fraction || xyz || cloud fraction for radiation
|-
| FRLAND || GMICHEM || 1 || xy || fraction of land
|-
| FRLANDICE || GMICHEM || 1 || xy || fraction of land ice
|-
| LAI || GMICHEM || 1 || xy || leaf area index
|-
| LFR || GMICHEM || km-2 s-1 || xy || lightning flash rate
|-
| LWI || GMICHEM || 1 || xy || land-ocean-ice mask
|-
| PFL_CN || GMICHEM || kg m-2 s-1 || xyz || 3D flux of liquid convective precipitation
|-
| PFL_LSAN || GMICHEM || kg m-2 s-1 || xyz || 3D flux of liquid nonconvective precipitation
|-
| PLE || GMICHEM || Pa || xyz || air pressure
|-
| Q || GMICHEM || kg kg-1 || xyz || specific humidity
|-
| QCTOT || GMICHEM || kg kg-1 || xyz || mass fraction of total cloud water
|-
| QL || GMICHEM || kg kg-1 || xyz || cloud liquid for radiation
|-
| RH2 || GMICHEM || 1 || xyz || relative humidity after moist
|-
| SWNDSRF || GMICHEM || W m-2 || xy || surface net downward shortwave flux
|-
| T || GMICHEM || K || xyz || air temperature
|-
| T2M || GMICHEM || K || xy || 2-meter air temperature
|-
| TA || GMICHEM || K || xy || surface air temperature
|-
| TAUCLI || GMICHEM || 1 || xyz || optical thickness for ice clouds
|-
| TAUCLW || GMICHEM || 1 || xyz || optical thickness for liquid clouds
|-
| TPREC || GMICHEM || kg m-2 s-1 || xy || total precipitation
|-
| TROPP || GMICHEM || Pa || xy || tropopause pressure based on blended estimate
|-
| U10M || GMICHEM || m s-1 || xy || 10-meter eastward wind
|-
| USTAR || GMICHEM || m s-1 || xy || surface velocity scale
|-
| V10M || GMICHEM || m s-1 || xy || 10-meter northward wind
|-
| WET1 || GMICHEM || 1 || xy || surface soil wetness
|-
| Z0H || GMICHEM || m || xy || surface roughness for heat
|-
| ZLE || GMICHEM || m || xyz || geopotential height
|-
| ZPBL || GMICHEM || m || xy || planetary boundary layer height
|-
| UNKNOWN || GMIchem || state%chemReg%vunits(n) || xyz || state%chemReg%vtitle(n)
|-
| UNKNOWN || GMIchem || state%chemReg%vunits(n) || xyz || state%chemReg%vtitle(n)
|-
| AIRDENS || GOCART || kgm^3 || xyz || air density
|-
| AREA || GOCART || m^2 || xy || agrid cell area
|-
| CH4 || GOCART || molmol || xyz || Methane
|-
| CNV_MFC || GOCART || kg m-2 s-1 || xyz || cumulative mass flux
|-
| CNV_MFD || GOCART || kg m-2 s-1 || xyz || detraining mass flux
|-
| CNV_QC || GOCART || kg kg-1 || xyz || grid mean convective condensate
|-
| CN_PRCP || GOCART || kgm^2s || xy || Surface Conv. rain flux needed by land
|-
| DQDT || GOCART || kgkgs || xyz || Q tendency - moist physics
|-
| DQRL || GOCART || kgkgs || xyz || Large Scale Rainwater Source - moist physics
|-
| DZ || GOCART || m || xy || surface layer height
|-
| FCLD || GOCART || 1 || xyz || Cloud fraction for radiation
|-
| FRACI || GOCART || 1 || xy || ice covered fraction of tile
|-
| FRLAKE || GOCART || 1 || xy || fraction of lake
|-
| FROCEAN || GOCART || 1 || xy || fraction of ocean
|-
| GRN || GOCART || 1 || xy || greeness fraction
|-
| H2O2 || GOCART || molmol || xyz || Hydrogen peroxide
|-
| LAI || GOCART || 1 || xy || leaf area index
|-
| LWI || GOCART || 1 || xy || land-ocean-ice mask
|-
| NCN_PRCP || GOCART || kgm^2s || xy || Non-convective precipitation
|-
| NO3 || GOCART || molmol || xyz || Nitrogen trioxide
|-
| O3 || GOCART || kgkg || xyz || ozone mass mixing ratio
|-
| OH || GOCART || molmol || xyz || Hydroxyl radical
|-
| PLE || GOCART || Pa || xyz || air pressure
|-
| PS || GOCART || Pa || xy || surface pressure
|-
| RH2 || GOCART || 1 || xyz || Rel Hum after moist
|-
| SH || GOCART || W m-2 || xy || sensible heat flux from turbulence
|-
| T || GOCART || K || xyz || air temperature
|-
| TA || GOCART || K || xy || surface temperature from surface
|-
| TROPP || GOCART || Pa || xy || tropopause pressure based on blended estimate
|-
| TS || GOCART || K || xy || surface skin temperature
|-
| TSOIL1 || GOCART || K || xy || soil temperatures layer 1
|-
| U || GOCART || m s-1 || xyz || eastward wind
|-
| U10M || GOCART || m s-1 || xy || 10-meter eastward wind
|-
| U10N || GOCART || m s-1 || xy || equivalent neutral 10-meter eastward wind
|-
| USTAR || GOCART || m s-1 || xy || surface velocity scale
|-
| V || GOCART || m s-1 || xyz || northward wind
|-
| V10M || GOCART || m s-1 || xy || 10-meter northward wind
|-
| V10N || GOCART || m s-1 || xy || equivalent neutral 10-meter northward wind
|-
| WET1 || GOCART || 1 || xy || surface soil wetness
|-
| Z0H || GOCART || m || xy || surface roughness for heat
|-
| ZLE || GOCART || m || xyz || geopotential height
|-
| ZPBL || GOCART || m || xy || Planetary boundary layer height
|-
| LS_PRCP || Gwd || kg m-2 s-1 || xy || Total LS Surface precipitation flux
|-
| PLE || Gwd || Pa || xyz || air pressure
|-
| PREF || Gwd || Pa || z || reference air pressure
|-
| Q || Gwd || kg kg-1 || xyz || specific humidity
|-
| QI || Gwd || kg kg-1 || xyz || specific humidity of suspended ice
|-
| SGH || Gwd || m || xy || standard deviation of topography
|-
| T || Gwd || K || xyz || air temperature
|-
| U || Gwd || m s-1 || xyz || eastward wind
|-
| V || Gwd || m s-1 || xyz || northward wind
|-
| AGCM_Exports || IAU || X || xy || export iau increments
|-
| DO3DT || IAU || ppmv || xyz || ozone analysis increment
|-
| DPEDT || IAU || Pa || xyz || edge pressure analysis increment
|-
| DQVDT || IAU || kg kg-1 || xyz || specific humidity analysis increment
|-
| DTDT || IAU || K || xyz || temperature analysis increment
|-
| DTSDT || IAU || K || xy || skin temparature increment
|-
| DUDT || IAU || m s-1 || xyz || eastward wind analysis increment
|-
| DVDT || IAU || m s-1 || xyz || northward wind analysis increment
|-
| AERO || Irrad || 1 || xyz || aerosols
|-
| CFC11 || Irrad || pppv || xyz || CFC11 concentration
|-
| CFC12 || Irrad || pppv || xyz || CFC12 concentration
|-
| CH4 || Irrad || pppv || xyz || methane concentration
|-
| EMIS || Irrad || 1 || xy || surface emissivity
|-
| FCLD || Irrad || 1 || xyz || cloud area fraction in atmosphere layer
|-
| HCFC22 || Irrad || pppv || xyz || HCFC22 concentration
|-
| N2O || Irrad || pppv || xyz || nitrous oxide concentration
|-
| O3 || Irrad || kg kg-1 || xyz || ozone mass mixing ratio
|-
| PLE || Irrad || Pa || xyz || air pressure
|-
| PREF || Irrad || Pa || z || reference air pressure
|-
| QI || Irrad || kg kg-1 || xyz || mass fraction of cloud ice in air
|-
| QL || Irrad || kg kg-1 || xyz || mass fraction of cloud liquid water in air
|-
| QR || Irrad || kg kg-1 || xyz || mass fraction of rain water in air
|-
| QS || Irrad || kg kg-1 || xyz || mass fraction of snow in air
|-
| QV || Irrad || kg kg-1 || xyz || specific humidity
|-
| RI || Irrad || m || xyz || effective radius of cloud ice particles
|-
| RL || Irrad || m || xyz || effective radius of cloud liquid water particles
|-
| RR || Irrad || m || xyz || effective radius of rain particles
|-
| RS || Irrad || m || xyz || effective radius of snow particles
|-
| T || Irrad || K || xyz || air temperature
|-
| TS || Irrad || K || xy || surface skin temperature
|-
| TSINST || Irrad || K || xy || surface skin temperature
|-
| ALW || Lake || W m-2 || tile || linearization of surface upwelling longwave flux
|-
| BLW || Lake || W m-2 K-1 || tile || linearization of surface upwelling longwave flux
|-
| CQATM || Lake || kg m-2 s-1 || tile || surface exchange coefficient for moisture
|-
| CTATM || Lake || kg m-2 s-1 || tile || surface exchange coefficient for heat
|-
| DEVAP || Lake || kg m-2 s-1 || tile || derivative of evaporation
|-
| DFNIR || Lake || W m-2 || tile || surface downwelling nir diffuse flux
|-
| DFPAR || Lake || W m-2 || tile || surface downwelling par diffuse flux
|-
| DFUVR || Lake || W m-2 || tile || surface downwelling uvr diffuse flux
|-
| DRNIR || Lake || W m-2 || tile || surface downwelling nir beam flux
|-
| DRPAR || Lake || W m-2 || tile || surface downwelling par beam flux
|-
| DRUVR || Lake || W m-2 || tile || surface downwelling uvr beam flux
|-
| DSH || Lake || W m-2 || tile || derivative of upward sensible heat flux
|-
| DZ || Lake || m || tile || surface layer height
|-
| EVAP || Lake || kg m-2 s-1 || tile || evaporation
|-
| LWDNSRF || Lake || W m-2 || tile || surface downwelling longwave flux
|-
| PCU || Lake || kg m-2 s-1 || tile || liquid water convective precipitation
|-
| PLS || Lake || kg m-2 s-1 || tile || liquid water large scale precipitation
|-
| PS || Lake || Pa || tile || surface pressure
|-
| QA || Lake || kg kg-1 || tile || surface air specific humidity
|-
| QHATM || Lake || kg kg-1 || tile || effective surface specific humidity
|-
| SH || Lake || W m-2 || tile || upward sensible heat flux
|-
| SNO || Lake || kg m-2 s-1 || tile || snowfall
|-
| TA || Lake || K || tile || surface air temperature
|-
| THATM || Lake || K || tile || effective surface skin temperature
|-
| UU || Lake || m s-1 || tile || surface wind speed
|-
| UWINDLMTILE || Lake || m s-1 || tile || levellm uwind
|-
| VWINDLMTILE || Lake || m s-1 || tile || levellm vwind
|-
| ALW || Landice || W m-2 || tile || linearization of surface upwelling longwave flux
|-
| BLW || Landice || W m-2 K-1 || tile || linearization of surface upwelling longwave flux
|-
| CQATM || Landice || kg m-2 s-1 || tile || surface exchange coefficient for moisture
|-
| CTATM || Landice || kg m-2 s-1 || tile || surface exchange coefficient for heat
|-
| DEVAP || Landice || kg m-2 s-1 || tile || derivative of evaporation
|-
| DFNIR || Landice || W m-2 || tile || surface downwelling nir diffuse flux
|-
| DFPAR || Landice || W m-2 || tile || surface downwelling par diffuse flux
|-
| DFUVR || Landice || W m-2 || tile || surface downwelling uvr diffuse flux
|-
| DRNIR || Landice || W m-2 || tile || surface downwelling nir beam flux
|-
| DRPAR || Landice || W m-2 || tile || surface downwelling par beam flux
|-
| DRUVR || Landice || W m-2 || tile || surface downwelling uvr beam flux
|-
| DSH || Landice || W m-2 || tile || derivative of upward sensible heat flux
|-
| DZ || Landice || m || tile || surface layer height
|-
| EVAP || Landice || kg m-2 s-1 || tile || evaporation
|-
| LWDNSRF || Landice || W m-2 || tile || surface downwelling longwave flux
|-
| PCU || Landice || kg m-2 s-1 || tile || liquid water convective precipitation
|-
| PLS || Landice || kg m-2 s-1 || tile || liquid water large scale precipitation
|-
| PS || Landice || Pa || tile || surface pressure
|-
| QA || Landice || kg kg-1 || tile || surface air specific humidity
|-
| QHATM || Landice || kg kg-1 || tile || effective surface specific humidity
|-
| SH || Landice || W m-2 || tile || upward sensible heat flux
|-
| SNO || Landice || kg m-2 s-1 || tile || snowfall
|-
| TA || Landice || K || tile || surface air temperature
|-
| THATM || Landice || K || tile || effective surface skin temperature
|-
| UU || Landice || m s-1 || tile || surface wind speed
|-
| UWINDLMTILE || Landice || m s-1 || tile || levellm uwind
|-
| VWINDLMTILE || Landice || m s-1 || tile || levellm vwind
|-
| AIRDENS || MAMchem || kgm3 || xyz || Air density
|-
| CN_PRCP || MAMchem || kgm2s || xy || Conv precip @ground
|-
| DELP || MAMchem || Pa || xyz || Pressure thickness
|-
| DQDT || MAMchem || kg kg-1 s-1 || xyz || Q tendency - moist physics
|-
| FCLD || MAMchem || 1 || xyz || Cloud fraction
|-
| FRACI || MAMchem || 1 || xy || Ice  fraction
|-
| FRLAKE || MAMchem || 1 || xy || Lake fraction
|-
| FRLAND || MAMchem || 1 || xy || Land fraction
|-
| GINOUX_DU || MAMchem || 1 || xy || Ginoux dust source
|-
| LAI || MAMchem ||  || xy || Leaf area index
|-
| LWI || MAMchem ||  || xy || Land-water-ice flags
|-
| NCN_PRCP || MAMchem || kgm^2s || xy || Non-convective precipitation
|-
| PLE || MAMchem || Pa || xyz || Edge pressure
|-
| Q || MAMchem || kg kg-1 || xyz || Specific Humidity
|-
| RH2 || MAMchem || 1 || xyz || Relative humidity
|-
| SH || MAMchem || Wm2 || xy || Sensible heat flux
|-
| T || MAMchem || K || xyz || Air Temperature (from Dynamics)
|-
| TROPP || MAMchem || Pa || xy || Tropopause pressure
|-
| U || MAMchem || m s-1 || xyz || Eastward (EW) wind
|-
| U10M || MAMchem || m s-1 || xy || EW 10-meter wind speed
|-
| U10N || MAMchem || m s-1 || xy || Equivalent neutral 10-meter eastward wind speed
|-
| USTAR || MAMchem || m s-1 || xy || Surface (friction) velocity scale
|-
| V || MAMchem || m s-1 || xyz || Northward (NS) wind
|-
| V10M || MAMchem || m s-1 || xy || NS 10-meter wind speed
|-
| V10N || MAMchem || m s-1 || xy || Equivalent neutral 10-meter northward wind speed
|-
| WET1 || MAMchem || 1 || xy || Surface Soil Wetness
|-
| ZLE || MAMchem || m || xyz || Edge heights
|-
| ZPBL || MAMchem || m || xy || PBL depth
|-
| FRLAND || Moist || 1 || xy || areal land fraction
|-
| FROCEAN || Moist || 1 || xy || areal ocean fraction
|-
| KH || Moist || m+2 s-1 || xyz || scalar diffusivity
|-
| MTR || Moist || X || xyz || tracers for moist
|-
| PLE || Moist || Pa || xyz || air pressure
|-
| PREF || Moist || Pa || z || reference air pressure
|-
| TH || Moist || K || xyz || potential temperature
|-
| TS || Moist || K || xy || surface temperature
|-
| U || Moist || m s-1 || xyz || eastward wind
|-
| V || Moist || m s-1 || xyz || northward wind
|-
| ZPBL || Moist || m || xy || planetary boundary layer height
|-
| BCDP || Ogcm || kg m-2 s-1 || tile || Black Carbon Dry Deposition
|-
| BCWT || Ogcm || kg m-2 s-1 || tile || Black Carbon Wet Deposition
|-
| CO2SC || Ogcm || 1e-6 || tile || CO2 Surface Concentration Bin 001
|-
| DAIDTD || Ogcm || % day-1 || tile || ice area tendency dueto dynamics
|-
| DISCHRG || Ogcm || kg m-2 s-1 || tile || river discharge at ocean points
|-
| DUDP || Ogcm || kg m-2 s-1 || tile || Dust Dry Deposition
|-
| DUSD || Ogcm || kg m-2 s-1 || tile || Dust Sedimentation
|-
| DUWT || Ogcm || kg m-2 s-1 || tile || Dust Wet Deposition
|-
| DVIDTD || Ogcm || cm day-1 || tile || ice volume tendency dueto dynamics
|-
| ERGICE || Ogcm || J m-2 || tile || ice category layer internal energy
|-
| ERGSNO || Ogcm || J m-2 || tile || snow category layer internal energy
|-
| FRACICE || Ogcm || 1 || tile || fractional cover of seaice
|-
| FSWBAND || Ogcm || W m-2 || tile || net surface downward shortwave flux per band in air
|-
| FSWBANDNA || Ogcm || W m-2 || tile || net surface downward shortwave flux per band in air assuming no aerosol
|-
| HI || Ogcm || kg || tile || seaice skin layer mass
|-
| HW || Ogcm || kg || tile || water skin layer mass
|-
| MPOND || Ogcm || m || tile || pond volume
|-
| OCDP || Ogcm || kg m-2 s-1 || tile || Organic Carbon Dry Deposition
|-
| OCWT || Ogcm || kg m-2 s-1 || tile || Organic Carbon Wet Deposition
|-
| OUSTAR3 || Ogcm || m+3 s-3 || tile || ocean ustar cubed
|-
| PENPAF || Ogcm || W m-2 || tile || net downward penetrating diffuse PAR flux
|-
| PENPAR || Ogcm || W m-2 || tile || net downward penetrating direct PAR flux
|-
| PENUVF || Ogcm || W m-2 || tile || net downward penetrating diffuse UV flux
|-
| PENUVR || Ogcm || W m-2 || tile || net downward penetrating direct UV flux
|-
| PS || Ogcm || Pa || tile || surface air pressure
|-
| SI || Ogcm || psu || tile || seaice skin salinity
|-
| SW || Ogcm || psu || tile || water skin salinity
|-
| TAUAGE || Ogcm || s || tile || volume weighted mean ice age
|-
| TAUXI || Ogcm || N m-2 || tile || eastward stress on ice
|-
| TAUXW || Ogcm || N m-2 || tile || eastward stress on ocean
|-
| TAUYI || Ogcm || N m-2 || tile || northward stress on ice
|-
| TAUYW || Ogcm || N m-2 || tile || northward stress on ocean
|-
| TI || Ogcm || K || tile || seaice skin temperature
|-
| TI || Ogcm || K || tile || seaice skin temperature
|-
| TW || Ogcm || K || tile || water skin temperature
|-
| UU || Ogcm || m s-1 || tile || surface wind speed
|-
| VOLICE || Ogcm || m || tile || ice category volume per unit area of grid cell
|-
| VOLSNO || Ogcm || m || tile || sno category volume per unit area of grid cell
|-
| COSZ || Orad || 1 || xy || cosine of the solar zenith angle
|-
| FROCEAN || Orad || 1 || xy || ocean fraction of grid cell
|-
| H || Orad || dyn-m || xyz || Layer mass
|-
| PENPAF || Orad || W m-2 || xy || net downward penetrating diffuse PAR flux
|-
| PENPAR || Orad || W m-2 || xy || net downward penetrating direct PAR flux
|-
| PENUVF || Orad || W m-2 || xy || net downward penetrating diffuse UV flux
|-
| PENUVR || Orad || W m-2 || xy || net downward penetrating direct UV flux
|-
| PLE || PChem || Pa || xyz || air pressure
|-
| Q || PChem || kg kg-1 || xyz || specific humidity
|-
| TROPP || PChem || Pa || xy || tropopause pressure
|-
| DZ || Physics || m || xy || surface layer height
|-
| PLE || Physics || Pa || xyz || air pressure
|-
| S || Physics || m+2 s-2 || xyz || dry static energy
|-
| T || Physics || K || xyz || air temperature
|-
| TH || Physics || K || xyz || potential temperature
|-
| U || Physics || m s-1 || xyz || eastward wind
|-
| V || Physics || m s-1 || xyz || northward wind
|-
| ZLE || Physics || m || xyz || geopotential height
|-
| PLEINST || Radiation || Pa || xyz || air pressure
|-
| ALW || Saltwater || W m-2 || tile || linearization of surface upwelling longwave flux
|-
| BLW || Saltwater || W m-2 K-1 || tile || linearization of surface upwelling longwave flux
|-
| CMATM || Saltwater || kg m-2 s-1 || tile || surface exchange coefficient for momentum
|-
| CQATM || Saltwater || kg m-2 s-1 || tile || surface exchange coefficient for moisture
|-
| CTATM || Saltwater || kg m-2 s-1 || tile || surface exchange coefficient for heat
|-
| DEVAP || Saltwater || kg m-2 s-1 || tile || derivative of evaporation
|-
| DFNIR || Saltwater || W m-2 || tile || surface downwelling nir diffuse flux
|-
| DFPAR || Saltwater || W m-2 || tile || surface downwelling par diffuse flux
|-
| DFUVR || Saltwater || W m-2 || tile || surface downwelling uvr diffuse flux
|-
| DRNIR || Saltwater || W m-2 || tile || surface downwelling nir beam flux
|-
| DRPAR || Saltwater || W m-2 || tile || surface downwelling par beam flux
|-
| DRUVR || Saltwater || W m-2 || tile || surface downwelling uvr beam flux
|-
| DSH || Saltwater || W m-2 || tile || derivative of upward sensible heat flux
|-
| DTSDT || Saltwater || K s-1 || tile || skin temperature analysis tendency
|-
| DZ || Saltwater || m || tile || surface layer height
|-
| EVAP || Saltwater || kg m-2 s-1 || tile || evaporation
|-
| FRACICE || Saltwater || 1 || tile || ice covered fraction of tile
|-
| KPAR || Saltwater || m-1 || tile || PAR extinction coefficient
|-
| LWDNSRF || Saltwater || W m-2 || tile || surface downwelling longwave flux
|-
| PCU || Saltwater || kg m-2 s-1 || tile || liquid water convective precipitation
|-
| PLS || Saltwater || kg m-2 s-1 || tile || liquid water large scale precipitation
|-
| PS || Saltwater || Pa || tile || surface pressure
|-
| QA || Saltwater || kg kg-1 || tile || surface air specific humidity
|-
| QHATM || Saltwater || kg kg-1 || tile || effective surface specific humidity
|-
| SH || Saltwater || W m-2 || tile || upward sensible heat flux
|-
| SNO || Saltwater || kg m-2 s-1 || tile || snowfall
|-
| TA || Saltwater || K || tile || surface air temperature
|-
| TAUX || Saltwater || N m-2 || tile || eastward surface stress
|-
| TAUY || Saltwater || N m-2 || tile || northward surface stress
|-
| THATM || Saltwater || K || tile || effective surface skin temperature
|-
| TS_FOUND || Saltwater || K || tile || foundation temperature for interface layer
|-
| UHATM || Saltwater || m s-1 || tile || effective surface zonal velocity
|-
| UI || Saltwater || m s-1 || tile || zonal velocity of surface ice
|-
| UU || Saltwater || m s-1 || tile || surface wind speed
|-
| UW || Saltwater || m s-1 || tile || zonal velocity of surface water
|-
| UWINDLMTILE || Saltwater || m s-1 || tile || levellm uwind
|-
| VHATM || Saltwater || m s-1 || tile || effective surface meridional velocity
|-
| VI || Saltwater || m s-1 || tile || meridional velocity of surface ice
|-
| VW || Saltwater || m s-1 || tile || meridional velocity of surface water
|-
| VWINDLMTILE || Saltwater || m s-1 || tile || levellm vwind
|-
| FCLD || Satsim || 1 || xyz || cloud area fraction
|-
| FRLAND || Satsim || 1 || xy || fraction of land
|-
| FROCEAN || Satsim || 1 || xy || fraction of ocean
|-
| MCOSZ || Satsim || 1 || xy || mean cosine of the solar zenith angle
|-
| PLE || Satsim || Pa || xyz || Edge pressures
|-
| QICN || Satsim || 1 || xyz || mass fraction of convective cloud ice water
|-
| QILS || Satsim || 1 || xyz || mass fraction of large scale cloud ice water
|-
| QLCN || Satsim || 1 || xyz || mass fraction of convective cloud liquid water
|-
| QLLS || Satsim || 1 || xyz || mass fraction of large scale cloud liquid water
|-
| QRTOT || Satsim || kg kg-1 || xyz || mass fraction of falling rain
|-
| QSTOT || Satsim || kg kg-1 || xyz || mass fraction of falling snow
|-
| QV || Satsim || 1 || xyz || specific humidity
|-
| RI || Satsim || m || xyz || ice phase cloud particle effective radius
|-
| RL || Satsim || m || xyz || liquid cloud particle effective radius
|-
| RR || Satsim || m || xyz || rain cloud particle effective radius
|-
| RS || Satsim || m || xyz || snow particle effective radius
|-
| SATORB || Satsim || days || xy || Satellite orbits
|-
| T || Satsim || K || xyz || air temperature
|-
| TS || Satsim || K || xy || skin temperature
|-
| ZLE || Satsim || m || xyz || Edge heights
|-
| AERO || Solar || kg kg-1 || xyz || aerosols
|-
| ALBNF || Solar || 1 || xy || surface albedo for near infrared diffuse
|-
| ALBNR || Solar || 1 || xy || surface albedo for near infrared beam
|-
| ALBVF || Solar || 1 || xy || surface albedo for visible diffuse
|-
| ALBVR || Solar || 1 || xy || surface albedo for visible beam
|-
| FCLD || Solar || 1 || xyz || cloud area fraction
|-
| OX || Solar || mol mol-1 || xyz || odd-oxygen volume mixing ratio
|-
| PLE || Solar || Pa || xyz || air pressure
|-
| PREF || Solar || Pa || z || reference air pressure
|-
| QI || Solar || kg kg-1 || xyz || mass fraction of cloud ice in air
|-
| QL || Solar || kg kg-1 || xyz || mass fraction of cloud liquid water in air
|-
| QR || Solar || kg kg-1 || xyz || mass fraction of rain water in air
|-
| QS || Solar || kg kg-1 || xyz || mass fraction of snow in air
|-
| QV || Solar || kg kg-1 || xyz || specific humidity
|-
| RI || Solar || m || xyz || effective radius of cloud ice particles
|-
| RL || Solar || m || xyz || effective radius of cloud liquid water particles
|-
| RR || Solar || m || xyz || effective radius of rain particles
|-
| RS || Solar || m || xyz || effective radius of snow particles
|-
| SWNDSRF || Solar || W m-2 || xy || surface net downward shortwave flux
|-
| T || Solar || K || xyz || air temperature
|-
| AIRDENS || StratChem || kg m-3 || xyz || air density
|-
| AREA || StratChem || m^2 || xy || agrid cell area
|-
| LFR || StratChem || km-2 s-1 || xy || lightning flash rate
|-
| PLE || StratChem || Pa || xyz || air pressure
|-
| Q || StratChem || kg kg-1 || xyz || specific humidity
|-
| QCTOT || StratChem || kg kg-1 || xyz || mass fraction of total cloud water
|-
| T || StratChem || K || xyz || air temperature
|-
| TROPP || StratChem || Pa || xy || tropopause pressure based on blended estimate
|-
| DTDT || Superdyn || Pa K s-1 || xyz || delta-p weighted temperature tendency
|-
| DUDT || Superdyn || m s-2 || xyz || eastward wind tendency
|-
| DVDT || Superdyn || m s-2 || xyz || northward wind tendency
|-
| AERO_DP || Surface || kg m-2 s-1 || xy || aerosol deposition
|-
| ALW || Surface || W m-2 || xy || linearization of surface upwelling longwave flux
|-
| BLW || Surface || W m-2 K-1 || xy || linearization of surface upwelling longwave flux
|-
| CO2SC || Surface || 1e-6 || xy || CO2 Surface Concentration Bin 001
|-
| DDEWL || Surface || kg m-2 s-1 || xy || derivative of dewfall wrt QS
|-
| DEVAP || Surface || kg m-2 s-1 || xy || derivative of evaporation wrt QS
|-
| DEWL || Surface || kg m-2 s-1 || xy || dewfall
|-
| DFNIRN || Surface || 1 || xy || normalized surface downwelling nir diffuse flux
|-
| DFPARN || Surface || 1 || xy || normalized surface downwelling par diffuse flux
|-
| DFRSL || Surface || kg m-2 s-1 || xy || derivative of frostfall wrt QS
|-
| DFU || Surface || N s m-3 || xy || derivative of eastward surface stress wrt Us
|-
| DFUVRN || Surface || 1 || xy || normalized surface downwelling uvr diffuse flux
|-
| DFV || Surface || N s m-3 || xy || derivative of northward surface stress wrt Us
|-
| DRNIRN || Surface || 1 || xy || normalized surface downwelling nir beam flux
|-
| DRPARN || Surface || 1 || xy || normalized surface downwelling par beam flux
|-
| DRUVRN || Surface || 1 || xy || normalized surface downwelling uvr beam flux
|-
| DSH || Surface || W m-2 K-1 || xy || derivative of sensible heat wrt dry static energy
|-
| DTSDT || Surface || K s-1 || xy || skin temperature analysis tendency
|-
| DZ || Surface || m || xy || surface layer height
|-
| EVAP || Surface || kg m-2 s-1 || xy || evaporation
|-
| FRSL || Surface || kg m-2 s-1 || xy || frostfall
|-
| FSWBAND || Surface || W m-2 || xy || net surface downward shortwave flux per band in air
|-
| FSWBANDNA || Surface || W m-2 || xy || net surface downward shortwave flux per band in air assuming no aerosol
|-
| LWDNSRF || Surface || W m-2 || xy || surface downwelling longwave flux
|-
| PCU || Surface || kg m-2 s-1 || xy || liquid water convective precipitation
|-
| PHIS || Surface || m+2 s-2 || xy || surface geopotential height
|-
| PLS || Surface || kg m-2 s-1 || xy || liquid water large scale precipitation
|-
| PS || Surface || Pa || xy || surface pressure
|-
| QA || Surface || kg kg-1 || xy || surface air specific humidity
|-
| SH || Surface || W m-2 || xy || sensible heat flux
|-
| SNO || Surface || kg m-2 s-1 || xy || snowfall
|-
| SPEED || Surface || m s-1 || xy || surface wind speed
|-
| TA || Surface || K || xy || surface air temperature
|-
| TAUX || Surface || N m-2 || xy || eastward surface stress on air
|-
| TAUY || Surface || N m-2 || xy || northward surface stress on air
|-
| UA || Surface || m s-1 || xy || eastward wind bottom level
|-
| VA || Surface || m s-1 || xy || northward wind bottom level
|-
| BSTAR || Turbulence || m s-2 || xy || surface bouyancy scale
|-
| CLCN || Turbulence || 1 || xyz || cloud fraction
|-
| CLLS || Turbulence || 1 || xyz || cloud fraction
|-
| CM || Turbulence || kg m-2 s-1 || xy || surface momentum exchange coefficient
|-
| CQ || Turbulence || kg m-2 s-1 || xy || surface moisture exchange coefficient
|-
| CT || Turbulence || kg m-2 s-1 || xy || surface heat exchange coefficient
|-
| DTG || Turbulence || X || xy || change of surface values of diffused quantity
|-
| FRLAND || Turbulence || 1 || xy || land fraction
|-
| PLE || Turbulence || Pa || xyz || air pressure
|-
| PREF || Turbulence || Pa || z || reference air pressure
|-
| QICN || Turbulence || kg kg-1 || xyz || frozen condensate mixing ratio
|-
| QILS || Turbulence || kg kg-1 || xyz || frozen condensate mixing ratio
|-
| QLCN || Turbulence || kg kg-1 || xyz || liquid condensate mixing ratio
|-
| QLLS || Turbulence || kg kg-1 || xyz || liquid condensate mixing ratio
|-
| QV || Turbulence || kg kg-1 || xyz || specific humidity
|-
| RADLW || Turbulence || K s-1 || xyz || air temperature tendency due to longwave
|-
| RADLWC || Turbulence || K s-1 || xyz || clearsky air temperature tendency lw
|-
| T || Turbulence || K || xyz || air temperature
|-
| TH || Turbulence || K || xyz || potential temperature
|-
| TR || Turbulence || X || xyz || diffused quantities
|-
| TRG || Turbulence || X || xy || surface values of diffused quantity
|-
| U || Turbulence || m s-1 || xyz || eastward wind
|-
| USTAR || Turbulence || m s-1 || xy || surface velocity scale
|-
| V || Turbulence || m s-1 || xyz || northward wind
|-
| VARFLT || Turbulence || m+2 || xy || variance of filtered topography
|-
| AK || mkiau || Pa || z || hybrid sigma pressure a
|-
| BK || mkiau || Pa || z || hybrid sigma pressure b
|-
| O3PPMV || mkiau || ppmv || xyz || ozone volume mixing ratio
|-
| PHIS || mkiau || m2 sec-2 || xy || surface geopotential height
|-
| PLE || mkiau || Pa || xyz || air pressure
|-
| QV || mkiau || kgkg || xyz || water vapor specific humdity
|-
| T || mkiau || K || xyz || air temperature
|-
| TRANA || mkiau || X || xy || analyzed quantities
|-
| TS || mkiau || K || xy || skin temperature
|-
| U || mkiau || m s-1 || xyz || eastward wind
|-
| V || mkiau || m s-1 || xyz || northward wind
|}
 
 
__FORCETOC__
===Export States===
 
Sorted 2284 states by Component name - within each component, variables are sorted by their short name
{| class="wikitable"
|+ List of GEOS-5 [EX] State variables
! Name !! Component !! Units !! Dim !! Long name
|-
| AREA || ARIESg3 || m+2 || xy || agrid cell area
|-
| CNV || ARIESg3 || W m-2 || xy || generation of atmosphere kinetic energy content
|-
| CONVCPT || ARIESg3 || W m-2 || xy || vertically integrated enthalpy convergence
|-
| CONVKE || ARIESg3 || W m-2 || xy || vertically integrated kinetic energy convergence
|-
| CONVPHI || ARIESg3 || W m-2 || xy || vertically integrated geopotential convergence
|-
| CONVTHV || ARIESg3 || W m-2 || xy || vertically integrated thetav convergence
|-
| DCPT || ARIESg3 || W m-2 || xy || tendency of atmosphere dry energy content due to dynamics
|-
| DDELPDTANA || ARIESg3 || K sec-1 || xyz || tendency of pressure thickness due to analysis
|-
| DDELPDTDYN || ARIESg3 || Pa sec-1 || xyz || tendency of pressure thickness due to dynamics
|-
| DELP || ARIESg3 || Pa || xyz || pressure thickness
|-
| DKE || ARIESg3 || W m-2 || xy || tendency of atmosphere kinetic energy content due to dynamics
|-
| DKERESIN || ARIESg3 || W m-2 || xy || vertically integrated kinetic energy residual from inertial terms
|-
| DKERESPG || ARIESg3 || W m-2 || xy || vertically integrated kinetic energy residual from PG terms
|-
| DMDTANA || ARIESg3 || kg m-2 s-1 || xy || vertically integrated mass tendency due to analysis
|-
| DMDTDYN || ARIESg3 || kg m-2 s-1 || xy || vertically integrated mass tendency due to dynamics
|-
| DOXDTANAINT || ARIESg3 || kg m-2 s-1 || xy || vertically integrated ozone tendency due to analysis
|-
| DOXDTDYN || ARIESg3 || kgkgsec || xyz || tendency of ozone due to dynamics
|-
| DOXDTDYNINT || ARIESg3 || kg m-2 s-1 || xy || vertically integrated ozone tendency due to dynamics
|-
| DPET || ARIESg3 || W m-2 || xy || tendency of atmosphere topographic potential energy due to dynamics
|-
| DQI || ARIESg3 || kg m-2 s-1 || xy || tendency of atmosphere ice content due to dynamics
|-
| DQIDTANAINT || ARIESg3 || kg m-2 s-1 || xy || vertically integrated ice water tendency due to analysis
|-
| DQIDTDYN || ARIESg3 || kgkgsec || xyz || tendency of ice water due to dynamics
|-
| DQIDTDYNINT || ARIESg3 || kg m-2 s-1 || xy || vertically integrated ice water tendency due to dynamics
|-
| DQL || ARIESg3 || kg m-2 s-1 || xy || tendency of atmosphere liquid water content due to dynamics
|-
| DQLDTANAINT || ARIESg3 || kg m-2 s-1 || xy || vertically integrated liquid water tendency due to analysis
|-
| DQLDTDYN || ARIESg3 || kgkgsec || xyz || tendency of liquid water due to dynamics
|-
| DQLDTDYNINT || ARIESg3 || kg m-2 s-1 || xy || vertically integrated liquid water tendency due to dynamics
|-
| DQV || ARIESg3 || kg m-2 s-1 || xy || tendency of atmosphere water vapor content due to dynamics
|-
| DQVDTANAINT || ARIESg3 || kg m-2 s-1 || xy || vertically integrated water vapor tendency due to analysis
|-
| DQVDTDYN || ARIESg3 || kgkgsec || xyz || tendency of specific humidity due to dynamics
|-
| DQVDTDYNINT || ARIESg3 || kg m-2 s-1 || xy || vertically integrated water vapor tendency due to dynamics
|-
| DTDTANA || ARIESg3 || K sec-1 || xyz || tendency of air temperature due to analysis
|-
| DTDTDYN || ARIESg3 || K sec-1 || xyz || tendency of air temperature due to dynamics
|-
| DTHVDTANAINT || ARIESg3 || K kg m-2 s-1 || xy || vertically integrated THV tendency due to analysis
|-
| DTHVDTCONSV || ARIESg3 || K kg m-2 s-1 || xy || vertically integrated THV tendency due to TE conservation
|-
| DTHVDTDYNINT || ARIESg3 || K kg m-2 s-1 || xy || vertically integrated THV tendency due to dynamics
|-
| DTHVDTPHYINT || ARIESg3 || K kg m-2 s-1 || xy || vertically integrated THV tendency due to physics
|-
| DTHVDTREMAP || ARIESg3 || K kg m-2 s-1 || xy || vertically integrated THV tendency due to vertical remapping
|-
| DUDTANA || ARIESg3 || msecsec || xyz || tendency of eastward wind due to analysis
|-
| DUDTDYN || ARIESg3 || msecsec || xyz || tendency of eastward wind due to dynamics
|-
| DVDTANA || ARIESg3 || msecsec || xyz || tendency of northward wind due to analysis
|-
| DVDTDYN || ARIESg3 || msecsec || xyz || tendency of northward wind due to dynamics
|-
| DZ || ARIESg3 || m || xy || surface layer height
|-
| EPV || ARIESg3 || K m+2 kg-1 sec-1 || xyz || ertels potential vorticity
|-
| H1000 || ARIESg3 || m || xy || height at 1000 mb
|-
| H250 || ARIESg3 || m || xy || height at 250 hPa
|-
| H500 || ARIESg3 || m || xy || height at 500 hPa
|-
| H850 || ARIESg3 || m || xy || height at 850 hPa
|-
| KE || ARIESg3 || J m-2 || xy || vertically integrated kinetic energy
|-
| KEADV || ARIESg3 || W m-2 || xy || vertically integrated kinetic energy tendency due to dynamics advection
|-
| KEANA || ARIESg3 || W m-2 || xy || total kinetic energy tendency due to analysis
|-
| KECDCOR || ARIESg3 || W m-2 || xy || vertically integrated kinetic energy tendency due to cdcore
|-
| KEDP || ARIESg3 || W m-2 || xy || vertically integrated kinetic energy tendency due to pressure change
|-
| KEDYN || ARIESg3 || W m-2 || xy || vertically integrated kinetic energy tendency due to dynamics
|-
| KEGEN || ARIESg3 || W m-2 || xy || vertically integrated generation of kinetic energy
|-
| KEHOT || ARIESg3 || W m-2 || xy || vertically integrated kinetic energy tendency due to HOT
|-
| KEPG || ARIESg3 || W m-2 || xy || vertically integrated kinetic energy tendency due to pressure gradient
|-
| KEPHY || ARIESg3 || W m-2 || xy || vertically integrated kinetic energy tendency due to physics
|-
| KEREMAP || ARIESg3 || W m-2 || xy || vertically integrated kinetic energy tendency due to remap
|-
| MFX || ARIESg3 || Pa m+2 s-1 || xyz || pressure weighted eastward wind
|-
| MFX_A || ARIESg3 || Pa m+2 s-1 || xyz || zonal mass flux
|-
| MFX_UR || ARIESg3 || Pa m+2 s-1 || xyz || pressure weighted eastward wind unremapped
|-
| MFY || ARIESg3 || Pa m+2 s-1 || xyz || pressure weighted northward wind
|-
| MFY_A || ARIESg3 || Pa m+2 s-1 || xyz || meridional mass flux
|-
| MFY_UR || ARIESg3 || Pa m+2 s-1 || xyz || pressure weighted northward wind unremapped
|-
| MFZ || ARIESg3 || kg m-2 s-1 || xyz || vertical mass flux
|-
| OMEGA || ARIESg3 || Pa sec-1 || xyz || vertical pressure velocity
|-
| OMEGA500 || ARIESg3 || Pa s-1 || xy || omega at 500 hPa
|-
| PEANA || ARIESg3 || W m-2 || xy || total potential energy tendency due to analysis
|-
| PECDCOR || ARIESg3 || W m-2 || xy || vertically integrated potential energy tendency due to cdcore
|-
| PEDYN || ARIESg3 || W m-2 || xy || vertically integrated potential energy tendency due to dynamics
|-
| PEPHY || ARIESg3 || W m-2 || xy || total potential energy tendency due to physics
|-
| PEREMAP || ARIESg3 || W m-2 || xy || vertically integrated potential energy tendency due to remap
|-
| PL || ARIESg3 || Pa || xyz || mid level pressure
|-
| PLE || ARIESg3 || Pa || xyz || edge pressure
|-
| PLK || ARIESg3 || Pa$^\kappa$ || xyz || mid-layer p$^\kappa$
|-
| PREF || ARIESg3 || Pa || z || reference air pressure
|-
| PS || ARIESg3 || Pa || xy || surface pressure
|-
| PTFX || ARIESg3 || K Pa m+2 s-1 || xyz || pressure weighted eastward potential temperature flux unremapped
|-
| PTFY || ARIESg3 || K Pa m+2 s-1 || xyz || pressure weighted northward potential temperature flux unremapped
|-
| PV || ARIESg3 || m+2 kg-1 sec-1 || xyz || ertels isentropic potential vorticity
|-
| Q || ARIESg3 || 1 || xyz || specific humidity
|-
| Q250 || ARIESg3 || kg kg-1 || xy || specific humidity at 250 hPa
|-
| Q500 || ARIESg3 || kg kg-1 || xy || specific humidity at 500 hPa
|-
| Q850 || ARIESg3 || kg kg-1 || xy || specific humidity at 850 hPa
|-
| QA || ARIESg3 || kg kg-1 || xy || surface specific humidity
|-
| QFIXER || ARIESg3 || W m-2 || xy || vertically integrated potential energy tendency due to CONSV
|-
| S || ARIESg3 || m || xyz || mid layer dry static energy
|-
| SLP || ARIESg3 || Pa || xy || sea level pressure
|-
| SPEED || ARIESg3 || m s-1 || xy || surface wind speed
|-
| T || ARIESg3 || K || xyz || air temperature
|-
| T250 || ARIESg3 || K || xy || air temperature at 250 hPa
|-
| T500 || ARIESg3 || K || xy || air temperature at 500 hPa
|-
| T850 || ARIESg3 || K || xy || air temperature at 850 hPa
|-
| TA || ARIESg3 || K || xy || surface air temperature
|-
| TAVE || ARIESg3 || K || xy || vertically averaged dry temperature
|-
| TEANA || ARIESg3 || W m-2 || xy || mountain work tendency due to analysis
|-
| TECDCOR || ARIESg3 || W m-2 || xy || mountain work tendency due to cdcore
|-
| TEDYN || ARIESg3 || W m-2 || xy || mountain work tendency due to dynamics
|-
| TEPHY || ARIESg3 || W m-2 || xy || mountain work tendency due to physics
|-
| TEREMAP || ARIESg3 || W m-2 || xy || mountain work tendency due to remap
|-
| TH || ARIESg3 || K || xyz || potential temperature
|-
| THV || ARIESg3 || KPa$^\kappa$ || xyz || scaled virtual potential temperature
|-
| TROPP_BLENDED || ARIESg3 || Pa || xy || tropopause pressure based on blended estimate
|-
| TROPP_EPV || ARIESg3 || Pa || xy || tropopause pressure based on EPV estimate
|-
| TROPP_THERMAL || ARIESg3 || Pa || xy || tropopause pressure based on thermal estimate
|-
| TROPQ || ARIESg3 || kgkg || xy || tropopause specific humidity using blended TROPP estimate
|-
| TROPT || ARIESg3 || K || xy || tropopause temperature using blended TROPP estimate
|-
| TV || ARIESg3 || K || xyz || air virtual temperature
|-
| U || ARIESg3 || m s-1 || xyz || eastward wind
|-
| U250 || ARIESg3 || m s-1 || xy || eastward wind at 250 hPa
|-
| U500 || ARIESg3 || m s-1 || xy || eastward wind at 500 hPa
|-
| U50M || ARIESg3 || m s-1 || xy || eastward wind at 50 meters
|-
| U850 || ARIESg3 || m s-1 || xy || eastward wind at 850 hPa
|-
| UAVE || ARIESg3 || m sec-1 || xy || vertically averaged zonal wind
|-
| UCPT || ARIESg3 || J m-1 s-1 || xy || eastward flux of atmospheric enthalpy
|-
| UKE || ARIESg3 || J m-1 s-1 || xy || eastward flux of atmospheric kinetic energy
|-
| UPHI || ARIESg3 || J m-1 s-1 || xy || eastward flux of atmospheric potential energy
|-
| UQI || ARIESg3 || kg m-1 s-1 || xy || eastward flux of atmospheric ice
|-
| UQL || ARIESg3 || kg m-1 s-1 || xy || eastward flux of atmospheric liquid water
|-
| UQV || ARIESg3 || kg m-1 s-1 || xy || eastward flux of atmospheric water vapor
|-
| US || ARIESg3 || m s-1 || xy || surface eastward wind
|-
| U_CGRID || ARIESg3 || m s-1 || xyz || eastward wind on C-Grid
|-
| U_DGRID || ARIESg3 || m s-1 || xyz || eastward wind on native D-Grid
|-
| V || ARIESg3 || m s-1 || xyz || northward wind
|-
| V250 || ARIESg3 || m s-1 || xy || northward wind at 250 hPa
|-
| V500 || ARIESg3 || m s-1 || xy || northward wind at 500 hPa
|-
| V50M || ARIESg3 || m s-1 || xy || northward wind at 50 meters
|-
| V850 || ARIESg3 || m s-1 || xy || northward wind at 850 hPa
|-
| VCPT || ARIESg3 || J m-1 s-1 || xy || northward flux of atmospheric enthalpy
|-
| VKE || ARIESg3 || J m-1 s-1 || xy || northward flux of atmospheric kinetic energy
|-
| VPHI || ARIESg3 || J m-1 s-1 || xy || northward flux of atmospheric potential energy
|-
| VQI || ARIESg3 || kg m-1 s-1 || xy || northward flux of atmospheric ice
|-
| VQL || ARIESg3 || kg m-1 s-1 || xy || northward flux of atmospheric liquid water
|-
| VQV || ARIESg3 || kg m-1 s-1 || xy || northward flux of atmospheric water vapor
|-
| VS || ARIESg3 || m s-1 || xy || surface northward wind
|-
| V_CGRID || ARIESg3 || m s-1 || xyz || northward wind on C-Grid
|-
| V_DGRID || ARIESg3 || m s-1 || xyz || northward wind on native D-Grid
|-
| WRKT || ARIESg3 || W m-2 || xy || work done by atmosphere at top
|-
| ZL || ARIESg3 || m || xyz || mid layer heights
|-
| ZLE || ARIESg3 || m || xyz || edge heights
|-
| AK || Agcm || m+2 || xy || isotropic variance of filtered topography
|-
| BK || Agcm || m+2 || xy || isotropic variance of filtered topography
|-
| CPT || Agcm || J m-2 || xy || vertically integrated enthalpy
|-
| DO3DT_ANA || Agcm || 1e-6 s-1 || xyz || total ozone analysis tendency in ppmv sec-1
|-
| DPEDT_ANA || Agcm || Pa s-1 || xyz || total edge pressure analysis tendency
|-
| DQVDT_ANA || Agcm || kg kg-1 s-1 || xyz || total specific humidity analysis tendency
|-
| DTDT_ANA || Agcm || K s-1 || xyz || total temperature analysis tendency
|-
| DTHVDTFILINT || Agcm || K kg m-2 s-1 || xy || vertically integrated thv adjustment from filling
|-
| DTSDT_ANA || Agcm || K s-1 || xy || total skin temperature tendency
|-
| DUDT_ANA || Agcm || m s-2 || xyz || total eastward wind analysis tendency
|-
| DVDT_ANA || Agcm || m s-2 || xyz || total northward wind analysis tendency
|-
| FRACI || Agcm || m+2 || xy || isotropic variance of filtered topography
|-
| FRLAKE || Agcm || m+2 || xy || isotropic variance of filtered topography
|-
| FRLAND || Agcm || m+2 || xy || isotropic variance of filtered topography
|-
| FRLANDICE || Agcm || m+2 || xy || isotropic variance of filtered topography
|-
| FROCEAN || Agcm || m+2 || xy || isotropic variance of filtered topography
|-
| GWDVARX || Agcm || m+2 || xy || east-west variance of GWD topography
|-
| GWDVARXY || Agcm || m+2 || xy || SW-NE variance of GWD topography
|-
| GWDVARY || Agcm || m+2 || xy || north-south variance of GWD topography
|-
| GWDVARYX || Agcm || m+2 || xy || NW-SE variance of GWD topography
|-
| KE || Agcm || J m-2 || xy || vertically integrated kinetic energy
|-
| LWI || Agcm || m+2 || xy || isotropic variance of filtered topography
|-
| MASS || Agcm || kg m-2 || xy || atmospheric mass
|-
| O3PPMV || Agcm || m+2 || xy || isotropic variance of filtered topography
|-
| OX || Agcm || m+2 || xy || isotropic variance of filtered topography
|-
| OXFILL || Agcm || kg m-2 s-1 || xy || vertically integrated ox adjustment from filling
|-
| PE || Agcm || m+2 || xy || isotropic variance of filtered topography
|-
| PEFILL || Agcm || W m-2 || xy || vertically integrated cpt adjustment from filling
|-
| PERES || Agcm || W m-2 || xy || vertically integrated cpt tendency residual
|-
| PHIS || Agcm || m+2 s-2 || xy || surface geopotential height
|-
| PLE || Agcm || m+2 || xy || isotropic variance of filtered topography
|-
| PS || Agcm || m+2 || xy || isotropic variance of filtered topography
|-
| PT || Agcm || m+2 || xy || isotropic variance of filtered topography
|-
| Q || Agcm || m+2 || xy || isotropic variance of filtered topography
|-
| QCTOT || Agcm || m+2 || xy || isotropic variance of filtered topography
|-
| QIFILL || Agcm || kg m-2 s-1 || xy || vertically integrated qi adjustment from filling
|-
| QITOT || Agcm || kg kg-1 || xyz || mass fraction of cloud ice water
|-
| QLFILL || Agcm || kg m-2 s-1 || xy || vertically integrated ql adjustment from filling
|-
| QLTOT || Agcm || kg kg-1 || xyz || mass fraction of cloud liquid water
|-
| QTFILL || Agcm || kg m-2 s-1 || xy || vertically integrated total water adjustment from filling
|-
| QVFILL || Agcm || kg m-2 s-1 || xy || vertically integrated qv adjustment from filling
|-
| SGH || Agcm || m || xy || isotropic stdv of GWD topography
|-
| SNOMAS || Agcm || m+2 || xy || isotropic variance of filtered topography
|-
| T || Agcm || m+2 || xy || isotropic variance of filtered topography
|-
| THV || Agcm || K || xy || vertically integrated virtual potential temperature
|-
| TOX || Agcm || kg m-2 || xy || total column odd oxygen
|-
| TQI || Agcm || kg m-2 || xy || total precipitable ice water
|-
| TQL || Agcm || kg m-2 || xy || total precipitable liquid water
|-
| TQV || Agcm || kg m-2 || xy || total precipitable water vapor
|-
| TRANA || Agcm || m+2 || xy || isotropic variance of filtered topography
|-
| TRBVAR || Agcm || m+2 || xy || isotropic variance of TRB topography
|-
| TROPP_BLENDED || Agcm || Pa || xy || tropopause pressure based on blended estimate
|-
| TROPP_EPV || Agcm || Pa || xy || tropopause pressure based on EPV estimate
|-
| TROPP_THERMAL || Agcm || Pa || xy || tropopause pressure based on thermal estimate
|-
| TROPQ || Agcm || kg kg-1 || xy || tropopause specific humidity using blended TROPP estimate
|-
| TROPT || Agcm || K || xy || tropopause temperature using blended TROPP estimate
|-
| TS || Agcm || m+2 || xy || isotropic variance of filtered topography
|-
| TSOIL1 || Agcm || m+2 || xy || isotropic variance of filtered topography
|-
| TV || Agcm || m+2 || xy || isotropic variance of filtered topography
|-
| U || Agcm || m+2 || xy || isotropic variance of filtered topography
|-
| U10N || Agcm || m+2 || xy || isotropic variance of filtered topography
|-
| U_DGRID || Agcm || m+2 || xy || isotropic variance of filtered topography
|-
| V || Agcm || m+2 || xy || isotropic variance of filtered topography
|-
| V10N || Agcm || m+2 || xy || isotropic variance of filtered topography
|-
| VARFLT || Agcm || m+2 || xy || isotropic variance of filtered topography
|-
| V_DGRID || Agcm || m+2 || xy || isotropic variance of filtered topography
|-
| WET1 || Agcm || m+2 || xy || isotropic variance of filtered topography
|-
| Z0 || Agcm || m+2 || xy || isotropic variance of filtered topography
|-
| CARMA_ASHANGSTR || CARMA || 1 || xy || Ash 470-870 nm Angstrom parameter
|-
| CARMA_ASHCMASS || CARMA || kg m-2 || xy || Ash column burden
|-
| CARMA_ASHCONC || CARMA || kg m-3 || xyz || Ash Mass Concentration
|-
| CARMA_ASHDP || CARMA || kg m-2 s-1 || xy || Ash deposition flux
|-
| CARMA_ASHEM || CARMA || kg m-2 s-1 || xy || Ash emission flux
|-
| CARMA_ASHEXTTAU || CARMA || 1 || xy || Ash 550-nm extinction AOT
|-
| CARMA_ASHFLUXU || CARMA || kg m-1 s-1 || xy || Ash column u-wind mass flux
|-
| CARMA_ASHFLUXV || CARMA || kg m-1 s-1 || xy || Ash column v-wind mass flux
|-
| CARMA_ASHMASS || CARMA || kg kg-1 || xyz || Ash Mass Mixing Ratio
|-
| CARMA_ASHSCATAU || CARMA || 1 || xy || Ash 550-nm scattering AOT
|-
| CARMA_ASHSD || CARMA || kg m-2 s-1 || xy || Ash sedimentation flux
|-
| CARMA_ASHSMASS || CARMA || kg m-3 || xy || Ash surface mass concentration
|-
| CARMA_ASHSV || CARMA || kg m-2 s-1 || xy || Ash convective scavenging flux
|-
| CARMA_ASHWT || CARMA || kg m-2 s-1 || xy || Ash wet-deposition flux
|-
| CARMA_BCANGSTR || CARMA || 1 || xy || Black Carbon 470-870 nm Angstrom parameter
|-
| CARMA_BCCMASS || CARMA || kg m-2 || xy || Black Carbon column burden
|-
| CARMA_BCCONC || CARMA || kg m-3 || xyz || Black Carbon Mass Concentration
|-
| CARMA_BCDP || CARMA || kg m-2 s-1 || xy || Black Carbon deposition flux
|-
| CARMA_BCEM || CARMA || kg m-2 s-1 || xy || Black Carbon emission flux
|-
| CARMA_BCEXTTAU || CARMA || 1 || xy || Black Carbon 550-nm extinction AOT
|-
| CARMA_BCFLUXU || CARMA || kg m-1 s-1 || xy || Black Carbon column u-wind mass flux
|-
| CARMA_BCFLUXV || CARMA || kg m-1 s-1 || xy || Black Carbon column v-wind mass flux
|-
| CARMA_BCMASS || CARMA || kg kg-1 || xyz || Black Carbon Mass Mixing Ratio
|-
| CARMA_BCSCATAU || CARMA || 1 || xy || Black Carbon 550-nm scattering AOT
|-
| CARMA_BCSD || CARMA || kg m-2 s-1 || xy || Black Carbon sedimentation flux
|-
| CARMA_BCSMASS || CARMA || kg m-3 || xy || Black Carbon surface mass concentration
|-
| CARMA_BCSV || CARMA || kg m-2 s-1 || xy || Black Carbon convective scavenging flux
|-
| CARMA_BCWT || CARMA || kg m-2 s-1 || xy || Black Carbon wet-deposition flux
|-
| CARMA_DUANGSTR || CARMA || 1 || xy || Dust 470-870 nm Angstrom parameter
|-
| CARMA_DUCM001 || CARMA || kg m-2 || xy || Dust column burden Bin 001
|-
| CARMA_DUCM002 || CARMA || kg m-2 || xy || Dust column burden Bin 002
|-
| CARMA_DUCM003 || CARMA || kg m-2 || xy || Dust column burden Bin 003
|-
| CARMA_DUCM004 || CARMA || kg m-2 || xy || Dust column burden Bin 004
|-
| CARMA_DUCM005 || CARMA || kg m-2 || xy || Dust column burden Bin 005
|-
| CARMA_DUCM006 || CARMA || kg m-2 || xy || Dust column burden Bin 006
|-
| CARMA_DUCM007 || CARMA || kg m-2 || xy || Dust column burden Bin 007
|-
| CARMA_DUCM008 || CARMA || kg m-2 || xy || Dust column burden Bin 008
|-
| CARMA_DUCMASS || CARMA || kg m-2 || xy || Dust column burden
|-
| CARMA_DUCONC || CARMA || kg m-3 || xyz || Dust Mass Concentration
|-
| CARMA_DUDP || CARMA || kg m-2 s-1 || xy || Dust deposition flux
|-
| CARMA_DUEM || CARMA || kg m-2 s-1 || xy || Dust emission flux
|-
| CARMA_DUEXTTAU || CARMA || 1 || xy || Dust 550-nm extinction AOT
|-
| CARMA_DUFLUXU || CARMA || kg m-1 s-1 || xy || Dust column u-wind mass flux
|-
| CARMA_DUFLUXV || CARMA || kg m-1 s-1 || xy || Dust column v-wind mass flux
|-
| CARMA_DUMASS || CARMA || kg kg-1 || xyz || Dust Mass Mixing Ratio
|-
| CARMA_DUSCATAU || CARMA || 1 || xy || Dust 550-nm scattering AOT
|-
| CARMA_DUSD || CARMA || kg m-2 s-1 || xy || Dust sedimentation flux
|-
| CARMA_DUSMASS || CARMA || kg m-3 || xy || Dust surface mass concentration
|-
| CARMA_DUSV || CARMA || kg m-2 s-1 || xy || Dust convective scavenging flux
|-
| CARMA_DUWT || CARMA || kg m-2 s-1 || xy || Dust wet-deposition flux
|-
| CARMA_SMANGSTR || CARMA || 1 || xy || Smoke 470-870 nm Angstrom parameter
|-
| CARMA_SMCMASS || CARMA || kg m-2 || xy || Smoke column burden
|-
| CARMA_SMCONC || CARMA || kg m-3 || xyz || Smoke Mass Concentration
|-
| CARMA_SMDP || CARMA || kg m-2 s-1 || xy || Smoke deposition flux
|-
| CARMA_SMEM || CARMA || kg m-2 s-1 || xy || Smoke emission flux
|-
| CARMA_SMEXTTAU || CARMA || 1 || xy || Smoke 550-nm extinction AOT
|-
| CARMA_SMFLUXU || CARMA || kg m-1 s-1 || xy || Smoke column u-wind mass flux
|-
| CARMA_SMFLUXV || CARMA || kg m-1 s-1 || xy || Smoke column v-wind mass flux
|-
| CARMA_SMMASS || CARMA || kg kg-1 || xyz || Smoke Mass Mixing Ratio
|-
| CARMA_SMSCATAU || CARMA || 1 || xy || Smoke 550-nm scattering AOT
|-
| CARMA_SMSD || CARMA || kg m-2 s-1 || xy || Smoke sedimentation flux
|-
| CARMA_SMSMASS || CARMA || kg m-3 || xy || Smoke surface mass concentration
|-
| CARMA_SMSV || CARMA || kg m-2 s-1 || xy || Smoke convective scavenging flux
|-
| CARMA_SMWT || CARMA || kg m-2 s-1 || xy || Smoke wet-deposition flux
|-
| CARMA_SSANGSTR || CARMA || 1 || xy || Seasalt 470-870 nm Angstrom parameter
|-
| CARMA_SSCMASS || CARMA || kg m-2 || xy || Seasalt column burden
|-
| CARMA_SSCONC || CARMA || kg m-3 || xyz || Seasalt Mass Concentration
|-
| CARMA_SSDP || CARMA || kg m-2 s-1 || xy || Seasalt deposition flux
|-
| CARMA_SSEM || CARMA || kg m-2 s-1 || xy || Seasalt emission flux
|-
| CARMA_SSEXTTAU || CARMA || 1 || xy || Seasalt 550-nm extinction AOT
|-
| CARMA_SSFLUXU || CARMA || kg m-1 s-1 || xy || Seasalt column u-wind mass flux
|-
| CARMA_SSFLUXV || CARMA || kg m-1 s-1 || xy || Seasalt column v-wind mass flux
|-
| CARMA_SSMASS || CARMA || kg kg-1 || xyz || Seasalt Mass Mixing Ratio
|-
| CARMA_SSSCATAU || CARMA || 1 || xy || Seasalt 550-nm scattering AOT
|-
| CARMA_SSSD || CARMA || kg m-2 s-1 || xy || Seasalt sedimentation flux
|-
| CARMA_SSSMASS || CARMA || kg m-3 || xy || Seasalt surface mass concentration
|-
| CARMA_SSSV || CARMA || kg m-2 s-1 || xy || Seasalt convective scavenging flux
|-
| CARMA_SSWT || CARMA || kg m-2 s-1 || xy || Seasalt wet-deposition flux
|-
| CARMA_SUANGSTR || CARMA || 1 || xy || Sulfate 470-870 nm Angstrom parameter
|-
| CARMA_SUCMASS || CARMA || kg m-2 || xy || Sulfate column burden
|-
| CARMA_SUCONC || CARMA || kg m-3 || xyz || Sulfate Mass Concentration
|-
| CARMA_SUDP || CARMA || kg m-2 s-1 || xy || Sulfate deposition flux
|-
| CARMA_SUEXTTAU || CARMA || 1 || xy || Sulfate 550-nm extinction AOT
|-
| CARMA_SUFLUXU || CARMA || kg m-1 s-1 || xy || Sulfate column u-wind mass flux
|-
| CARMA_SUFLUXV || CARMA || kg m-1 s-1 || xy || Sulfate column v-wind mass flux
|-
| CARMA_SUMASS || CARMA || kg kg-1 || xyz || Sulfate Mass Mixing Ratio
|-
| CARMA_SUSCATAU || CARMA || 1 || xy || Sulfate 550-nm scattering AOT
|-
| CARMA_SUSD || CARMA || kg m-2 s-1 || xy || Sulfate sedimentation flux
|-
| CARMA_SUSMASS || CARMA || kg m-3 || xy || Sulfate surface mass concentration
|-
| CARMA_SUSV || CARMA || kg m-2 s-1 || xy || Sulfate convective scavenging flux
|-
| CARMA_SUWT || CARMA || kg m-2 s-1 || xy || Sulfate wet-deposition flux
|-
| CARMA_TOTANGSTR || CARMA || 1 || xy || Total 470-870 nm Angstrom parameter
|-
| CARMA_TOTEXTTAU || CARMA || 1 || xy || Total 550-nm extinction AOT
|-
| CARMA_TOTSCATAU || CARMA || 1 || xy || Total 550-nm scattering AOT
|-
| AERO || CARMAchem || kg kg-1 || xyz || aerosol mass mixing ratios
|-
| AERO_DP || CARMAchem || kg m-2 s-1 || xy || aerosol deposition
|-
| ACCUM || Catch || kg m-2 s-1 || tile || net ice accumulation rate
|-
| ALBNF || Catch || 1 || tile || surface albedo near infrared diffuse
|-
| ALBNR || Catch || 1 || tile || surface albedo near infrared beam
|-
| ALBVF || Catch || 1 || tile || surface albedo visible diffuse
|-
| ALBVR || Catch || 1 || tile || surface albedo visible beam
|-
| AR1 || Catch || 1 || tile || areal fraction saturated zone
|-
| AR2 || Catch || 1 || tile || areal fraction transpiration zone
|-
| ASNOW || Catch || 1 || tile || fractional area of land snowcover
|-
| AVETSNOW || Catch || K || tile || averaged snow temperature
|-
| BASEFLOW || Catch || kg m-2 s-1 || tile || baseflow flux
|-
| CHT || Catch || kg m-2 s-1 || tile || surface heat exchange coefficient
|-
| CMT || Catch || kg m-2 s-1 || tile || surface momentum exchange coefficient
|-
| CNT || Catch || 1 || tile || neutral drag coefficient
|-
| CQT || Catch || kg m-2 s-1 || tile || surface moisture exchange coefficient
|-
| D0 || Catch || m || tile || zero plane displacement height
|-
| DELEVAP || Catch || kg m-2 s-1 || tile || change evaporation
|-
| DELQS || Catch || kg kg-1 || tile || change surface specific humidity
|-
| DELSH || Catch || W m-2 || tile || change upward sensible energy flux
|-
| DELTS || Catch || K || tile || change surface skin temperature
|-
| DHLAND || Catch || W m-2 || tile || rate of change of total land energy
|-
| DWLAND || Catch || kg m-2 s-1 || tile || rate of change of total land water
|-
| EMIS || Catch || 1 || tile || surface emissivity
|-
| EVAPOUT || Catch || kg m-2 s-1 || tile || evaporation
|-
| EVLAND || Catch || kg m-2 s-1 || tile || Evaporation land
|-
| EVPICE || Catch || W m-2 || tile || snow ice evaporation energy flux
|-
| EVPINT || Catch || W m-2 || tile || interception loss energy flux
|-
| EVPSNO || Catch || W m-2 || tile || snowpack evaporation energy flux
|-
| EVPSOI || Catch || W m-2 || tile || baresoil evap energy flux
|-
| EVPVEG || Catch || W m-2 || tile || transpiration energy flux
|-
| FRSAT || Catch || 1 || tile || fractional area of saturated zone
|-
| FRUST || Catch || 1 || tile || fractional area of unsaturated zone
|-
| FRWLT || Catch || 1 || tile || fractional area of wilting zone
|-
| GHFLX || Catch || W m-2 || tile || ground energy flux
|-
| GHLAND || Catch || W m-2 || tile || Ground heating land
|-
| GUST || Catch || m s-1 || tile || gustiness
|-
| HLATN || Catch || W m-2 || tile || total latent energy flux
|-
| HLWUP || Catch || W m-2 || tile || surface outgoing longwave flux
|-
| ICESOI || Catch || kg m-2 || tile || soil frozen water content
|-
| ITY || Catch || 1 || tile || vegetation type
|-
| LHLAND || Catch || W m-2 || tile || Latent heat flux land
|-
| LST || Catch || K || tile || land surface skin temperature
|-
| LWLAND || Catch || W m-2 || tile || Net longwave land
|-
| LWNDSRF || Catch || W m-2 || tile || surface net downward longwave flux
|-
| MOQ10M || Catch || kg kg-1 || tile || humidity 10m wind from MO sfc
|-
| MOQ2M || Catch || kg kg-1 || tile || humidity 2m wind from MO sfc
|-
| MOT10M || Catch || K || tile || temperature 10m wind from MO sfc
|-
| MOT2M || Catch || K || tile || temperature 2m wind from MO sfc
|-
| MOU10M || Catch || m s-1 || tile || zonal 10m wind from MO sfc
|-
| MOU2M || Catch || m s-1 || tile || zonal 2m wind from MO sfc
|-
| MOU50M || Catch || m s-1 || tile || zonal 50m wind from MO sfc
|-
| MOV10M || Catch || m s-1 || tile || meridional 10m wind from MO sfc
|-
| MOV2M || Catch || m s-1 || tile || meridional 2m wind from MO sfc
|-
| MOV50M || Catch || m s-1 || tile || meridional 50m wind from MO sfc
|-
| QH || Catch || kg kg-1 || tile || turbulence surface skin specific hum
|-
| QINFIL || Catch || kg m-2 s-1 || tile || rainwater infiltration flux
|-
| QST || Catch || kg kg-1 || tile || surface specific humidity
|-
| RIT || Catch || 1 || tile || surface bulk richardson number
|-
| RUNOFF || Catch || kg m-2 s-1 || tile || runoff flux
|-
| RUNSURF || Catch || kg m-2 s-1 || tile || surface runoff flux
|-
| RZEQ || Catch || kg m-2 || tile || root zone equilibrium moisture
|-
| SHLAND || Catch || W m-2 || tile || Sensible heat flux land
|-
| SHOUT || Catch || W m-2 || tile || upward sensible heat flux
|-
| SHSNOW || Catch || W m-2 || tile || downward heat flux into snow
|-
| SMELT || Catch || kg m-2 s-1 || tile || snowmelt flux
|-
| SMLAND || Catch || kg m-2 s-1 || tile || Snowmelt flux land
|-
| SNOWDP || Catch || m || tile || snow depth
|-
| SNOWMASS || Catch || kg m-2 || tile || snow mass
|-
| SPLAND || Catch || W m-2 || tile || rate of spurious land energy source
|-
| SPSNOW || Catch || W m-2 || tile || rate of spurious snow energy
|-
| SPWATR || Catch || kg m-2 s-1 || tile || rate of spurious land water source
|-
| SUBLIM || Catch || kg m-2 s-1 || tile || sublimation
|-
| SWLAND || Catch || W m-2 || tile || Net shortwave land
|-
| SWNDSRF || Catch || W m-2 || tile || surface net downward shortwave flux
|-
| TELAND || Catch || J m-2 || tile || Total energy storage land
|-
| TH || Catch || K || tile || turbulence surface skin temperature
|-
| TP1 || Catch || C || tile || soil temperatures layer 1
|-
| TP2 || Catch || C || tile || soil temperatures layer 2
|-
| TP3 || Catch || C || tile || soil temperatures layer 3
|-
| TP4 || Catch || C || tile || soil temperatures layer 4
|-
| TP5 || Catch || C || tile || soil temperatures layer 5
|-
| TP6 || Catch || C || tile || soil temperatures layer 6
|-
| TPSAT || Catch || K || tile || temperature saturated zone
|-
| TPSNOW || Catch || K || tile || temperature top snow layer
|-
| TPSURF || Catch || K || tile || ave catchment temp incl snw
|-
| TPUNST || Catch || K || tile || temperature unsaturated zone
|-
| TPWLT || Catch || K || tile || temperature wilted zone
|-
| TSLAND || Catch || kg m-2 || tile || Total snow storage land
|-
| TST || Catch || K || tile || surface skin temperature
|-
| TWLAND || Catch || kg m-2 || tile || Avail water storage land
|-
| VENT || Catch || m s-1 || tile || surface ventilation velocity
|-
| WAT10CM || Catch || kg m-2 || tile || soil moisture in Upper 10cm
|-
| WATSOI || Catch || kg m-2 || tile || totoal soil moisture
|-
| WCPR || Catch || m3 m-3 || tile || water ave prof
|-
| WCRZ || Catch || m3 m-3 || tile || water root zone
|-
| WCSF || Catch || m3 m-3 || tile || water surface layer
|-
| WET1 || Catch || 1 || tile || surface soil wetness
|-
| WET2 || Catch || 1 || tile || root zone soil wetness
|-
| WET3 || Catch || 1 || tile || ave prof soil  moisture
|-
| Z0 || Catch || m || tile || surface roughness
|-
| Z0H || Catch || m || tile || surface roughness for heat
|-
| CHEM_TRACERS || Chem || X ||  || chemistry friendly tracers
|-
| CHEM_TRACERS || Chem || X ||  || chemistry friendly tracers
|-
| CHEM_TRACERS || Chem || X ||  || chemistry friendly tracers
|-
| CHEM_TRACERS || Chem || X ||  || chemistry friendly tracers
|-
| CHEM_TRACERS || Chem || X ||  || chemistry friendly tracers
|-
| AIRDENS || ChemEnv || kg m-3 || xyz || air density
|-
| CN_PRCP || ChemEnv || kg m-2 s-1 || xy || Convective precipitation
|-
| DELP || ChemEnv || Pa || xyz || pressure thickness
|-
| NCN_PRCP || ChemEnv || kg m-2 s-1 || xy || Non-convective precipitation
|-
| TPREC || ChemEnv || kg m-2 s-1 || xy || total precipitation
|-
| TS_FOUND || DataSea || K || xy || foundation temperature for interface layer
|-
| UW || DataSea || m s-1 || xy || zonal velocity of surface water
|-
| VW || DataSea || m s-1 || xy || meridional velocity of surface water
|-
| FRACICE || DataSeaIce || 1 || xy || fractional cover of seaice
|-
| MELTQ || DataSeaIce || W m-2 || xy || heat of melting or freezing
|-
| UI || DataSeaIce || m s-1 || xy || zonal velocity of surface seaice
|-
| VI || DataSeaIce || m s-1 || xy || meridional velocity of surface seaice
|-
| AREA || DatmoDyn || m+2 || xy || agrid cell area
|-
| DCLCNDTDYN || DatmoDyn || fraction || xyz || tendency of convective cloud fraction due to dynamics
|-
| DCLLSDTDYN || DatmoDyn || fraction || xyz || tendency of large scale cloud fraction due to dynamics
|-
| DIV || DatmoDyn || s-1 || xyz || divergence
|-
| DOXDTANAINT || DatmoDyn || kg m-2 s-1 || xy || vertically integrated ozone tendency due to analysis
|-
| DQICNDTDYN || DatmoDyn || kgkgsec || xyz || tendency of convective cloud ice due to dynamics
|-
| DQIDTANAINT || DatmoDyn || kg m-2 s-1 || xy || vertically integrated ice water tendency due to analysis
|-
| DQILSDTDYN || DatmoDyn || kgkgsec || xyz || tendency of large scale cloud ice due to dynamics
|-
| DQLCNDTDYN || DatmoDyn || kgkgsec || xyz || tendency of convective cloud water due to dynamics
|-
| DQLDTANAINT || DatmoDyn || kg m-2 s-1 || xy || vertically integrated liquid water tendency due to analysis
|-
| DQLLSDTDYN || DatmoDyn || kgkgsec || xyz || tendency of large scale cloud water due to dynamics
|-
| DQVDTANAINT || DatmoDyn || kg m-2 s-1 || xy || vertically integrated water vapor tendency due to analysis
|-
| DQVDTDYN || DatmoDyn || kgkgsec || xyz || tendency of specific humidity due to dynamics
|-
| DQVDTDYNINT || DatmoDyn || kg m-2 s-1 || xy || vertically integrated water vapor tendency due to dynamics
|-
| DTDTDYN || DatmoDyn || K sec-1 || xyz || tendency of air temperature due to dynamics
|-
| DTHVDTANAINT || DatmoDyn || K kg m-2 s-1 || xy || vertically integrated THV tendency due to analysis
|-
| DTHVDTPHYINT || DatmoDyn || K kg m-2 s-1 || xy || vertically integrated THV tendency due to physics
|-
| DZ || DatmoDyn || m || xy || Surface layer height
|-
| EPV || DatmoDyn || K m+2 kg-1 sec-1 || xyz || ertels potential vorticity
|-
| HDQDTDYN || DatmoDyn || kgkgsec || xyz || horiz tendency of specific humidity due to dynamics
|-
| HDTDTDYN || DatmoDyn || K sec-1 || xyz || horiz tendency of air temperature due to dynamics
|-
| HDTHDTDYN || DatmoDyn || K sec-1 || xyz || horiz tendency of air pot temp due to dynamics
|-
| LHOBS || DatmoDyn || W m-2 || xy || Obs. latent heat flux (surface)
|-
| OMEGA || DatmoDyn || Pas || xyz || pressure velocity
|-
| PCPOBS || DatmoDyn || mmd || xy || Obs. precipitation rate
|-
| PEANA || DatmoDyn || W m-2 || xy || total potential energy tendency due to analysis
|-
| PEPHY || DatmoDyn || W m-2 || xy || total potential energy tendency due to physics
|-
| PHIS || DatmoDyn || K || xy || obs skin temperature
|-
| PL || DatmoDyn || Pa || xyz || midlevel pressures
|-
| PLE || DatmoDyn || Pascals || xyz || Pressure at the edges
|-
| PLK || DatmoDyn || J kg-1 || xyz || Exner quantity
|-
| PS || DatmoDyn || Pa || xy || Surface Pressure
|-
| PSFCOBS || DatmoDyn || [PahPa] || xy || Obs. Sfc. Pressure
|-
| PV || DatmoDyn || m+2 kg-1 sec-1 || xyz || ertels isentropic potential vorticity
|-
| Q || DatmoDyn || ms || xyz || meridional wind
|-
| QA || DatmoDyn || 1 || xy || Surface air spec humidity
|-
| QHATOBS || DatmoDyn || K s-1 || xyz || Obs. Moisture Tendency H adv
|-
| QIOBS || DatmoDyn || 1 || xyz || Obs. Cloud ice
|-
| QLOBS || DatmoDyn || 1 || xyz || Obs. Cloud liquid
|-
| QOBS || DatmoDyn || 1 || xyz || Obs. Spec. Humidity
|-
| QSKINOBS || DatmoDyn || 1 || xy || obs skin spec humidity whatever that means
|-
| QTEST || DatmoDyn || 1 || xyz || test tracer
|-
| QVATOBS || DatmoDyn || K s-1 || xyz || Obs. Moisture Tendency V adv
|-
| S || DatmoDyn || J kg-1 || xyz || static energy
|-
| SHOBS || DatmoDyn || W m-2 || xy || Obs. sensible heat flux (surface)
|-
| SPEED || DatmoDyn || m s-1 || xy || Surface wind speed
|-
| T || DatmoDyn || K || xyz || air temperature
|-
| TA || DatmoDyn || K || xy || Surface air temperature
|-
| TGSOILOBS || DatmoDyn || K || xy || Obs. Soil Temp.
|-
| TH || DatmoDyn || K || xyz || potential temperature
|-
| THATOBS || DatmoDyn || K s-1 || xyz || Obs. Temperature Tendency H adv
|-
| TOBS || DatmoDyn || K || xyz || Obs. Temperature
|-
| TROPP_BLENDED || DatmoDyn || Pa || xy || tropopause pressure based on blended estimate
|-
| TSAIROBS || DatmoDyn || K || xy || Obs. sfc(2m?) air temp.
|-
| TSKINOBS || DatmoDyn || K || xy || obs skin temperature
|-
| TV || DatmoDyn || K || xyz || air virtual temperature
|-
| TVATOBS || DatmoDyn || K s-1 || xyz || Obs. Temperature Tendency V adv
|-
| U || DatmoDyn || ms || xyz || Zonal wind
|-
| UE || DatmoDyn || m s-1 || xyz || Diagnosed Edge Winds
|-
| V || DatmoDyn || ms || xyz || meridional wind
|-
| VARFLT || DatmoDyn || K || xy || obs skin temperature
|-
| VDQDTDYN || DatmoDyn || kgkgsec || xyz || vertical tendency of specific humidity due to dynamics
|-
| VDTDTDYN || DatmoDyn || K sec-1 || xyz || vertical tendency of air temperature due to dynamics
|-
| VDTHDTDYN || DatmoDyn || K sec-1 || xyz || vertical tendency of air pot temp due to dynamics
|-
| WTOT || DatmoDyn || m s-1 || xyz || total vertical velocity
|-
| WWTG || DatmoDyn || m s-1 || xyz || weak T-gradient compensating W
|-
| ZLE || DatmoDyn || m || xyz || Geop. height at the edges
|-
| AK || DynCore || 1 || z || hybrid sigma pressure a
|-
| AREA || DynCore || m+2 || xy || agrid cell area
|-
| BK || DynCore || 1 || z || hybrid sigma pressure b
|-
| CNV || DynCore || W m-2 || xy || generation of atmosphere kinetic energy content
|-
| CONVCPT || DynCore || W m-2 || xy || vertically integrated enthalpy convergence
|-
| CONVKE || DynCore || W m-2 || xy || vertically integrated kinetic energy convergence
|-
| CONVPHI || DynCore || W m-2 || xy || vertically integrated geopotential convergence
|-
| CONVTHV || DynCore || W m-2 || xy || vertically integrated thetav convergence
|-
| DCPT || DynCore || W m-2 || xy || tendency of atmosphere dry energy content due to dynamics
|-
| DDELPDTANA || DynCore || K s-1 || xyz || tendency of pressure thickness due to analysis
|-
| DDELPDTDYN || DynCore || Pa s-1 || xyz || tendency of pressure thickness due to dynamics
|-
| DELP || DynCore || Pa || xyz || pressure thickness
|-
| DELPTOP || DynCore || Pa || xy || pressure thickness at model top
|-
| DKE || DynCore || W m-2 || xy || tendency of atmosphere kinetic energy content due to dynamics
|-
| DKERESIN || DynCore || W m-2 || xy || vertically integrated kinetic energy residual from inertial terms
|-
| DKERESPG || DynCore || W m-2 || xy || vertically integrated kinetic energy residual from PG terms
|-
| DMDTANA || DynCore || kg m-2 s-1 || xy || vertically integrated mass tendency due to analysis
|-
| DMDTDYN || DynCore || kg m-2 s-1 || xy || vertically integrated mass tendency due to dynamics
|-
| DOXDTANAINT || DynCore || kg m-2 s-1 || xy || vertically integrated ozone tendency due to analysis
|-
| DOXDTDYN || DynCore || kgkgs || xyz || tendency of ozone due to dynamics
|-
| DOXDTDYNINT || DynCore || kg m-2 s-1 || xy || vertically integrated ozone tendency due to dynamics
|-
| DPET || DynCore || W m-2 || xy || tendency of atmosphere topographic potential energy due to dynamics
|-
| DQI || DynCore || kg m-2 s-1 || xy || tendency of atmosphere ice content due to dynamics
|-
| DQIDTANAINT || DynCore || kg m-2 s-1 || xy || vertically integrated ice water tendency due to analysis
|-
| DQIDTDYN || DynCore || kgkgs || xyz || tendency of ice water due to dynamics
|-
| DQIDTDYNINT || DynCore || kg m-2 s-1 || xy || vertically integrated ice water tendency due to dynamics
|-
| DQL || DynCore || kg m-2 s-1 || xy || tendency of atmosphere liquid water content due to dynamics
|-
| DQLDTANAINT || DynCore || kg m-2 s-1 || xy || vertically integrated liquid water tendency due to analysis
|-
| DQLDTDYN || DynCore || kgkgs || xyz || tendency of liquid water due to dynamics
|-
| DQLDTDYNINT || DynCore || kg m-2 s-1 || xy || vertically integrated liquid water tendency due to dynamics
|-
| DQV || DynCore || kg m-2 s-1 || xy || tendency of atmosphere water vapor content due to dynamics
|-
| DQVDTANAINT || DynCore || kg m-2 s-1 || xy || vertically integrated water vapor tendency due to analysis
|-
| DQVDTDYN || DynCore || kgkgs || xyz || tendency of specific humidity due to dynamics
|-
| DQVDTDYNINT || DynCore || kg m-2 s-1 || xy || vertically integrated water vapor tendency due to dynamics
|-
| DTDTANA || DynCore || K s-1 || xyz || tendency of air temperature due to analysis
|-
| DTDTDYN || DynCore || K s-1 || xyz || tendency of air temperature due to dynamics
|-
| DTHVDTANAINT || DynCore || K kg m-2 s-1 || xy || vertically integrated THV tendency due to analysis
|-
| DTHVDTCONSV || DynCore || K kg m-2 s-1 || xy || vertically integrated THV tendency due to TE conservation
|-
| DTHVDTDYNINT || DynCore || K kg m-2 s-1 || xy || vertically integrated THV tendency due to dynamics
|-
| DTHVDTPHYINT || DynCore || K kg m-2 s-1 || xy || vertically integrated THV tendency due to physics
|-
| DTHVDTREMAP || DynCore || K kg m-2 s-1 || xy || vertically integrated THV tendency due to vertical remapping
|-
| DUDTANA || DynCore || mss || xyz || tendency of eastward wind due to analysis
|-
| DUDTDYN || DynCore || mss || xyz || tendency of eastward wind due to dynamics
|-
| DVDTANA || DynCore || mss || xyz || tendency of northward wind due to analysis
|-
| DVDTDYN || DynCore || mss || xyz || tendency of northward wind due to dynamics
|-
| DZ || DynCore || m || xy || surface layer height
|-
| EPV || DynCore || K m+2 kg-1 s-1 || xyz || ertels potential vorticity
|-
| H1000 || DynCore || m || xy || height at 1000 mb
|-
| H250 || DynCore || m || xy || height at 250 hPa
|-
| H300 || DynCore || m || xy || height at 300 hPa
|-
| H500 || DynCore || m || xy || height at 500 hPa
|-
| H700 || DynCore || m || xy || height at 700 hPa
|-
| H850 || DynCore || m || xy || height at 850 hPa
|-
| KE || DynCore || J m-2 || xy || vertically integrated kinetic energy
|-
| KEADV || DynCore || W m-2 || xy || vertically integrated kinetic energy tendency due to dynamics advection
|-
| KEANA || DynCore || W m-2 || xy || total kinetic energy tendency due to analysis
|-
| KECDCOR || DynCore || W m-2 || xy || vertically integrated kinetic energy tendency due to cdcore
|-
| KEDP || DynCore || W m-2 || xy || vertically integrated kinetic energy tendency due to pressure change
|-
| KEDYN || DynCore || W m-2 || xy || vertically integrated kinetic energy tendency due to dynamics
|-
| KEGEN || DynCore || W m-2 || xy || vertically integrated generation of kinetic energy
|-
| KEHOT || DynCore || W m-2 || xy || vertically integrated kinetic energy tendency due to HOT
|-
| KEPG || DynCore || W m-2 || xy || vertically integrated kinetic energy tendency due to pressure gradient
|-
| KEPHY || DynCore || W m-2 || xy || vertically integrated kinetic energy tendency due to physics
|-
| KEREMAP || DynCore || W m-2 || xy || vertically integrated kinetic energy tendency due to remap
|-
| MFX || DynCore || Pa m+2 s-1 || xyz || pressure weighted eastward wind
|-
| MFX_A || DynCore || Pa m+2 s-1 || xyz || zonal mass flux
|-
| MFX_UR || DynCore || Pa m+2 s-1 || xyz || pressure weighted eastward wind unremapped
|-
| MFY || DynCore || Pa m+2 s-1 || xyz || pressure weighted northward wind
|-
| MFY_A || DynCore || Pa m+2 s-1 || xyz || meridional mass flux
|-
| MFY_UR || DynCore || Pa m+2 s-1 || xyz || pressure weighted northward wind unremapped
|-
| MFZ || DynCore || kg m-2 s-1 || xyz || vertical mass flux
|-
| OMEGA || DynCore || Pa s-1 || xyz || vertical pressure velocity
|-
| OMEGA10 || DynCore || Pa s-1 || xy || omega at 10 hPa
|-
| OMEGA200 || DynCore || Pa s-1 || xy || omega at 200 hPa
|-
| OMEGA500 || DynCore || Pa s-1 || xy || omega at 500 hPa
|-
| OMEGA850 || DynCore || Pa s-1 || xy || omega at 850 hPa
|-
| PE || DynCore || Pa || xyz || air pressure
|-
| PEANA || DynCore || W m-2 || xy || total potential energy tendency due to analysis
|-
| PECDCOR || DynCore || W m-2 || xy || vertically integrated potential energy tendency due to cdcore
|-
| PEDYN || DynCore || W m-2 || xy || vertically integrated potential energy tendency due to dynamics
|-
| PEPHY || DynCore || W m-2 || xy || total potential energy tendency due to physics
|-
| PEREMAP || DynCore || W m-2 || xy || vertically integrated potential energy tendency due to remap
|-
| PHIS || DynCore || m || xy || surface height
|-
| PL || DynCore || Pa || xyz || mid level pressure
|-
| PLE || DynCore || Pa || xyz || edge pressure
|-
| PLK || DynCore || Pa$^\kappa$ || xyz || mid-layer p$^\kappa$
|-
| PREF || DynCore || Pa || z || reference air pressure
|-
| PS || DynCore || Pa || xy || surface pressure
|-
| PT || DynCore || K Pa$^{-\kappa}$ || xyz || scaled potential temperature
|-
| PTFX || DynCore || K Pa m+2 s-1 || xyz || pressure weighted eastward potential temperature flux unremapped
|-
| PTFY || DynCore || K Pa m+2 s-1 || xyz || pressure weighted northward potential temperature flux unremapped
|-
| PV || DynCore || m+2 kg-1 s-1 || xyz || ertels isentropic potential vorticity
|-
| Q || DynCore || 1 || xyz || specific humidity
|-
| Q250 || DynCore || kg kg-1 || xy || specific humidity at 250 hPa
|-
| Q500 || DynCore || kg kg-1 || xy || specific humidity at 500 hPa
|-
| Q850 || DynCore || kg kg-1 || xy || specific humidity at 850 hPa
|-
| QA || DynCore || 1 || xy || surface specific humidity
|-
| QFIXER || DynCore || W m-2 || xy || vertically integrated potential energy tendency due to CONSV
|-
| S || DynCore || m || xyz || mid layer dry static energy
|-
| SLP || DynCore || Pa || xy || sea level pressure
|-
| SPEED || DynCore || m s-1 || xy || surface wind speed
|-
| T || DynCore || K || xyz || air temperature
|-
| T250 || DynCore || K || xy || air temperature at 250 hPa
|-
| T300 || DynCore || K || xy || air temperature at 300 hPa
|-
| T500 || DynCore || K || xy || air temperature at 500 hPa
|-
| T700 || DynCore || K || xy || air temperature at 700 hPa
|-
| T850 || DynCore || K || xy || air temperature at 850 hPa
|-
| TA || DynCore || K || xy || surface air temperature
|-
| TAVE || DynCore || K || xy || vertically averaged dry temperature
|-
| TEANA || DynCore || W m-2 || xy || mountain work tendency due to analysis
|-
| TECDCOR || DynCore || W m-2 || xy || mountain work tendency due to cdcore
|-
| TEDYN || DynCore || W m-2 || xy || mountain work tendency due to dynamics
|-
| TEPHY || DynCore || W m-2 || xy || mountain work tendency due to physics
|-
| TEREMAP || DynCore || W m-2 || xy || mountain work tendency due to remap
|-
| TH || DynCore || K || xyz || potential temperature
|-
| THV || DynCore || KPa$^\kappa$ || xyz || scaled virtual potential temperature
|-
| TROPP_BLENDED || DynCore || Pa || xy || tropopause pressure based on blended estimate
|-
| TROPP_EPV || DynCore || Pa || xy || tropopause pressure based on EPV estimate
|-
| TROPP_THERMAL || DynCore || Pa || xy || tropopause pressure based on thermal estimate
|-
| TROPQ || DynCore || kgkg || xy || tropopause specific humidity using blended TROPP estimate
|-
| TROPT || DynCore || K || xy || tropopause temperature using blended TROPP estimate
|-
| TTOP || DynCore || K || xy || air temperature at model top
|-
| TV || DynCore || K || xyz || air virtual temperature
|-
| U || DynCore || m s-1 || xyz || eastward wind
|-
| U200 || DynCore || m s-1 || xy || eastward wind at 200 hPa
|-
| U250 || DynCore || m s-1 || xy || eastward wind at 250 hPa
|-
| U500 || DynCore || m s-1 || xy || eastward wind at 500 hPa
|-
| U50M || DynCore || m s-1 || xy || eastward wind at 50 meters
|-
| U700 || DynCore || m s-1 || xy || eastward wind at 700 hPa
|-
| U850 || DynCore || m s-1 || xy || eastward wind at 850 hPa
|-
| UAVE || DynCore || m sec-1 || xy || vertically averaged zonal wind
|-
| UCPT || DynCore || J m-1 s-1 || xy || eastward flux of atmospheric enthalpy
|-
| UKE || DynCore || J m-1 s-1 || xy || eastward flux of atmospheric kinetic energy
|-
| UNKNOWN || DynCore || 1 || xy || UNKNOWN
|-
| UNKNOWN || DynCore || 1 || xyz || UNKNOWN
|-
| UPHI || DynCore || J m-1 s-1 || xy || eastward flux of atmospheric potential energy
|-
| UQI || DynCore || kg m-1 s-1 || xy || eastward flux of atmospheric ice
|-
| UQL || DynCore || kg m-1 s-1 || xy || eastward flux of atmospheric liquid water
|-
| UQV || DynCore || kg m-1 s-1 || xy || eastward flux of atmospheric water vapor
|-
| US || DynCore || m s-1 || xy || surface eastward wind
|-
| UTOP || DynCore || m s-1 || xy || eastward wind at model top
|-
| U_CGRID || DynCore || m s-1 || xyz || eastward wind on C-Grid
|-
| U_DGRID || DynCore || m s-1 || xyz || eastward wind on native D-Grid
|-
| V || DynCore || m s-1 || xyz || northward wind
|-
| V200 || DynCore || m s-1 || xy || northward wind at 200 hPa
|-
| V250 || DynCore || m s-1 || xy || northward wind at 250 hPa
|-
| V500 || DynCore || m s-1 || xy || northward wind at 500 hPa
|-
| V50M || DynCore || m s-1 || xy || northward wind at 50 meters
|-
| V700 || DynCore || m s-1 || xy || northward wind at 700 hPa
|-
| V850 || DynCore || m s-1 || xy || northward wind at 850 hPa
|-
| VCPT || DynCore || J m-1 s-1 || xy || northward flux of atmospheric enthalpy
|-
| VKE || DynCore || J m-1 s-1 || xy || northward flux of atmospheric kinetic energy
|-
| VORT || DynCore || s-1 || xyz || vorticity
|-
| VORT200 || DynCore || m s-1 || xy || vorticity at 200 hPa
|-
| VORT700 || DynCore || m s-1 || xy || vorticity at 700 hPa
|-
| VORT850 || DynCore || m s-1 || xy || vorticity at 850 hPa
|-
| VPHI || DynCore || J m-1 s-1 || xy || northward flux of atmospheric potential energy
|-
| VQI || DynCore || kg m-1 s-1 || xy || northward flux of atmospheric ice
|-
| VQL || DynCore || kg m-1 s-1 || xy || northward flux of atmospheric liquid water
|-
| VQV || DynCore || kg m-1 s-1 || xy || northward flux of atmospheric water vapor
|-
| VS || DynCore || m s-1 || xy || surface northward wind
|-
| VTOP || DynCore || m s-1 || xy || northward wind at model top
|-
| V_CGRID || DynCore || m s-1 || xyz || northward wind on C-Grid
|-
| V_DGRID || DynCore || m s-1 || xyz || northward wind on native D-Grid
|-
| W || DynCore || m s-1 || xyz || vertical velocity
|-
| W10 || DynCore || m s-1 || xy || w at 10 hPa
|-
| W200 || DynCore || m s-1 || xy || w at 200 hPa
|-
| W500 || DynCore || m s-1 || xy || w at 500 hPa
|-
| W850 || DynCore || m s-1 || xy || w at 850 hPa
|-
| WRKT || DynCore || W m-2 || xy || work done by atmosphere at top
|-
| Z300 || DynCore || m || xy || geopotential height at 300 hPa
|-
| Z500 || DynCore || m || xy || geopotential height at 500 hPa
|-
| Z700 || DynCore || m || xy || geopotential height at 700 hPa
|-
| ZL || DynCore || m || xyz || mid layer heights
|-
| ZLE || DynCore || m || xyz || edge heights
|-
| AK || FVdycore || 1 || z || hybrid sigma pressure a
|-
| AREA || FVdycore || m+2 || xy || agrid cell area
|-
| BK || FVdycore || 1 || z || hybrid sigma pressure b
|-
| CNV || FVdycore || W m-2 || xy || generation of atmosphere kinetic energy content
|-
| CONVCPT || FVdycore || W m-2 || xy || vertically integrated enthalpy convergence
|-
| CONVKE || FVdycore || W m-2 || xy || vertically integrated kinetic energy convergence
|-
| CONVPHI || FVdycore || W m-2 || xy || vertically integrated geopotential convergence
|-
| CONVTHV || FVdycore || W m-2 || xy || vertically integrated thetav convergence
|-
| DCPT || FVdycore || W m-2 || xy || tendency of atmosphere dry energy content due to dynamics
|-
| DDELPDTANA || FVdycore || K s-1 || xyz || tendency of pressure thickness due to analysis
|-
| DDELPDTDYN || FVdycore || Pa s-1 || xyz || tendency of pressure thickness due to dynamics
|-
| DELP || FVdycore || Pa || xyz || pressure thickness
|-
| DKE || FVdycore || W m-2 || xy || tendency of atmosphere kinetic energy content due to dynamics
|-
| DKERESIN || FVdycore || W m-2 || xy || vertically integrated kinetic energy residual from inertial terms
|-
| DKERESPG || FVdycore || W m-2 || xy || vertically integrated kinetic energy residual from PG terms
|-
| DMDTANA || FVdycore || kg m-2 s-1 || xy || vertically integrated mass tendency due to analysis
|-
| DMDTDYN || FVdycore || kg m-2 s-1 || xy || vertically integrated mass tendency due to dynamics
|-
| DOXDTANAINT || FVdycore || kg m-2 s-1 || xy || vertically integrated ozone tendency due to analysis
|-
| DOXDTDYN || FVdycore || kg kg-1 s-1 || xyz || tendency of ozone due to dynamics
|-
| DOXDTDYNINT || FVdycore || kg m-2 s-1 || xy || vertically integrated ozone tendency due to dynamics
|-
| DPET || FVdycore || W m-2 || xy || tendency of atmosphere topographic potential energy due to dynamics
|-
| DQI || FVdycore || kg m-2 s-1 || xy || tendency of atmosphere ice content due to dynamics
|-
| DQIDTANAINT || FVdycore || kg m-2 s-1 || xy || vertically integrated ice water tendency due to analysis
|-
| DQIDTDYN || FVdycore || kg kg-1 s-1 || xyz || tendency of ice water due to dynamics
|-
| DQIDTDYNINT || FVdycore || kg m-2 s-1 || xy || vertically integrated ice water tendency due to dynamics
|-
| DQL || FVdycore || kg m-2 s-1 || xy || tendency of atmosphere liquid water content due to dynamics
|-
| DQLDTANAINT || FVdycore || kg m-2 s-1 || xy || vertically integrated liquid water tendency due to analysis
|-
| DQLDTDYN || FVdycore || kg kg-1 s-1 || xyz || tendency of liquid water due to dynamics
|-
| DQLDTDYNINT || FVdycore || kg m-2 s-1 || xy || vertically integrated liquid water tendency due to dynamics
|-
| DQV || FVdycore || kg m-2 s-1 || xy || tendency of atmosphere water vapor content due to dynamics
|-
| DQVDTANAINT || FVdycore || kg m-2 s-1 || xy || vertically integrated water vapor tendency due to analysis
|-
| DQVDTDYN || FVdycore || kg kg-1 s-1 || xyz || tendency of specific humidity due to dynamics
|-
| DQVDTDYNINT || FVdycore || kg m-2 s-1 || xy || vertically integrated water vapor tendency due to dynamics
|-
| DTDTANA || FVdycore || K s-1 || xyz || tendency of air temperature due to analysis
|-
| DTDTDYN || FVdycore || K s-1 || xyz || tendency of air temperature due to dynamics
|-
| DTHVDTANAINT || FVdycore || K kg m-2 s-1 || xy || vertically integrated THV tendency due to analysis
|-
| DTHVDTCONSV || FVdycore || K kg m-2 s-1 || xy || vertically integrated THV tendency due to TE conservation
|-
| DTHVDTDYNINT || FVdycore || K kg m-2 s-1 || xy || vertically integrated THV tendency due to dynamics
|-
| DTHVDTPHYINT || FVdycore || K kg m-2 s-1 || xy || vertically integrated THV tendency due to physics
|-
| DTHVDTREMAP || FVdycore || K kg m-2 s-1 || xy || vertically integrated THV tendency due to vertical remapping
|-
| DUDTANA || FVdycore || m s-2 || xyz || tendency of eastward wind due to analysis
|-
| DUDTDYN || FVdycore || m s-2 || xyz || tendency of eastward wind due to dynamics
|-
| DVDTANA || FVdycore || m s-2 || xyz || tendency of northward wind due to analysis
|-
| DVDTDYN || FVdycore || m s-2 || xyz || tendency of northward wind due to dynamics
|-
| DZ || FVdycore || m || xy || surface layer height
|-
| EPV || FVdycore || K m+2 kg-1 s-1 || xyz || ertels potential vorticity
|-
| H1000 || FVdycore || m || xy || height at 1000 mb
|-
| H250 || FVdycore || m || xy || height at 250 hPa
|-
| H500 || FVdycore || m || xy || height at 500 hPa
|-
| H850 || FVdycore || m || xy || height at 850 hPa
|-
| KE || FVdycore || J m-2 || xy || vertically integrated kinetic energy
|-
| KEADV || FVdycore || W m-2 || xy || vertically integrated kinetic energy tendency due to dynamics advection
|-
| KEANA || FVdycore || W m-2 || xy || total kinetic energy tendency due to analysis
|-
| KECDCOR || FVdycore || W m-2 || xy || vertically integrated kinetic energy tendency due to cdcore
|-
| KEDP || FVdycore || W m-2 || xy || vertically integrated kinetic energy tendency due to pressure change
|-
| KEDYN || FVdycore || W m-2 || xy || vertically integrated kinetic energy tendency due to dynamics
|-
| KEGEN || FVdycore || W m-2 || xy || vertically integrated generation of kinetic energy
|-
| KEHOT || FVdycore || W m-2 || xy || vertically integrated kinetic energy tendency due to HOT
|-
| KEPG || FVdycore || W m-2 || xy || vertically integrated kinetic energy tendency due to pressure gradient
|-
| KEPHY || FVdycore || W m-2 || xy || vertically integrated kinetic energy tendency due to physics
|-
| KEREMAP || FVdycore || W m-2 || xy || vertically integrated kinetic energy tendency due to remap
|-
| MFX || FVdycore || Pa m+2 s-1 || xyz || pressure weighted eastward wind
|-
| MFX_A || FVdycore || Pa m+2 s-1 || xyz || zonal mass flux
|-
| MFX_UR || FVdycore || Pa m+2 s-1 || xyz || pressure weighted eastward wind unremapped
|-
| MFY || FVdycore || Pa m+2 s-1 || xyz || pressure weighted northward wind
|-
| MFY_A || FVdycore || Pa m+2 s-1 || xyz || meridional mass flux
|-
| MFY_UR || FVdycore || Pa m+2 s-1 || xyz || pressure weighted northward wind unremapped
|-
| MFZ || FVdycore || kg m-2 s-1 || xyz || vertical mass flux
|-
| OMEGA || FVdycore || Pa s-1 || xyz || vertical pressure velocity
|-
| OMEGA500 || FVdycore || Pa s-1 || xy || omega at 500 hPa
|-
| PE || FVdycore || Pa || xyz || air pressure
|-
| PEANA || FVdycore || W m-2 || xy || total potential energy tendency due to analysis
|-
| PECDCOR || FVdycore || W m-2 || xy || vertically integrated potential energy tendency due to cdcore
|-
| PEDYN || FVdycore || W m-2 || xy || vertically integrated potential energy tendency due to dynamics
|-
| PEPHY || FVdycore || W m-2 || xy || total potential energy tendency due to physics
|-
| PEREMAP || FVdycore || W m-2 || xy || vertically integrated potential energy tendency due to remap
|-
| PL || FVdycore || Pa || xyz || mid level pressure
|-
| PLE || FVdycore || Pa || xyz || edge pressure
|-
| PLK || FVdycore || Pa$^\kappa$ || xyz || mid layer $p^\kappa$
|-
| PREF || FVdycore || Pa || z || reference air pressure
|-
| PS || FVdycore || Pa || xy || surface pressure
|-
| PT || FVdycore || K Pa$^{-\kappa}$ || xyz || scaled potential temperature
|-
| PTFX || FVdycore || K Pa m+2 s-1 || xyz || pressure weighted eastward potential temperature flux unremapped
|-
| PTFY || FVdycore || K Pa m+2 s-1 || xyz || pressure weighted northward potential temperature flux unremapped
|-
| PV || FVdycore || m+2 kg-1 s-1 || xyz || ertels isentropic potential vorticity
|-
| Q || FVdycore || kg kg-1 || xyz || specific humidity
|-
| Q250 || FVdycore || kg kg-1 || xy || specific humidity at 250 hPa
|-
| Q500 || FVdycore || kg kg-1 || xy || specific humidity at 500 hPa
|-
| Q850 || FVdycore || kg kg-1 || xy || specific humidity at 850 hPa
|-
| QA || FVdycore || kg kg-1 || xy || surface specific humidity
|-
| QFIXER || FVdycore || W m-2 || xy || vertically integrated potential energy tendency due to CONSV
|-
| S || FVdycore || m || xyz || mid layer dry static energy
|-
| SLP || FVdycore || Pa || xy || sea level pressure
|-
| SPEED || FVdycore || m s-1 || xy || surface wind speed
|-
| T || FVdycore || K || xyz || air temperature
|-
| T250 || FVdycore || K || xy || air temperature at 250 hPa
|-
| T500 || FVdycore || K || xy || air temperature at 500 hPa
|-
| T850 || FVdycore || K || xy || air temperature at 850 hPa
|-
| TA || FVdycore || K || xy || surface air temperature
|-
| TAVE || FVdycore || K || xy || vertically averaged dry temperature
|-
| TEANA || FVdycore || W m-2 || xy || mountain work tendency due to analysis
|-
| TECDCOR || FVdycore || W m-2 || xy || mountain work tendency due to cdcore
|-
| TEDYN || FVdycore || W m-2 || xy || mountain work tendency due to dynamics
|-
| TEPHY || FVdycore || W m-2 || xy || mountain work tendency due to physics
|-
| TEREMAP || FVdycore || W m-2 || xy || mountain work tendency due to remap
|-
| TH || FVdycore || K || xyz || potential temperature
|-
| THV || FVdycore || KPa$^\kappa$ || xyz || scaled virtual potential temperature
|-
| TROPP_BLENDED || FVdycore || Pa || xy || tropopause pressure based on blended estimate
|-
| TROPP_EPV || FVdycore || Pa || xy || tropopause pressure based on EPV estimate
|-
| TROPP_THERMAL || FVdycore || Pa || xy || tropopause pressure based on thermal estimate
|-
| TROPQ || FVdycore || kg kg-1 || xy || tropopause specific humidity using blended TROPP estimate
|-
| TROPT || FVdycore || K || xy || tropopause temperature using blended TROPP estimate
|-
| TV || FVdycore || K || xyz || air virtual temperature
|-
| U || FVdycore || m s-1 || xyz || eastward wind
|-
| U250 || FVdycore || m s-1 || xy || eastward wind at 250 hPa
|-
| U500 || FVdycore || m s-1 || xy || eastward wind at 500 hPa
|-
| U50M || FVdycore || m s-1 || xy || eastward wind at 50 meters
|-
| U850 || FVdycore || m s-1 || xy || eastward wind at 850 hPa
|-
| UAVE || FVdycore || m s-1 || xy || vertically averaged zonal wind
|-
| UCPT || FVdycore || J m-1 s-1 || xy || eastward flux of atmospheric enthalpy
|-
| UKE || FVdycore || J m-1 s-1 || xy || eastward flux of atmospheric kinetic energy
|-
| UPHI || FVdycore || J m-1 s-1 || xy || eastward flux of atmospheric potential energy
|-
| UQI || FVdycore || kg m-1 s-1 || xy || eastward flux of atmospheric ice
|-
| UQL || FVdycore || kg m-1 s-1 || xy || eastward flux of atmospheric liquid water
|-
| UQV || FVdycore || kg m-1 s-1 || xy || eastward flux of atmospheric water vapor
|-
| US || FVdycore || m s-1 || xy || surface eastward wind
|-
| U_CGRID || FVdycore || m s-1 || xyz || eastward wind on C-Grid
|-
| U_DGRID || FVdycore || m s-1 || xyz || eastward wind on native D-Grid
|-
| V || FVdycore || m s-1 || xyz || northward wind
|-
| V250 || FVdycore || m s-1 || xy || northward wind at 250 hPa
|-
| V500 || FVdycore || m s-1 || xy || northward wind at 500 hPa
|-
| V50M || FVdycore || m s-1 || xy || northward wind at 50 meters
|-
| V850 || FVdycore || m s-1 || xy || northward wind at 850 hPa
|-
| VCPT || FVdycore || J m-1 s-1 || xy || northward flux of atmospheric enthalpy
|-
| VKE || FVdycore || J m-1 s-1 || xy || northward flux of atmospheric kinetic energy
|-
| VPHI || FVdycore || J m-1 s-1 || xy || northward flux of atmospheric potential energy
|-
| VQI || FVdycore || kg m-1 s-1 || xy || northward flux of atmospheric ice
|-
| VQL || FVdycore || kg m-1 s-1 || xy || northward flux of atmospheric liquid water
|-
| VQV || FVdycore || kg m-1 s-1 || xy || northward flux of atmospheric water vapor
|-
| VS || FVdycore || m s-1 || xy || surface northward wind
|-
| V_CGRID || FVdycore || m s-1 || xyz || northward wind on C-Grid
|-
| V_DGRID || FVdycore || m s-1 || xyz || northward wind on native D-Grid
|-
| WRKT || FVdycore || W m-2 || xy || work done by atmosphere at top
|-
| ZL || FVdycore || m || xyz || mid layer heights
|-
| ZLE || FVdycore || m || xyz || edge heights
|-
| AODANA || GAAS || 1 || xy || Aerosol Optical Depth Analysis
|-
| AODINC || GAAS || 1 || xy || Aerosol Optical Depth Analysis Increment
|-
| BCANA || GAAS || kgkg || xyz || Black Carbon Mixing Ratio Analysis
|-
| BCINC || GAAS || kgkg || xyz || Black Carbon Mixing Ratio Analysis Increments
|-
| DUANA || GAAS || kgkg || xyz || Dust Mixing Ratio Analysis
|-
| DUINC || GAAS || kgkg || xyz || Dust Mixing Ratio Analysis Increments
|-
| OCANA || GAAS || kgkg || xyz || Organic Carbon Mixing Ratio Analysis
|-
| OCINC || GAAS || kgkg || xyz || Organic Carbon Mixing Ratio Analysis Increments
|-
| SSANA || GAAS || kgkg || xyz || Sea-salt Mixing Ratio Analysis
|-
| SSINC || GAAS || kgkg || xyz || Sea-salt Mixing Ratio Analysis Increments
|-
| SUANA || GAAS || kgkg || xyz || Sulfate Mixing Ratio Analysis
|-
| SUINC || GAAS || kgkg || xyz || Sulfate Mixing Ratio Analysis Increments
|-
| AGCMTROPP || GMICHEM || Pa || xy || tropopause pressure imported into GMICHEM
|-
| BCHYGRO || GMICHEM || 1 || xyz || hygroscopic growth of black carbon
|-
| BCOD || GMICHEM || 1 || xyz || black carbon optical depth (400 nm)
|-
| BCSA || GMICHEM || cm+2 cm-3 || xyz || black carbon surface area
|-
| DUSTOD || GMICHEM || 1 || xyz || dust optical depth (400 nm)
|-
| DUSTSA || GMICHEM || cm+2 cm-3 || xyz || dust surface area
|-
| EMBIOCOMETH || GMICHEM || kg m-2 s-1 || xy || biogenic source of CO from oxidation of methanol
|-
| EMBIOCOMONOT || GMICHEM || kg m-2 s-1 || xy || biogenic source of CO from oxidation of monoterpenes
|-
| EMBIOPROPENE || GMICHEM || kg m-2 s-1 || xy || biogenic source of propene
|-
| EMISOPSFC || GMICHEM || kg m-2 s-1 || xy || surface emission of isoprene
|-
| EMMONOT || GMICHEM || kg m-2 s-1 || xy || surface emission of monoterpenes
|-
| EMNOX || GMICHEM || kg m-2 s-1 || xy || surface emission of odd nitrogen
|-
| EMSHIPHNO3 || GMICHEM || kg m-2 s-1 || xy || surface ship source of nitric acid
|-
| EMSHIPO3 || GMICHEM || kg m-2 s-1 || xy || surface ship source of ozone
|-
| EMSOILNOX || GMICHEM || kg m-2 s-1 || xy || soil source of odd nitrogen
|-
| EM_ACET || GMICHEM || mol mol-1 s-1 || xyz || acetone emissions
|-
| EM_ALD2 || GMICHEM || mol mol-1 s-1 || xyz || acetaldehyde (C2H4O) emissions
|-
| EM_ALK4 || GMICHEM || mol mol-1 s-1 || xyz || C45 alkanes (C4H10) emissions
|-
| EM_C2H6 || GMICHEM || mol mol-1 s-1 || xyz || ethane emissions
|-
| EM_C3H8 || GMICHEM || mol mol-1 s-1 || xyz || propane emissions
|-
| EM_CH2O || GMICHEM || mol mol-1 s-1 || xyz || formaldehyde emissions
|-
| EM_CH4 || GMICHEM || mol mol-1 s-1 || xyz || methane emissions
|-
| EM_CO || GMICHEM || mol mol-1 s-1 || xyz || carbon monoxide emissions
|-
| EM_LGTNO || GMICHEM || mol mol-1 s-1 || xyz || NO emissions from lightning
|-
| EM_MEK || GMICHEM || mol mol-1 s-1 || xyz || methyl ethyl ketone (C4H8O) emissions
|-
| EM_NO || GMICHEM || mol mol-1 s-1 || xyz || nitrous oxide emissions
|-
| EM_PRPE || GMICHEM || mol mol-1 s-1 || xyz || propene (C3H6) emissions
|-
| GMICHEMBCphilic || GMICHEM || kg kg-1 || xyz || prescribed hydrophylic black carbon from GMICHEM
|-
| GMICHEMBCphobic || GMICHEM || kg kg-1 || xyz || prescribed hydrophobic black carbon from GMICHEM
|-
| GMICHEMOCphilic || GMICHEM || kg kg-1 || xyz || prescribed hydrophylic organic carbon from GMICHEM
|-
| GMICHEMOCphobic || GMICHEM || kg kg-1 || xyz || prescribed hydrophobic organic carbon from GMICHEM
|-
| GMICHEMSO4 || GMICHEM || kg kg-1 || xyz || prescribed sulfate from GMICHEM
|-
| GMICHEMdu001 || GMICHEM || kg kg-1 || xyz || prescribed dust bin 1 from GMICHEM
|-
| GMICHEMdu002 || GMICHEM || kg kg-1 || xyz || prescribed dust bin 2 from GMICHEM
|-
| GMICHEMdu003 || GMICHEM || kg kg-1 || xyz || prescribed dust bin 3 from GMICHEM
|-
| GMICHEMdu004 || GMICHEM || kg kg-1 || xyz || prescribed dust bin 4 from GMICHEM
|-
| GMICHEMss001 || GMICHEM || kg kg-1 || xyz || prescribed sea salt bin 1 from GMICHEM
|-
| GMICHEMss003 || GMICHEM || kg kg-1 || xyz || prescribed sea salt bin 3 from GMICHEM
|-
| GMICHEMss004 || GMICHEM || kg kg-1 || xyz || prescribed sea salt bin 4 from GMICHEM
|-
| GMICHEMss005 || GMICHEM || kg kg-1 || xyz || prescribed sea salt bin 5 from GMICHEM
|-
| GMIH2O || GMICHEM || mol mol-1 || xyz || gas phase water from GMICHEM
|-
| GMITO3 || GMICHEM || dobsons || xy || total ozone
|-
| GMITROPP || GMICHEM || Pa || xy || tropopause pressure used in GMICHEM
|-
| GMITTO3 || GMICHEM || dobsons || xy || total tropospheric ozone
|-
| H2O_TEND || GMICHEM || kg kg-1 s-1 || xyz || tendency of water vapor mixing ratio due to chemistry
|-
| HO2PBLFLAG || GMICHEM || 0-1 || xyz || PBL flag for HO2 loss in aerosols
|-
| O3 || GMICHEM || kg kg-1 || xyz || ozone mass mixing ratio
|-
| O3PPMV || GMICHEM || ppmv || xyz || ozone mass mixing ratio in ppm
|-
| OCHYGRO || GMICHEM || 1 || xyz || hygroscopic growth of organic carbon
|-
| OCOD || GMICHEM || 1 || xyz || organic carbon optical depth (400 nm)
|-
| OCSA || GMICHEM || cm+2 cm-3 || xyz || organic carbon surface area
|-
| OX_TEND || GMICHEM || kg kg-1 s-1 || xyz || tendency of odd oxygen mixing ratio due to chemistry
|-
| REFFICE || GMICHEM || cm || xyz || ice aerosol effective radius
|-
| REFFSTS || GMICHEM || cm || xyz || STS aerosol effective radius
|-
| SO4HYGRO || GMICHEM || 1 || xyz || hygroscopic growth of sulfate
|-
| SO4OD || GMICHEM || 1 || xyz || sulfate optical depth (400 nm)
|-
| SO4SA || GMICHEM || cm+2 cm-3 || xyz || sulfate surface area
|-
| SSAHYGRO || GMICHEM || 1 || xyz || hygroscopic growth of accumulated sea salt
|-
| SSAOD || GMICHEM || 1 || xyz || accumulated sea salt optical depth (400 nm)
|-
| SSASA || GMICHEM || cm+2 cm-3 || xyz || accumulated sea salt surface area
|-
| SSCHYGRO || GMICHEM || 1 || xyz || hygroscopic growth of coarse sea salt
|-
| SSCOD || GMICHEM || 1 || xyz || coarse sea salt optical depth (400 nm)
|-
| SSCSA || GMICHEM || cm+2 cm-3 || xyz || coarse sea salt surface area
|-
| SZAPHOT || GMICHEM || deg || xy || solar zenith angle for GMIchem photolysis
|-
| VFALL || GMICHEM || cm s-1 || xyz || effective aerosol fall velocity
|-
| AERO || GMIchem || kg kg-1 || xyz || aerosol mass mixing ratios
|-
| AERO_DP || GMIchem || kg m-2 s-1 || xy || aerosol deposition
|-
| HNO3CONDsad || GMIchem || mixing_ratio || xyz || condensed phase hno3
|-
| HNO3GASsad || GMIchem || mixing_ratio || xyz || gas phase-hno3
|-
| gmiERADIUS || GMIchem || cm || xyz || Aerosol Dust Radii
|-
| gmiQJ || GMIchem || cm3 s-1 || xyz || photolysis rate constants
|-
| gmiQK || GMIchem || 2-3body_varies || xyz || thermal rate constants
|-
| gmiQQJ || GMIchem || cm-3 s-1 || xyz || photolysis reaction rates
|-
| gmiQQK || GMIchem || cm-3 s-1 || xyz || thermal reaction rates
|-
| gmiSAD || GMIchem || cm^2cm^3 || xyz || surface area densities
|-
| gmiTAREA || GMIchem || cm^2cm^3 || xyz || surface area aerosol dust
|-
| jNO2val || GMIchem || s^-1 || xy || photolysis rate constants for NO
|-
| surfEmissForChem || GMIchem || kg m-2 s-1 || xy || surface emission for chemistry
|-
| AERO || GOCART || kg kg-1 || xyz || aerosol mass mixing ratios
|-
| AERO_DP || GOCART || kg m-2 s-1 || xy || aerosol deposition
|-
| TOTANGSTR || GOCART || 1 || xy || Total Aerosol Angstrom parameter [470-870 nm]
|-
| TOTEXTT25 || GOCART || 1 || xy || Total Aerosol Exinction AOT [550 nm] - PM2.5
|-
| TOTEXTTAU || GOCART || 1 || xy || Total Aerosol Extinction AOT [550 nm]
|-
| TOTEXTTFM || GOCART || 1 || xy || Total Aerosol Exinction AOT [550 nm] - PM1.0
|-
| TOTSCAT25 || GOCART || 1 || xy || Total Aerosol Scattering AOT [550 nm] - PM2.5
|-
| TOTSCATAU || GOCART || 1 || xy || Total Aerosol Scattering AOT [550 nm]
|-
| TOTSCATFM || GOCART || 1 || xy || Total Aerosol Scattering AOT [550 nm] - PM1.0
|-
| AICE || Gcm ||  ||  ||
|-
| AK || Gcm ||  ||  ||
|-
| BK || Gcm ||  ||  ||
|-
| CICE_2D_MASK || Gcm ||  ||  ||
|-
| FRACI || Gcm ||  ||  ||
|-
| FRLAKE || Gcm ||  ||  ||
|-
| FRLAND || Gcm ||  ||  ||
|-
| FRLANDICE& || Gcm ||  ||  ||
|-
| FROCEAN || Gcm ||  ||  ||
|-
| HICE || Gcm ||  ||  ||
|-
| LWI || Gcm ||  ||  ||
|-
| MLD || Gcm ||  ||  ||
|-
| MOM_3D_MASK || Gcm ||  ||  ||
|-
| O3PPMV || Gcm ||  ||  ||
|-
| PHIS || Gcm ||  ||  ||
|-
| PS || Gcm ||  ||  ||
|-
| PSI || Gcm ||  ||  ||
|-
| Q || Gcm ||  ||  ||
|-
| QCTOT || Gcm ||  ||  ||
|-
| QITOT || Gcm ||  ||  ||
|-
| QLTOT || Gcm ||  ||  ||
|-
| RHO || Gcm ||  ||  ||
|-
| S || Gcm ||  ||  ||
|-
| SNOMAS || Gcm ||  ||  ||
|-
| SSH || Gcm ||  ||  ||
|-
| T || Gcm ||  ||  ||
|-
| TS || Gcm ||  ||  ||
|-
| TSOIL1 || Gcm ||  ||  ||
|-
| TV || Gcm ||  ||  ||
|-
| TX || Gcm ||  ||  ||
|-
| TY || Gcm ||  ||  ||
|-
| U || Gcm ||  ||  ||
|-
| U || Gcm ||  ||  ||
|-
| U10N || Gcm ||  ||  ||
|-
| V || Gcm ||  ||  ||
|-
| V || Gcm ||  ||  ||
|-
| V10N || Gcm ||  ||  ||
|-
| WET1 || Gcm ||  ||  ||
|-
| Z || Gcm ||  ||  ||
|-
| Z0 || Gcm ||  ||  ||
|-
| BKGERR || Gwd || W m-2 || xy || vertically integrated kinetic energy residual for BKG energy conservation
|-
| CLDSTD || Gwd || m || xy || gravity wave drag standard deviation due to clouds
|-
| DTDT || Gwd || Pa K s-1 || xyz || mass weighted air temperature tendency due to GWD
|-
| DTDT_BKG || Gwd || K s-1 || xyz || air temperature tendency due to background GWD
|-
| DTDT_ORO || Gwd || K s-1 || xyz || air temperature tendency due to orographic GWD
|-
| DTDT_RAY || Gwd || K s-1 || xyz || air temperature tendency due to Rayleigh friction
|-
| DUDT || Gwd || m s-2 || xyz || tendency of eastward wind due to GWD
|-
| DUDT_BKG || Gwd || m s-2 || xyz || tendency of eastward wind due to background GWD
|-
| DUDT_ORO || Gwd || m s-2 || xyz || tendency of eastward wind due to orographic GWD
|-
| DUDT_RAY || Gwd || m s-2 || xyz || tendency of eastward wind due to Rayleigh friction
|-
| DVDT || Gwd || m s-2 || xyz || tendency of northward wind due to GWD
|-
| DVDT_BKG || Gwd || m s-2 || xyz || tendency of northward wind due to background GWD
|-
| DVDT_ORO || Gwd || m s-2 || xyz || tendency of northward wind due to orographic GWD
|-
| DVDT_RAY || Gwd || m s-2 || xyz || tendency of northward wind due to Rayleigh friction
|-
| KEBKG || Gwd || W m-2 || xy || vertically integrated kinetic energy dissipation due to gravity wave background
|-
| KEGWD || Gwd || W m-2 || xy || vertically integrated kinetic energy tendency across gwd
|-
| KEORO || Gwd || W m-2 || xy || vertically integrated kinetic energy dissipation due to orographic gravity waves
|-
| KERAY || Gwd || W m-2 || xy || vertically integrated kinetic energy dissipation due to Rayleigh friction
|-
| KERES || Gwd || W m-2 || xy || vertically integrated kinetic energy residual for total energy conservation
|-
| PEBKG || Gwd || W m-2 || xy || vertically integrated potential energy tendency due to gravity wave background
|-
| PEGWD || Gwd || W m-2 || xy || vertically integrated potential energy tendency across gwd
|-
| PEORO || Gwd || W m-2 || xy || vertically integrated potential energy tendency due to orographic gravity waves
|-
| PERAY || Gwd || W m-2 || xy || vertically integrated potential energy tendency due to Rayleigh friction
|-
| PLE || Gwd || Pa || xyz || air pressure
|-
| PREF || Gwd || Pa || z || reference air pressure
|-
| Q || Gwd || kg kg-1 || xyz || specific humidity
|-
| SGH || Gwd || m || xy || standard deviation of topography
|-
| T || Gwd || K || xyz || air temperature
|-
| TAUBKGX || Gwd || N m-2 || xy || surface eastward background gravity wave stress
|-
| TAUBKGY || Gwd || N m-2 || xy || surface northward background gravity wave stress
|-
| TAUGWX || Gwd || N m-2 || xy || surface eastward gravity wave stress
|-
| TAUGWY || Gwd || N m-2 || xy || surface northward gravity wave stress
|-
| TAUMSTX || Gwd || N m-2 || xy || surface eastward gravity wave stress due to Moist Processes
|-
| TAUMSTY || Gwd || N m-2 || xy || surface northward gravity wave stress due to Moist Processes
|-
| TAUOROX || Gwd || N m-2 || xy || surface eastward orographic gravity wave stress
|-
| TAUOROY || Gwd || N m-2 || xy || surface northward orographic gravity wave stress
|-
| TTMGW || Gwd || K s-1 || xyz || air temperature tendency due to GWD
|-
| U || Gwd || m s-1 || xyz || eastward wind
|-
| UBAR || Gwd || m s-1 || xy || eastward component of mean level wind
|-
| UBASE || Gwd || m s-1 || xy || eastward component of base level wind
|-
| V || Gwd || m s-1 || xyz || northward wind
|-
| VBAR || Gwd || m s-1 || xy || northward component of mean level wind
|-
| VBASE || Gwd || m s-1 || xy || northward component of base level wind
|-
| CLDHILW || Irrad || 1 || xy || total cloud area fraction lw
|-
| CLDLOLW || Irrad || 1 || xy || total cloud area fraction lw
|-
| CLDMDLW || Irrad || 1 || xy || total cloud area fraction lw
|-
| CLDPRS || Irrad || Pa || xy || cloud top pressure
|-
| CLDTMP || Irrad || K || xy || cloud top temperature
|-
| CLDTTLW || Irrad || 1 || xy || total cloud area fraction lw
|-
| DSFDTS || Irrad || W m-2 K-1 || xy || sensitivity of longwave flux emitted from surface to surface temperature
|-
| DSFDTS0 || Irrad || W m-2 K-1 || xy || sensitivity of longwave flux emitted from surface to surface temperature at reference time
|-
| FLA || Irrad || W m-2 || xyz || net downward longwave flux in air assuming clear sky and no aerosol
|-
| FLAD || Irrad || W m-2 || xyz || downward longwave flux in air assuming clear sky and no aerosol
|-
| FLAU || Irrad || W m-2 || xyz || upward longwave flux in air assuming clear sky and no aerosol
|-
| FLC || Irrad || W m-2 || xyz || net downward longwave flux in air assuming clear sky
|-
| FLCD || Irrad || W m-2 || xyz || downward longwave flux in air assuming clear sky
|-
| FLCU || Irrad || W m-2 || xyz || upward longwave flux in air assuming clear sky
|-
| FLNS || Irrad || W m-2 || xy || surface net downward longwave flux
|-
| FLNSA || Irrad || W m-2 || xy || surface net downward longwave flux assuming clear sky and no aerosol
|-
| FLNSC || Irrad || W m-2 || xy || surface net downward longwave flux assuming clear sky
|-
| FLX || Irrad || W m-2 || xyz || net downward longwave flux in air
|-
| FLXD || Irrad || W m-2 || xyz || downward longwave flux in air
|-
| FLXU || Irrad || W m-2 || xyz || upward longwave flux in air
|-
| LAS || Irrad || W m-2 || xy || surface absorbed longwave radiation assuming clear sky and no aerosol
|-
| LCS || Irrad || W m-2 || xy || surface absorbed longwave radiation assuming clear sky
|-
| LWS || Irrad || W m-2 || xy || surface absorbed longwave radiation
|-
| OLA || Irrad || W m-2 || xy || upwelling longwave flux at toa assuming clear sky and no aerosol
|-
| OLC || Irrad || W m-2 || xy || upwelling longwave flux at toa assuming clear sky
|-
| OLR || Irrad || W m-2 || xy || upwelling longwave flux at toa
|-
| SFCEM || Irrad || W m-2 || xy || longwave flux emitted from surface
|-
| SFCEM0 || Irrad || W m-2 || xy || longwave flux emitted from surface at reference time
|-
| TAUIR || Irrad || W m-2 || xyz || longwave cloud optical thickness at 800 cm-1
|-
| TSREFF || Irrad || K || xy || surface temperature
|-
| ALBNF || Lake || 1 || tile || surface albedo for near infrared diffuse
|-
| ALBNR || Lake || 1 || tile || surface albedo for near infrared beam
|-
| ALBVF || Lake || 1 || tile || surface albedo for visible diffuse
|-
| ALBVR || Lake || 1 || tile || surface albedo for visible beam
|-
| CHT || Lake || kg m-2 s-1 || tile || surface heat exchange coefficient
|-
| CMT || Lake || kg m-2 s-1 || tile || surface momentum exchange coefficient
|-
| CNT || Lake || 1 || tile || neutral drag coefficient
|-
| CQT || Lake || kg m-2 s-1 || tile || surface moisture exchange coefficient
|-
| DELQS || Lake || kg kg-1 || tile || change of surface specific humidity
|-
| DELTS || Lake || K || tile || change of surface skin temperature
|-
| EMIS || Lake || 1 || tile || surface emissivity
|-
| EVAPOUT || Lake || kg m-2 s-1 || tile || evaporation
|-
| GUST || Lake || m s-1 || tile || gustiness
|-
| HLATN || Lake || W m-2 || tile || total latent energy flux
|-
| HLWUP || Lake || W m-2 || tile || surface outgoing longwave flux
|-
| LWNDSRF || Lake || W m-2 || tile || surface net downward longwave flux
|-
| MOQ10M || Lake || kg kg-1 || tile || humidity 10m wind from MO sfc
|-
| MOQ2M || Lake || kg kg-1 || tile || humidity 2m wind from MO sfc
|-
| MOT10M || Lake || K || tile || temperature 10m wind from MO sfc
|-
| MOT2M || Lake || K || tile || temperature 2m wind from MO sfc
|-
| MOU10M || Lake || m s-1 || tile || zonal 10m wind from MO sfc
|-
| MOU2M || Lake || m s-1 || tile || zonal 2m wind from MO sfc
|-
| MOU50M || Lake || m s-1 || tile || zonal 50m wind from MO sfc
|-
| MOV10M || Lake || m s-1 || tile || meridional 10m wind from MO sfc
|-
| MOV2M || Lake || m s-1 || tile || meridional 2m wind from MO sfc
|-
| MOV50M || Lake || m s-1 || tile || meridional 50m wind from MO sfc
|-
| OUSTAR3 || Lake || m+3 s-3 || tile || ocean ustar cubed
|-
| PENPAF || Lake || W m-2 || tile || downwelling par diffuse flux at skin base
|-
| PENPAR || Lake || W m-2 || tile || downwelling par direct flux at skin base
|-
| PENUVF || Lake || W m-2 || tile || downwelling uvr diffuse flux at skin base
|-
| PENUVR || Lake || W m-2 || tile || downwelling uvr direct flux at skin base
|-
| PS || Lake || Pa || tile || surface pressure
|-
| QH || Lake || kg kg-1 || tile || turbulence surface specific humidity
|-
| QST || Lake || kg kg-1 || tile || surface specific humidity
|-
| RIT || Lake || 1 || tile || surface bulk richardson number
|-
| RUNOFF || Lake || kg m-2 s-1 || tile || runoff flux
|-
| SHOUT || Lake || W m-2 || tile || upward sensible heat flux
|-
| SUBLIM || Lake || kg m-2 s-1 || tile || sublimation
|-
| SWNDSRF || Lake || W m-2 || tile || surface net downward shortwave flux
|-
| TAUXI || Lake || N m-2 || tile || eastward stress over ice
|-
| TAUXO || Lake || N m-2 || tile || eastward stress on ocean
|-
| TAUXW || Lake || N m-2 || tile || eastward stress over water
|-
| TAUYI || Lake || N m-2 || tile || northward stress over ice
|-
| TAUYO || Lake || N m-2 || tile || northward stress on ocean
|-
| TAUYW || Lake || N m-2 || tile || northward stress over water
|-
| TH || Lake || K || tile || turbulence surface skin temperature
|-
| TST || Lake || K || tile || surface skin temperature
|-
| UH || Lake || m s-1 || tile || turbulence surface zonal velocity
|-
| VENT || Lake || m s-1 || tile || surface ventilation velocity
|-
| VH || Lake || m s-1 || tile || turbulence surface meridional velocity
|-
| Z0 || Lake || m || tile || surface roughness
|-
| Z0H || Lake || m || tile || surface roughness for heat
|-
| LST || Land ||  ||  ||
|-
| ACCUM || Landice || kg m-2 s-1 || tile || net ice accumulation rate
|-
| ALBNF || Landice || 1 || tile || surface albedo for near infrared diffuse
|-
| ALBNR || Landice || 1 || tile || surface albedo for near infrared beam
|-
| ALBVF || Landice || 1 || tile || surface albedo for visible diffuse
|-
| ALBVR || Landice || 1 || tile || surface albedo for visible beam
|-
| ASNOW || Landice || 1 || tile || fractional area of land snowcover
|-
| CHT || Landice || kg m-2 s-1 || tile || surface heat exchange coefficient
|-
| CMT || Landice || kg m-2 s-1 || tile || surface momentum exchange coefficient
|-
| CNT || Landice || 1 || tile || neutral drag coefficient
|-
| CQT || Landice || kg m-2 s-1 || tile || surface moisture exchange coefficient
|-
| DELQS || Landice || kg kg-1 || tile || change of surface specific humidity
|-
| DELTS || Landice || K || tile || change of surface skin temperature
|-
| DNICFLX || Landice || W m-2 || tile || downward heat flux in ice
|-
| DRHOS0 || Landice || kg m-3 || tile || snow layer density change due to densification
|-
| EMIS || Landice || 1 || tile || surface emissivity
|-
| EVAPOUT || Landice || kg m-2 s-1 || tile || evaporation
|-
| EVPICE || Landice || W m-2 || tile || snow ice evaporation energy flux
|-
| GUST || Landice || m s-1 || tile || gustiness
|-
| HLATN || Landice || W m-2 || tile || total latent energy flux
|-
| HLWUP || Landice || W m-2 || tile || surface outgoing longwave flux
|-
| IMELT || Landice || kg m-2 s-1 || tile || icemelt flux
|-
| ITY || Landice || 1 || tile || vegetation type
|-
| LST || Landice || K || tile || land surface skin temperature
|-
| LWC || Landice || 1 || tile || liquid water content in top x m
|-
| LWNDSRF || Landice || W m-2 || tile || surface net downward longwave flux
|-
| MELTWTR || Landice || kg m-2 s-1 || tile || melt water production
|-
| MELTWTRCONT || Landice || kg m-2 || tile || melt water content
|-
| MOQ10M || Landice || kg kg-1 || tile || humidity 10m wind from MO sfc
|-
| MOQ2M || Landice || kg kg-1 || tile || humidity 2m wind from MO sfc
|-
| MOT10M || Landice || K || tile || temperature 10m wind from MO sfc
|-
| MOT2M || Landice || K || tile || temperature 2m wind from MO sfc
|-
| MOU10M || Landice || m s-1 || tile || zonal 10m wind from MO sfc
|-
| MOU2M || Landice || m s-1 || tile || zonal 2m wind from MO sfc
|-
| MOU50M || Landice || m s-1 || tile || zonal 50m wind from MO sfc
|-
| MOV10M || Landice || m s-1 || tile || meridional 10m wind from MO sfc
|-
| MOV2M || Landice || m s-1 || tile || meridional 2m wind from MO sfc
|-
| MOV50M || Landice || m s-1 || tile || meridional 50m wind from MO sfc
|-
| QH || Landice || kg kg-1 || tile || turbulence surface specific humidity
|-
| QST || Landice || kg kg-1 || tile || surface specific humidity
|-
| RAINRFZ || Landice || kg m-2 s-1 || tile || contribution to smb from refreezed rain over bare ice
|-
| RHOSNOW || Landice || kg m-3 || tile || snow layer density
|-
| RIT || Landice || 1 || tile || surface bulk richardson number
|-
| RUNOFF || Landice || kg m-2 s-1 || tile || runoff flux
|-
| SHOUT || Landice || W m-2 || tile || upward sensible heat flux
|-
| SMELT || Landice || kg m-2 s-1 || tile || snowmelt flux
|-
| SNDZ1PERC || Landice || m s-1 || tile || top snow layer thickness change due to percolation
|-
| SNDZPREC || Landice || m s-1 || tile || top snow layer thickness change due to precip
|-
| SNDZSC || Landice || m s-1 || tile || top snow layer thickness change due to sub con
|-
| SNICEALB || Landice || 1 || tile || aggregated snow ice broadband albedo
|-
| SNOWALB || Landice || 1 || tile || snow broadband albedo
|-
| SNOWDP || Landice || m || tile || snow depth
|-
| SNOWMASS || Landice || kg m-2 || tile || snow mass
|-
| SUBLIM || Landice || kg m-2 s-1 || tile || sublimation
|-
| SWNDSRF || Landice || W m-2 || tile || surface net downward shortwave flux
|-
| TH || Landice || K || tile || turbulence surface skin temperature
|-
| TICE0 || Landice || deg C || tile || aggregated ice layer temperature
|-
| TSNOW || Landice || deg C || tile || snow layer temperature
|-
| TST || Landice || K || tile || surface skin temperature
|-
| VENT || Landice || m s-1 || tile || surface ventilation velocity
|-
| WESNBOT || Landice || kg m-2 s-1 || tile || frozen runoff due to fixed max depth
|-
| WESNDENS || Landice || kg m-2 s-1 || tile || snow layer mass change due to densification
|-
| WESNEX || Landice || kg m-2 s-1 || tile || snow layer mass residual due to densification
|-
| WESNPERC || Landice || kg m-2 s-1 || tile || snow layer mass change due to percolation
|-
| WESNPREC || Landice || kg m-2 s-1 || tile || top snow layer mass change due to precip
|-
| WESNREPAR || Landice || kg m-2 s-1 || tile || snow layer mass change due to repartition
|-
| WESNSC || Landice || kg m-2 s-1 || tile || top snow layer mass change due to sub con
|-
| WSNOW || Landice || kg m-2 || tile || snow layer water content
|-
| Z0 || Landice || m || tile || surface roughness
|-
| Z0H || Landice || m || tile || surface roughness for heat
|-
| ZSNOW || Landice || m || tile || snow layer thickness
|-
| AERO || MAMchem || kg kg-1 || xyz || aerosol mass mixing ratios
|-
| AERO_DP || MAMchem || kg m-2 s-1 || xy || aerosol deposition
|-
| AMMSDACC || MAMchem || kg m-2 s-1 || xy || Ammonium Sedimentation Accumulation mode
|-
| AMMSDAIT || MAMchem || kg m-2 s-1 || xy || Ammonium Sedimentation Aitken mode
|-
| AMMSDCDU || MAMchem || kg m-2 s-1 || xy || Ammonium Sedimentation Coarse Dust mode
|-
| AMMSDCSS || MAMchem || kg m-2 s-1 || xy || Ammonium Sedimentation Coarse Seasalt mode
|-
| AMMSDFDU || MAMchem || kg m-2 s-1 || xy || Ammonium Sedimentation Fine Dust mode
|-
| AMMSDFSS || MAMchem || kg m-2 s-1 || xy || Ammonium Sedimentation Fine Seasalt mode
|-
| BCSDACC || MAMchem || kg m-2 s-1 || xy || Black Carbon Sedimentation Accumulation mode
|-
| BCSDPCM || MAMchem || kg m-2 s-1 || xy || Black Carbon Sedimentation Primary Carbon mode
|-
| DUCMASS || MAMchem || kg m-2 || xy || Dust Column Mass Density
|-
| DUCMASS25 || MAMchem || kg m-2 || xy || Dust Column Mass Density - PM 2.5
|-
| DUCONC || MAMchem || kg m-3 || xyz || Dust Mass Concentration
|-
| DUEMCDU || MAMchem || kg m-2 s-1 || xy || Dust Emission Coarse Dust mode
|-
| DUEMFDU || MAMchem || kg m-2 s-1 || xy || Dust Emission Fine Dust mode
|-
| DUFLUXU || MAMchem || kg m-1 s-1 || xy || Dust column u-wind mass flux
|-
| DUFLUXV || MAMchem || kg m-1 s-1 || xy || Dust column v-wind mass flux
|-
| DUMASS || MAMchem || kg kg-1 || xyz || Dust Mass Mixing Ratio
|-
| DUMASS25 || MAMchem || kg kg-1 || xyz || Dust Mass Mixing Ratio - PM 2.5
|-
| DUSDCDU || MAMchem || kg m-2 s-1 || xy || Dust Sedimentation Coarse Seasalt mode
|-
| DUSDFDU || MAMchem || kg m-2 s-1 || xy || Dust Sedimentation Fine Seasalt mode
|-
| DUSMASS || MAMchem || kg m-3 || xy || Dust Surface Mass Concentration
|-
| DUSMASS25 || MAMchem || kg m-3 || xy || Dust Surface Mass Concentration - PM 2.5
|-
| POMSDACC || MAMchem || kg m-2 s-1 || xy || POM Sedimentation Accumulation mode
|-
| POMSDPCM || MAMchem || kg m-2 s-1 || xy || POM Sedimentation Primary Carbon mode
|-
| SOASDACC || MAMchem || kg m-2 s-1 || xy || SOA Sedimentation Accumulation mode
|-
| SOASDAIT || MAMchem || kg m-2 s-1 || xy || SOA Sedimentation Aitken mode
|-
| SSCMASS || MAMchem || kg m-2 || xy || Sea Salt Column Mass Density
|-
| SSCMASS25 || MAMchem || kg m-2 || xy || Sea Salt Column Mass Density - PM 2.5
|-
| SSCONC || MAMchem || kg m-3 || xyz || Sea Salt Mass Concentration
|-
| SSEMACC || MAMchem || kg m-2 s-1 || xy || Sea Salt Emission Accumulation mode
|-
| SSEMAIT || MAMchem || kg m-2 s-1 || xy || Sea Salt Emission Aitken mode
|-
| SSEMCSS || MAMchem || kg m-2 s-1 || xy || Sea Salt Emission Coarse Seasalt mode
|-
| SSEMFSS || MAMchem || kg m-2 s-1 || xy || Sea Salt Emission Fine Seasalt mode
|-
| SSFLUXU || MAMchem || kg m-1 s-1 || xy || Sea Salt column u-wind mass flux
|-
| SSFLUXV || MAMchem || kg m-1 s-1 || xy || Sea Salt column v-wind mass flux
|-
| SSMASS || MAMchem || kg kg-1 || xyz || Sea Salt Mass Mixing Ratio
|-
| SSMASS25 || MAMchem || kg kg-1 || xyz || Sea Salt Mass Mixing Ratio - PM 2.5
|-
| SSSDACC || MAMchem || kg m-2 s-1 || xy || Sea Salt Sedimentation Accumulation mode
|-
| SSSDAIT || MAMchem || kg m-2 s-1 || xy || Sea Salt Sedimentation Aitken mode
|-
| SSSDCSS || MAMchem || kg m-2 s-1 || xy || Sea Salt Sedimentation Coarse Seasalt mode
|-
| SSSDFSS || MAMchem || kg m-2 s-1 || xy || Sea Salt Sedimentation Fine Seasalt mode
|-
| SSSMASS || MAMchem || kg m-3 || xy || Sea Salt Surface Mass Concentration
|-
| SSSMASS25 || MAMchem || kg m-3 || xy || Sea Salt Surface Mass Concentration - PM 2.5
|-
| SUSDACC || MAMchem || kg m-2 s-1 || xy || Sulfate Sedimentation Accumulation mode
|-
| SUSDAIT || MAMchem || kg m-2 s-1 || xy || Sulfate Sedimentation Aitken mode
|-
| SUSDCDU || MAMchem || kg m-2 s-1 || xy || Sulfate Sedimentation Coarse Dust mode
|-
| SUSDCSS || MAMchem || kg m-2 s-1 || xy || Sulfate Sedimentation Coarse Seasalt mode
|-
| SUSDFDU || MAMchem || kg m-2 s-1 || xy || Sulfate Sedimentation Fine Dust mode
|-
| SUSDFSS || MAMchem || kg m-2 s-1 || xy || Sulfate Sedimentation Fine Seasalt mode
|-
| WTR_A_ACC || MAMchem || kg kg-1 || xyz || Absorbed Water Mass Mixing Ratio Accumulation mode
|-
| WTR_A_AIT || MAMchem || kg kg-1 || xyz || Absorbed Water Mass Mixing Ratio Aitken mode
|-
| WTR_A_CDU || MAMchem || kg kg-1 || xyz || Absorbed Water Mass Mixing Ratio Coarse Dust mode
|-
| WTR_A_CSS || MAMchem || kg kg-1 || xyz || Absorbed Water Mass Mixing Ratio Coarse Seasalt mode
|-
| WTR_A_FDU || MAMchem || kg kg-1 || xyz || Absorbed Water Mass Mixing Ratio Fine Dust mode
|-
| WTR_A_FSS || MAMchem || kg kg-1 || xyz || Absorbed Water Mass Mixing Ratio Fine Seasalt mode
|-
| WTR_A_PCM || MAMchem || kg kg-1 || xyz || Absorbed Water Mass Mixing Ratio Primary Carbon mode
|-
| A1X1 || Moist || km-2 s-1 || xy || LFR Term number 1
|-
| A2X2 || Moist || km-2 s-1 || xy || LFR Term number 2
|-
| A3X3 || Moist || km-2 s-1 || xy || LFR Term number 3
|-
| A4X4 || Moist || km-2 s-1 || xy || LFR Term number 4
|-
| A5X5 || Moist || km-2 s-1 || xy || LFR Term number 5
|-
| ACRIL_AN || Moist || kg kg-1 s-1 || xyz || ice liq accretion of anvil precipitation
|-
| ACRIL_CN || Moist || kg kg-1 s-1 || xyz || ice liq accretion of convective precipitation
|-
| ACRIL_LS || Moist || kg kg-1 s-1 || xyz || ice liq accretion of nonanvil large scale precipitation
|-
| ACRLL_AN || Moist || kg kg-1 s-1 || xyz || liq liq accretion of anvil precipitation
|-
| ACRLL_CN || Moist || kg kg-1 s-1 || xyz || liq liq accretion of convective precipitation
|-
| ACRLL_LS || Moist || kg kg-1 s-1 || xyz || liq liq accretion of nonanvil large scale precipitation
|-
| ACR_TOT || Moist || kg kg-1 s-1 || xyz || total accretion of  precipitation
|-
| ALPH1 || Moist || 1 || xyz || pdf spread for condensation over qsat term1
|-
| ALPH2 || Moist || 1 || xyz || pdf spread for condensation over qsat term2
|-
| ALPHT || Moist || 1 || xyz || pdf spread for condensation over qsat total
|-
| AN_ARF || Moist || 1 || xy || areal fraction of anvil showers
|-
| AN_PRCP || Moist || kg m-2 s-1 || xy || anvil precipitation
|-
| AUT || Moist || kg kg-1 s-1 || xyz || autoconv sink of cloud liq
|-
| AUTZ || Moist || kg m-2 s-1 || xy || autoconversion loss of cloud water
|-
| BYNCY || Moist || m s-2 || xyz || buoyancy of surface parcel
|-
| CAPE || Moist || J m-2 || xy || cape for surface parcel
|-
| CCWP || Moist || kg m-2 || xy || grid mean conv cond water path diagnostic
|-
| CFPDF || Moist || 1 || xyz || cloud fraction after PDF
|-
| CFPDFX || Moist || 1 || xyz || cloud fraction internal in PDF scheme
|-
| CLCN || Moist || 1 || xyz || convective cloud area fraction
|-
| CLCNX0 || Moist || 1 || xyz || convective cloud area fraction
|-
| CLDNCCN || Moist || m-3 || xyz || number concentration of cloud particles
|-
| CLLS || Moist || 1 || xyz || large scale cloud area fraction
|-
| CLLSX0 || Moist || 1 || xyz || large scale cloud area fraction
|-
| CNVIZ || Moist || kg m-2 s-1 || xy || convective source of cloud ice
|-
| CNVLZ || Moist || kg m-2 s-1 || xy || convective source of cloud water
|-
| CNVRNZ || Moist || kg m-2 s-1 || xy || convective production of rain water
|-
| CNV_BASEP || Moist || Pa || xy || pressure at convective cloud base
|-
| CNV_CVW || Moist || hPa s-1 || xyz || updraft vertical velocity
|-
| CNV_DQLDT || Moist || kg m-2 s-1 || xyz || convective condensate source
|-
| CNV_FREQ || Moist || fraction || xy || convective frequency
|-
| CNV_MF0 || Moist || kg m-2 s-1 || xyz || cloud base mass flux
|-
| CNV_MFC || Moist || kg m-2 s-1 || xyz || cumulative mass flux
|-
| CNV_MFD || Moist || kg m-2 s-1 || xyz || detraining mass flux
|-
| CNV_PRC3 || Moist || kg m-2 s-1 || xyz || convective precipitation from RAS
|-
| CNV_QC || Moist || kg kg-1 || xyz || grid mean convective condensate
|-
| CNV_TOPP || Moist || Pa || xy || pressure at convective cloud top
|-
| CNV_UPDF || Moist || 1 || xyz || updraft areal fraction
|-
| CN_ARF || Moist || 1 || xy || areal fraction of convective showers
|-
| CN_PRCP || Moist || kg m-2 s-1 || xy || convective precipitation
|-
| COLLIZ || Moist || kg m-2 s-1 || xy || accretion loss of cloud water to snow
|-
| COLLLZ || Moist || kg m-2 s-1 || xy || accretion loss of cloud water to rain
|-
| CWP || Moist || kg m-2 || xy || condensed water path
|-
| DBCDT || Moist || kg m-2 s-1 || xy || black carbon tendency due to conv scav
|-
| DCNVI || Moist || kg kg-1 s-1 || xyz || convective source of cloud ice
|-
| DCNVL || Moist || kg kg-1 s-1 || xyz || convective source of cloud liq
|-
| DCPTE || Moist || J m-2 || xy || Total VI DcpT
|-
| DDF_BYNC || Moist || m s-2 || xyz || Buoyancy of DDF
|-
| DDF_DQDT || Moist || kg kg-1 s-1 || xyz || Total Downdraft moistening
|-
| DDF_DTDT || Moist || K s-1 || xyz || Total Downdraft heating
|-
| DDF_MFC || Moist || kg m-2 s-1 || xyz || Downdraft mass flux
|-
| DDF_MUPH || Moist || kg kg-1 s-1 || xyz || Downdraft moistening from evap subl
|-
| DDF_QVC || Moist || kg kg-1 || xyz || Spec hum excess in DDF
|-
| DDF_RH1 || Moist || 1 || xyz || Downdraft in cloud RH before
|-
| DDF_RH2 || Moist || 1 || xyz || Downdraft in cloud RH after
|-
| DDF_TC || Moist || K || xyz || Temperature excess in DDF
|-
| DDF_ZSCALE || Moist || m || xy || vertical scale for downdraft
|-
| DDUDT || Moist || kg m-2 s-1 || xy || dust tendency due to conv scav
|-
| DDUDTcarma || Moist || kg m-2 s-1 || xy || carma dust tendency due to conv scav
|-
| DIFIX || Moist || kg kg-1 s-1 || xyz || fix source sink of cloud ice
|-
| DIPDF || Moist || kg kg-1 s-1 || xyz || pdf source sink of cloud ice
|-
| DLFIX || Moist || kg kg-1 s-1 || xyz || fix source sink of cloud liq
|-
| DLPDF || Moist || kg kg-1 s-1 || xyz || pdf source sink of cloud liq
|-
| DOCDT || Moist || kg m-2 s-1 || xy || organic carbon tendency due to conv scav
|-
| DQCDTCN || Moist || kg kg-1 s-1 || xyz || condensate tendency due to convection
|-
| DQDT || Moist || kg kg-1 s-1 || xyz || specific humidity tendency due to moist
|-
| DQDTCN || Moist || kg kg-1 s-1 || xyz || specific humidity tendency due to convection
|-
| DQIDT || Moist || kg kg-1 s-1 || xyz || total ice water tendency due to moist
|-
| DQLDT || Moist || kg kg-1 s-1 || xyz || total liq water tendency due to moist
|-
| DQRC || Moist || kg kg-1 s-1 || xyz || convective rainwater source
|-
| DQRL || Moist || kg kg-1 s-1 || xyz || large scale rainwater source
|-
| DQSI || Moist || kg kg-1 K-1 || xyz || deriv sat specific humidity wrt t before ras
|-
| DSSDT || Moist || kg m-2 s-1 || xy || sea salt tendency due to conv scav
|-
| DSSDTcarma || Moist || kg m-2 s-1 || xy || carma seasalt tendency due to conv scav
|-
| DSUDT || Moist || kg m-2 s-1 || xy || sulfate tendency due to conv scav
|-
| DTDTFRIC || Moist || Pa K s-1 || xyz || pressure weighted temperature tendency due to moist friction
|-
| DTHDT || Moist || Pa K s-1 || xyz || pressure weighted potential temperature tendency due to moist
|-
| DTHDTCN || Moist || K s-1 || xyz || potential temperature tendency due to convection
|-
| DUDT || Moist || m s-2 || xyz || zonal wind tendency due to moist
|-
| DVDT || Moist || m s-2 || xyz || meridional wind tendency due to moist
|-
| ENTLAM || Moist || kg m-2 s-1 || xyz || entrainment parameter
|-
| ER_PRCP || Moist || kg m-2 s-1 || xy || spurious rain from RH cleanup
|-
| EVAPC || Moist || kg kg-1 s-1 || xyz || evaporation of cloud liq
|-
| EVPCZ || Moist || kg m-2 s-1 || xy || evaporation loss of cloud water
|-
| EVPPZ || Moist || kg m-2 s-1 || xy || evaporation loss of precip water
|-
| FCLD || Moist || 1 || xyz || cloud fraction for radiation
|-
| FILLNQV || Moist || kg m-2 s-1 || xy || filling of negative Q
|-
| FRLANDX0 || Moist || 1 || xy || areal land fraction
|-
| FRZCZ || Moist || kg m-2 s-1 || xy || net freezing of cloud condensate
|-
| FRZPZ || Moist || kg m-2 s-1 || xy || net freezing of precip condensate
|-
| FRZ_PP || Moist || kg kg-1 s-1 || xyz || freezing of precip condensate
|-
| FRZ_TT || Moist || kg kg-1 s-1 || xyz || freezing of cloud condensate
|-
| INHB || Moist || 1 || xy || inhibition for surface parcel
|-
| IWP || Moist || kg m-2 || xy || ice water path
|-
| KCBLI || Moist || 1 || xy || cloud base layer before ras
|-
| KEDISS || Moist || W m-2 || xyz || kinetic energy diss in RAS
|-
| KEMST || Moist || W m-2 || xy || vertically integrated kinetic energy tendency across moist
|-
| KEMST2 || Moist || W m-2 || xy || vertically integrated KE dissipation in RAS
|-
| KHX0 || Moist || m+2 s-1 || xyz || scalar diffusivity
|-
| LFR || Moist || km-2 s-1 || xy || lightning flash rate
|-
| LS_ARF || Moist || 1 || xy || areal fraction of nonanvil large scale showers
|-
| LS_PRCP || Moist || kg m-2 s-1 || xy || nonanvil large scale precipitation
|-
| LWP || Moist || kg m-2 || xy || liquid water path
|-
| MTRI || Moist || X s-1 || xyz || tracer tendencies due to moist
|-
| MXDIAM || Moist || m || xy || diameter of largest RAS plume
|-
| PCU || Moist || kg m-2 s-1 || xy || convective rainfall
|-
| PDFIZ || Moist || kg m-2 s-1 || xy || statistical source of cloud ice
|-
| PDFLZ || Moist || kg m-2 s-1 || xy || statistical source of cloud water
|-
| PFI_AN || Moist || kg m-2 s-1 || xyz || 3D flux of ice anvil precipitation
|-
| PFI_CN || Moist || kg m-2 s-1 || xyz || 3D flux of ice convective precipitation
|-
| PFI_LS || Moist || kg m-2 s-1 || xyz || 3D flux of ice nonanvil large scale precipitation
|-
| PFI_LSAN || Moist || kg m-2 s-1 || xyz || 3D flux of ice nonconvective precipitation
|-
| PFL_AN || Moist || kg m-2 s-1 || xyz || 3D flux of liquid anvil precipitation
|-
| PFL_CN || Moist || kg m-2 s-1 || xyz || 3D flux of liquid convective precipitation
|-
| PFL_LS || Moist || kg m-2 s-1 || xyz || 3D flux of liquid nonanvil large scale precipitation
|-
| PFL_LSAN || Moist || kg m-2 s-1 || xyz || 3D flux of liquid nonconvective precipitation
|-
| PGENTOT || Moist || kg m-2 s-1 || xy || Total column production of precipitation
|-
| PLEI || Moist || Pa || xyz || air pressure before ras
|-
| PLS || Moist || kg m-2 s-1 || xy || large scale rainfall
|-
| PREVTOT || Moist || kg m-2 s-1 || xy || Total column re-evapsubl of precipitation
|-
| QCTOT || Moist || kg kg-1 || xyz || mass fraction of total cloud water
|-
| QHOI || Moist || kg kg-1 || xyz || specific humidity before ras
|-
| QI || Moist || kg kg-1 || xyz || cloud ice for radiation
|-
| QICN || Moist || 1 || xyz || mass fraction of convective cloud ice water
|-
| QICNX0 || Moist || kg kg-1 || xyz || mass fraction of convective cloud ice water
|-
| QILSX0 || Moist || kg kg-1 || xyz || mass fraction of large scale cloud ice water
|-
| QITOT || Moist || kg kg-1 || xyz || mass fraction of cloud ice water
|-
| QL || Moist || kg kg-1 || xyz || cloud liquid for radiation
|-
| QLCN || Moist || 1 || xyz || mass fraction of convective cloud liquid water
|-
| QLCNX0 || Moist || kg kg-1 || xyz || mass fraction of convective cloud liquid water
|-
| QLLSX0 || Moist || kg kg-1 || xyz || mass fraction of large scale cloud liquid water
|-
| QLTOT || Moist || kg kg-1 || xyz || mass fraction of cloud liquid water
|-
| QR || Moist || kg kg-1 || xyz || Falling rain for radiation
|-
| QRTOT || Moist || kg kg-1 || xyz || mass fraction of falling rain
|-
| QS || Moist || kg kg-1 || xyz || Falling snow for radiation
|-
| QSATI || Moist || kg kg-1 || xyz || saturation spec hum over ice
|-
| QSATL || Moist || kg kg-1 || xyz || saturation spec hum over liquid
|-
| QSSI || Moist || kg kg-1 || xyz || saturation specific humidity before ras
|-
| QSTOT || Moist || kg kg-1 || xyz || mass fraction of falling snow
|-
| QV || Moist || kg kg-1 || xyz || water vapor for radiation
|-
| QVRAS || Moist || kg kg-1 || xyz || water vapor after ras
|-
| QX0 || Moist || kg kg-1 || xyz || specific humidity
|-
| RASPBLQ || Moist || (m+3 s-1)+12 || xy || sqrt of integral KH dz
|-
| RASTIME || Moist || s || xy || timescale for deep RAS plumes
|-
| RCCODE || Moist || codes || xyz || Convection return codes
|-
| REVSU_CN || Moist || kg kg-1 s-1 || xyz || evap subl of convective precipitation
|-
| REVSU_LSAN || Moist || kg kg-1 s-1 || xyz || evap subl of non convective precipitation
|-
| REV_AN || Moist || kg kg-1 s-1 || xyz || evaporation of anvil precipitation
|-
| REV_CN || Moist || kg kg-1 s-1 || xyz || evaporation of convective precipitation
|-
| REV_LS || Moist || kg kg-1 s-1 || xyz || evaporation of nonanvil large scale precipitation
|-
| RH1 || Moist || 1 || xyz || relative humidity before moist
|-
| RH2 || Moist || 1 || xyz || relative humidity after moist
|-
| RHCLR || Moist || 1 || xyz || RH clear sky
|-
| RHX || Moist || 1 || xyz || relative humidity after PDF
|-
| RI || Moist || m || xyz || ice phase cloud particle effective radius
|-
| RL || Moist || m || xyz || liquid cloud particle effective radius
|-
| RR || Moist || m || xyz || falling rain particle effective radius
|-
| RS || Moist || m || xyz || falling ice particle effective radius
|-
| RSU_AN || Moist || kg kg-1 s-1 || xyz || sublimation of anvil precipitation
|-
| RSU_CN || Moist || kg kg-1 s-1 || xyz || sublimation of convective precipitation
|-
| RSU_LS || Moist || kg kg-1 s-1 || xyz || sublimation of nonanvil large scale precipitation
|-
| SDM || Moist || kg kg-1 s-1 || xyz || sedimentation sink of cloud ice
|-
| SDMZ || Moist || kg m-2 s-1 || xy || sedimentation loss of cloud ice
|-
| SNO || Moist || kg m-2 s-1 || xy || snowfall
|-
| SUBCZ || Moist || kg m-2 s-1 || xy || sumblimation loss of cloud ice
|-
| SUBLC || Moist || kg kg-1 s-1 || xyz || sublimation of cloud ice
|-
| SUBPZ || Moist || kg m-2 s-1 || xy || sumblimation loss of precip ice
|-
| THOI || Moist || K || xyz || potential temperature before ras
|-
| THRAS || Moist || K || xyz || potential temperature after ras
|-
| THX0 || Moist || K || xyz || potential temperature
|-
| TPERTI || Moist || K || xy || temperature perturbation before ras
|-
| TPREC || Moist || kg m-2 s-1 || xy || total precipitation
|-
| TPW || Moist || kg m-2 || xy || total precipitable water
|-
| TRIEDLV || Moist || 0 or 1 || xyz || Tested for convection at this level
|-
| TSX0 || Moist || K || xy || surface temperature
|-
| TVE0 || Moist || J m-2 || xy || Total VI MSE Before
|-
| TVE1 || Moist || J m-2 || xy || Total VI MSE After
|-
| TVEX || Moist || J m-2 || xy || Total VI MSE Somewhere
|-
| TVQ0 || Moist || kg m-2 || xy || Total Water Substance Before
|-
| TVQ1 || Moist || kg m-2 || xy || Total Water Substance After
|-
| URAS || Moist || m s-1 || xyz || eastward wind after ras
|-
| UX0 || Moist || m s-1 || xyz || eastward wind
|-
| VFALLICE_AN || Moist || m s-1 || xyz || autoconversion fall velocity of anvil snow
|-
| VFALLICE_LS || Moist || m s-1 || xyz || autoconversion fall velocity of largescale snow
|-
| VFALLRN_AN || Moist || m s-1 || xyz || reevaporation fall velocity of anvil rain
|-
| VFALLRN_CN || Moist || m s-1 || xyz || reevaporation fall velocity of convective rain
|-
| VFALLRN_LS || Moist || m s-1 || xyz || reevaporation fall velocity of largescale rain
|-
| VFALLSN_AN || Moist || m s-1 || xyz || reevaporation fall velocity of anvil snow
|-
| VFALLSN_CN || Moist || m s-1 || xyz || reevaporation fall velocity of convective snow
|-
| VFALLSN_LS || Moist || m s-1 || xyz || reevaporation fall velocity of largescale snow
|-
| VFALLWAT_AN || Moist || m s-1 || xyz || autoconversion fall velocity of anvil rain
|-
| VFALLWAT_LS || Moist || m s-1 || xyz || autoconversion fall velocity of largescale rain
|-
| VRAS || Moist || m s-1 || xyz || northward wind after ras
|-
| VX0 || Moist || m s-1 || xyz || northward wind
|-
| ZCBL || Moist || m || xy || height of cloud base layer
|-
| ZLCL || Moist || m || xy || lifting condensation level
|-
| ZLFC || Moist || m || xy || level of free convection
|-
| ZPBLCN || Moist || m || xy || boundary layer depth
|-
| TURB || Oceanbiogeochem || m-1 || xy || water turbidity
|-
| AICE || Ogcm || N m-2 || tile || northward stress at base of ice
|-
| CICE_2D_MASK || Ogcm || N m-2 || tile || northward stress at base of ice
|-
| FRACICE || Ogcm || 1 || tile || fractional cover of seaice
|-
| HICE || Ogcm || N m-2 || tile || northward stress at base of ice
|-
| KPAR || Ogcm || m-1 || tile || PAR extinction coefficient
|-
| MLD || Ogcm || N m-2 || tile || northward stress at base of ice
|-
| MOM_3D_MASK || Ogcm || N m-2 || tile || northward stress at base of ice
|-
| PSI || Ogcm || N m-2 || tile || northward stress at base of ice
|-
| RHO || Ogcm || N m-2 || tile || northward stress at base of ice
|-
| S || Ogcm || N m-2 || tile || northward stress at base of ice
|-
| SSH || Ogcm || N m-2 || tile || northward stress at base of ice
|-
| T || Ogcm || N m-2 || tile || northward stress at base of ice
|-
| TAUXIBOT || Ogcm || N m-2 || tile || eastward stress at base of ice
|-
| TAUYIBOT || Ogcm || N m-2 || tile || northward stress at base of ice
|-
| TILELATS || Ogcm || degrees || tile || latitude
|-
| TILELONS || Ogcm || degrees || tile || longitude
|-
| TS_FOUND || Ogcm || K || tile || foundation temperature for interface layer
|-
| TX || Ogcm || N m-2 || tile || northward stress at base of ice
|-
| TY || Ogcm || N m-2 || tile || northward stress at base of ice
|-
| U || Ogcm || N m-2 || tile || northward stress at base of ice
|-
| UI || Ogcm || m s-1 || tile || zonal velocity of surface seaice
|-
| UW || Ogcm || m s-1 || tile || zonal velocity of surface water
|-
| V || Ogcm || N m-2 || tile || northward stress at base of ice
|-
| VI || Ogcm || m s-1 || tile || meridional velocity of surface seaice
|-
| VW || Ogcm || m s-1 || tile || meridional velocity of surface water
|-
| Z || Ogcm || N m-2 || tile || northward stress at base of ice
|-
| FROCEAN || Orad || 1 || xy || ocean fraction of grid cell
|-
| H || Orad || dyn-m || xyz || Layer mass
|-
| KPAR || Orad || m-1 || xy || PAR extinction coefficient
|-
| PENPAF || Orad || W m-2 || xy || net downward penetrating diffuse PAR flux
|-
| PENPAR || Orad || W m-2 || xy || net downward penetrating direct PAR flux
|-
| PENUVF || Orad || W m-2 || xy || net downward penetrating diffuse UV flux
|-
| PENUVR || Orad || W m-2 || xy || net downward penetrating direct UV flux
|-
| SWHEAT || Orad || W m-2 || xyz || solar heating rate
|-
| AERO_DP || PChem || kg m-2 s-1 || xy || aerosol deposition
|-
| BC || PChem || kg kg-1 || xyz || black carbon aerosol mixing ratio
|-
| CFC11_LOSS || PChem || mol mol-1 s-1 || xyz || tendency of CFC11 volume mixing ratio due to loss
|-
| CFC11_PROD || PChem || mol mol-1 s-1 || xyz || tendency of CFC11 volume mixing ratio due to production
|-
| CFC12_LOSS || PChem || mol mol-1 s-1 || xyz || tendency of CFC12 volume mixing ratio due to loss
|-
| CFC12_PROD || PChem || mol mol-1 s-1 || xyz || tendency of CFC12 volume mixing ratio due to production
|-
| CH4_LOSS || PChem || mol mol-1 s-1 || xyz || tendency of methane volume mixing ratio due to loss
|-
| CH4_PROD || PChem || mol mol-1 s-1 || xyz || tendency of methane volume mixing ratio due to production
|-
| DUST || PChem || kg kg-1 || xyz || mineral dust mixing ratio
|-
| H2O_LOSS || PChem || s-1 || xyz || tendency of specific humidity due to loss
|-
| H2O_PROD || PChem || s-1 || xyz || tendency of specific humidity due to production
|-
| H2O_TEND || PChem || kg kg-1 s-1 || xyz || tendency of water vapor mixing ratio due to chemistry
|-
| HCFC22_LOSS || PChem || mol mol-1 s-1 || xyz || tendency of HCFC22 volume mixing ratio due to loss
|-
| HCFC22_PROD || PChem || mol mol-1 s-1 || xyz || tendency of HCFC22 volume mixing ratio due to production
|-
| N2O_LOSS || PChem || mol mol-1 s-1 || xyz || tendency of nitrous oxide volume mixing ratio due to loss
|-
| N2O_PROD || PChem || mol mol-1 s-1 || xyz || tendency of nitrous oxide volume mixing ratio due to production
|-
| O3 || PChem || kg kg-1 || xyz || ozone mass mixing ratio
|-
| O3PPMV || PChem || ppmv || xyz || ozone volume mixing ratio
|-
| OC || PChem || kg kg-1 || xyz || organic carbon aerosol mixing ratio
|-
| OX_LOSS || PChem || mol mol-1 s-1 || xyz || tendency of odd oxygen volume mixing ratio due to loss
|-
| OX_PROD || PChem || mol mol-1 s-1 || xyz || tendency of odd oxygen volume mixing ratio due to production
|-
| OX_TEND || PChem || mol mol-1 s-1 || xyz || tendency of odd oxygen mixing ratio due to chemistry
|-
| SALT || PChem || kg kg-1 || xyz || sea salt mixing ratio
|-
| SO4 || PChem || kg kg-1 || xyz || sulfate aerosol mixing ratio
|-
| TO3 || PChem || Dobsons || xy || total column ozone
|-
| TTO3 || PChem || Dobsons || xy || tropospheric column ozone
|-
| DOXDTCHMINT || Physics || kg m-2 s-1 || xy || vertically integrated odd oxygen tendency due to chemistry
|-
| DOXDTPHYINT || Physics || kg m-2 s-1 || xy || vertically integrated odd oxygen tendency due to physics
|-
| DPEDT || Physics || Pa s-1 || xyz || tendency of pressure at layer edges due to physics
|-
| DQIDTMSTINT || Physics || kg m-2 s-1 || xy || vertically integrated ice tendency due to moist processes
|-
| DQIDTPHYINT || Physics || kg m-2 s-1 || xy || vertically integrated ice tendency due to physics
|-
| DQLDTMSTINT || Physics || kg m-2 s-1 || xy || vertically integrated liquid water tendency due to moist processes
|-
| DQLDTPHYINT || Physics || kg m-2 s-1 || xy || vertically integrated liquid water tendency due to physics
|-
| DQVDTCHMINT || Physics || kg m-2 s-1 || xy || vertically integrated water vapor tendency due to chemistry
|-
| DQVDTMSTINT || Physics || kg m-2 s-1 || xy || vertically integrated water vapor tendency due to moist processes
|-
| DQVDTPHYINT || Physics || kg m-2 s-1 || xy || vertically integrated water vapor tendency due to physics
|-
| DQVDTTRBINT || Physics || kg m-2 s-1 || xy || vertically integrated water vapor tendency due to turbulence
|-
| DTDT || Physics || Pa K s-1 || xyz || pressure weighted tendency of air temperature due to physics
|-
| DTDTRAD || Physics || K s-1 || xyz || tendency of air temperature due to radiation
|-
| DTDTTOT || Physics || K s-1 || xyz || tendency of air temperature due to physics
|-
| DUDT || Physics || m s-2 || xyz || tendency of eastward wind due to physics
|-
| DVDT || Physics || m s-2 || xyz || tendency of northward wind due to physics
|-
| FRACI || Physics || kg m-2 s-1 || xy || vertically integrated odd oxygen tendency due to physics
|-
| FRLAKE || Physics || kg m-2 s-1 || xy || vertically integrated odd oxygen tendency due to physics
|-
| FRLAND || Physics || kg m-2 s-1 || xy || vertically integrated odd oxygen tendency due to physics
|-
| FRLANDICE || Physics || kg m-2 s-1 || xy || vertically integrated odd oxygen tendency due to physics
|-
| FROCEAN || Physics || kg m-2 s-1 || xy || vertically integrated odd oxygen tendency due to physics
|-
| FTB || Physics || W m-2 || xyz || upward net turbulence heat flux
|-
| FTU || Physics || m+2 s-2 || xyz || upward net turbulence eastward momentum flux
|-
| FTV || Physics || m+2 s-2 || xyz || upward net turbulence northward momentum flux
|-
| KEPHY || Physics || W m-2 || xy || vertically integrated kinetic energy tendency across physics
|-
| LWI || Physics || kg m-2 s-1 || xy || vertically integrated odd oxygen tendency due to physics
|-
| O3PPMV || Physics || kg m-2 s-1 || xy || vertically integrated odd oxygen tendency due to physics
|-
| OX || Physics || kg m-2 s-1 || xy || vertically integrated odd oxygen tendency due to physics
|-
| OXIM || Physics || kg kg-1 s-1 || xyz || tendency of odd oxygen due to moist processes
|-
| OXIT || Physics || kg kg-1 s-1 || xyz || tendency of odd oxygen due to turbulence
|-
| PECUF || Physics || W m-2 || xy || vertically integrated potential energy tendency due to cumulus friction
|-
| PEFRI || Physics || W m-2 || xy || vertically integrated potential energy tendency due to friction
|-
| PEGWD || Physics || W m-2 || xy || vertically integrated potential energy tendency across gwd
|-
| PEMST || Physics || W m-2 || xy || vertically integrated potential energy tendency across moist
|-
| PEPHY || Physics || W m-2 || xy || vertically integrated potential energy tendency across physics
|-
| PERAD || Physics || W m-2 || xy || vertically integrated potential energy tendency across radiation
|-
| PETRB || Physics || W m-2 || xy || vertically integrated potential energy tendency across turbulence
|-
| Q || Physics || kg m-2 s-1 || xy || vertically integrated odd oxygen tendency due to physics
|-
| QCTOT || Physics || kg m-2 s-1 || xy || vertically integrated odd oxygen tendency due to physics
|-
| QILSIT || Physics || kg kg-1 s-1 || xyz || tendency of frozen condensate due to turbulence
|-
| QLLSIT || Physics || kg kg-1 s-1 || xyz || tendency of liquid condensate due to turbulence
|-
| QVIT || Physics || kg kg-1 s-1 || xyz || tendency of specific humidity due to turbulence
|-
| SIT || Physics || Pa m+2 s-3 || xyz || pressure weighted tendency of dry static energy due to turbulence
|-
| SNOMAS || Physics || kg m-2 s-1 || xy || vertically integrated odd oxygen tendency due to physics
|-
| THIM || Physics || Pa K s-1 || xyz || pressure weighted tendency of potential temperature due to moist processes
|-
| TIF || Physics || K s-1 || xyz || tendency of air temperature due to friction
|-
| TIM || Physics || K s-1 || xyz || tendency of air temperature due to moist processes
|-
| TIMFRIC || Physics || K s-1 || xyz || tendency of air temperature due to moist processes friction
|-
| TIT || Physics || K s-1 || xyz || tendency of air temperature due to turbulence
|-
| TRADV || Physics || X || xyz || advected quantities
|-
| TRANA || Physics || X || xyz || analyzed quantities
|-
| TS || Physics || kg m-2 s-1 || xy || vertically integrated odd oxygen tendency due to physics
|-
| TSOIL1 || Physics || kg m-2 s-1 || xy || vertically integrated odd oxygen tendency due to physics
|-
| U10M || Physics || kg m-2 s-1 || xy || vertically integrated odd oxygen tendency due to physics
|-
| U10N || Physics || kg m-2 s-1 || xy || vertically integrated odd oxygen tendency due to physics
|-
| UIT || Physics || m s-2 || xyz || tendency of eastward wind due to turbulence
|-
| V10M || Physics || kg m-2 s-1 || xy || vertically integrated odd oxygen tendency due to physics
|-
| V10N || Physics || kg m-2 s-1 || xy || vertically integrated odd oxygen tendency due to physics
|-
| VIT || Physics || m s-2 || xyz || tendency of northward wind due to turbulence
|-
| WET1 || Physics || kg m-2 s-1 || xy || vertically integrated odd oxygen tendency due to physics
|-
| Z0 || Physics || kg m-2 s-1 || xy || vertically integrated odd oxygen tendency due to physics
|-
| ALBEDO || Radiation || W m-2 K-1 || xy || linearization of surface upwelling longwave flux
|-
| ALW || Radiation || W m-2 || xy || linearization of surface upwelling longwave flux
|-
| BLW || Radiation || W m-2 K-1 || xy || linearization of surface upwelling longwave flux
|-
| CLDTT || Radiation || W m-2 K-1 || xy || linearization of surface upwelling longwave flux
|-
| DFNIR || Radiation || W m-2 K-1 || xy || linearization of surface upwelling longwave flux
|-
| DFNIRN || Radiation || W m-2 K-1 || xy || linearization of surface upwelling longwave flux
|-
| DFPAR || Radiation || W m-2 K-1 || xy || linearization of surface upwelling longwave flux
|-
| DFPARN || Radiation || W m-2 K-1 || xy || linearization of surface upwelling longwave flux
|-
| DFUVR || Radiation || W m-2 K-1 || xy || linearization of surface upwelling longwave flux
|-
| DFUVRN || Radiation || W m-2 K-1 || xy || linearization of surface upwelling longwave flux
|-
| DRNIR || Radiation || W m-2 K-1 || xy || linearization of surface upwelling longwave flux
|-
| DRNIRN || Radiation || W m-2 K-1 || xy || linearization of surface upwelling longwave flux
|-
| DRPAR || Radiation || W m-2 K-1 || xy || linearization of surface upwelling longwave flux
|-
| DRPARN || Radiation || W m-2 K-1 || xy || linearization of surface upwelling longwave flux
|-
| DRUVR || Radiation || W m-2 K-1 || xy || linearization of surface upwelling longwave flux
|-
| DRUVRN || Radiation || W m-2 K-1 || xy || linearization of surface upwelling longwave flux
|-
| DTDT || Radiation || Pa K s-1 || xyz || pressure weighted air temperature tendency due to radiation
|-
| FCLD || Radiation || W m-2 K-1 || xy || linearization of surface upwelling longwave flux
|-
| LWS || Radiation || W m-2 K-1 || xy || linearization of surface upwelling longwave flux
|-
| RADLW || Radiation || K s-1 || xyz || air temperature tendency due to longwave
|-
| RADLWC || Radiation || K s-1 || xyz || air temperature tendency due to longwave for clear skies
|-
| RADLWCNA || Radiation || K s-1 || xyz || air temperature tendency due to longwave for clear skies no aerosol
|-
| RADSRF || Radiation || W m-2 || xy || net downwelling radiation at surface
|-
| RADSW || Radiation || K s-1 || xyz || air temperature tendency due to shortwave
|-
| RADSWC || Radiation || K s-1 || xyz || air temperature tendency due to shortwave for clear skies
|-
| RADSWCNA || Radiation || K s-1 || xyz || air temperature tendency due to shortwave for clear skies no aerosol
|-
| RADSWNA || Radiation || K s-1 || xyz || air temperature tendency due to shortwave no aerosol
|-
| TAUCLI || Radiation || W m-2 K-1 || xy || linearization of surface upwelling longwave flux
|-
| TAUCLW || Radiation || W m-2 K-1 || xy || linearization of surface upwelling longwave flux
|-
| ALBNF || Saltwater || 1 || tile || surface albedo for near infrared diffuse
|-
| ALBNR || Saltwater || 1 || tile || surface albedo for near infrared beam
|-
| ALBVF || Saltwater || 1 || tile || surface albedo for visible diffuse
|-
| ALBVR || Saltwater || 1 || tile || surface albedo for visible beam
|-
| BCOOL || Saltwater || m+2 s-3 || tile || bouyancy generation in cool layer
|-
| CHT || Saltwater || kg m-2 s-1 || tile || surface heat exchange coefficient
|-
| CMT || Saltwater || kg m-2 s-1 || tile || surface momentum exchange coefficient
|-
| CNT || Saltwater || 1 || tile || neutral drag coefficient
|-
| CQT || Saltwater || kg m-2 s-1 || tile || surface moisture exchange coefficient
|-
| DCOOL || Saltwater || m || tile || depth of cool layer
|-
| DELQS || Saltwater || kg kg-1 || tile || change of surface specific humidity
|-
| DELTS || Saltwater || K || tile || change of surface skin temperature
|-
| DWARM || Saltwater || m || tile || depth at base of warm layer
|-
| EMIS || Saltwater || 1 || tile || surface emissivity
|-
| EVAPOUT || Saltwater || kg m-2 s-1 || tile || evaporation
|-
| FRACI || Saltwater || 1 || tile || ice covered fraction of tile
|-
| GUST || Saltwater || m s-1 || tile || gustiness
|-
| HLATICE || Saltwater || W m-2 || tile || sea ice latent energy flux
|-
| HLATN || Saltwater || W m-2 || tile || total latent energy flux
|-
| HLATWTR || Saltwater || W m-2 || tile || open water latent energy flux
|-
| HLWUP || Saltwater || W m-2 || tile || surface outgoing longwave flux
|-
| LCOOL || Saltwater || 1 || tile || Saunders parameter
|-
| LWNDICE || Saltwater || W m-2 || tile || sea ice net downward longwave flux
|-
| LWNDSRF || Saltwater || W m-2 || tile || surface net downward longwave flux
|-
| LWNDWTR || Saltwater || W m-2 || tile || open water net downward longwave flux
|-
| MOQ10M || Saltwater || kg kg-1 || tile || humidity 10m wind from MO sfc
|-
| MOQ2M || Saltwater || kg kg-1 || tile || humidity 2m wind from MO sfc
|-
| MOT10M || Saltwater || K || tile || temperature 10m wind from MO sfc
|-
| MOT2M || Saltwater || K || tile || temperature 2m wind from MO sfc
|-
| MOU10M || Saltwater || m s-1 || tile || zonal 10m wind from MO sfc
|-
| MOU2M || Saltwater || m s-1 || tile || zonal 2m wind from MO sfc
|-
| MOU50M || Saltwater || m s-1 || tile || zonal 50m wind from MO sfc
|-
| MOV10M || Saltwater || m s-1 || tile || meridional 10m wind from MO sfc
|-
| MOV2M || Saltwater || m s-1 || tile || meridional 2m wind from MO sfc
|-
| MOV50M || Saltwater || m s-1 || tile || meridional 50m wind from MO sfc
|-
| OUSTAR3 || Saltwater || m+3 s-3 || tile || ocean ustar cubed
|-
| PENPAF || Saltwater || W m-2 || tile || downwelling par diffuse flux at skin base
|-
| PENPAR || Saltwater || W m-2 || tile || downwelling par direct flux at skin base
|-
| PENUVF || Saltwater || W m-2 || tile || downwelling uvr diffuse flux at skin base
|-
| PENUVR || Saltwater || W m-2 || tile || downwelling uvr direct flux at skin base
|-
| PS || Saltwater || Pa || tile || surface pressure
|-
| QCOOL || Saltwater || W m-2 || tile || net cooling in cool layer
|-
| QH || Saltwater || kg kg-1 || tile || turbulence surface specific humidity
|-
| QST || Saltwater || kg kg-1 || tile || surface specific humidity
|-
| RAINOCN || Saltwater || kg m-2 s-1 || tile || ocean rainfall
|-
| RET || Saltwater || 1 || tile || surface reynolds number
|-
| RIT || Saltwater || 1 || tile || surface bulk richardson number
|-
| SHICE || Saltwater || W m-2 || tile || sea ice upward sensible heat flux
|-
| SHOUT || Saltwater || W m-2 || tile || upward sensible heat flux
|-
| SHWTR || Saltwater || W m-2 || tile || open water upward sensible heat flux
|-
| SNOWOCN || Saltwater || kg m-2 s-1 || tile || ocean snowfall
|-
| SUBLIM || Saltwater || kg m-2 s-1 || tile || sublimation
|-
| SWCOOL || Saltwater || W m-2 || tile || solar heating in cool layer
|-
| SWNDICE || Saltwater || W m-2 || tile || sea ice net downward shortwave flux
|-
| SWNDSRF || Saltwater || W m-2 || tile || surface net downward shortwave flux
|-
| SWNDWTR || Saltwater || W m-2 || tile || open water net downward shortwave flux
|-
| TAUXI || Saltwater || N m-2 || tile || eastward stress over ice
|-
| TAUXO || Saltwater || N m-2 || tile || eastward stress on ocean
|-
| TAUXW || Saltwater || N m-2 || tile || eastward stress over water
|-
| TAUYI || Saltwater || N m-2 || tile || northward stress over ice
|-
| TAUYO || Saltwater || N m-2 || tile || northward stress on ocean
|-
| TAUYW || Saltwater || N m-2 || tile || northward stress over water
|-
| TBAR || Saltwater || K || tile || mean temperature of interface layer
|-
| TDEL || Saltwater || K || tile || temperature at base of cool layer
|-
| TDROP || Saltwater || K || tile || temperature drop across cool layer
|-
| TH || Saltwater || K || tile || turbulence surface temperature
|-
| TST || Saltwater || K || tile || surface skin temperature
|-
| TS_FOUND || Saltwater || K || tile || foundation temperature for interface layer
|-
| UCOOL || Saltwater || m s-1 || tile || ustarw at cool layer
|-
| UH || Saltwater || m s-1 || tile || turbulence surface zonal velocity
|-
| VENT || Saltwater || m s-1 || tile || surface ventilation velocity
|-
| VH || Saltwater || m s-1 || tile || turbulence surface meridional velocity
|-
| Z0 || Saltwater || m || tile || surface roughness
|-
| Z0H || Saltwater || m || tile || surface roughness for heat
|-
| ALBISCCP || Satsim || 1 || xy || isccp cloud albedo
|-
| CFADLIDARSR532_01 || Satsim || 1 || xyz || calipso scattering ratio cfad 01
|-
| CFADLIDARSR532_02 || Satsim || 1 || xyz || calipso scattering ratio cfad 02
|-
| CFADLIDARSR532_03 || Satsim || 1 || xyz || calipso scattering ratio cfad 03
|-
| CFADLIDARSR532_04 || Satsim || 1 || xyz || calipso scattering ratio cfad 04
|-
| CFADLIDARSR532_05 || Satsim || 1 || xyz || calipso scattering ratio cfad 05
|-
| CFADLIDARSR532_06 || Satsim || 1 || xyz || calipso scattering ratio cfad 06
|-
| CFADLIDARSR532_07 || Satsim || 1 || xyz || calipso scattering ratio cfad 07
|-
| CFADLIDARSR532_08 || Satsim || 1 || xyz || calipso scattering ratio cfad 08
|-
| CFADLIDARSR532_09 || Satsim || 1 || xyz || calipso scattering ratio cfad 09
|-
| CFADLIDARSR532_10 || Satsim || 1 || xyz || calipso scattering ratio cfad 10
|-
| CFADLIDARSR532_11 || Satsim || 1 || xyz || calipso scattering ratio cfad 11
|-
| CFADLIDARSR532_12 || Satsim || 1 || xyz || calipso scattering ratio cfad 12
|-
| CFADLIDARSR532_13 || Satsim || 1 || xyz || calipso scattering ratio cfad 13
|-
| CFADLIDARSR532_14 || Satsim || 1 || xyz || calipso scattering ratio cfad 14
|-
| CFADLIDARSR532_15 || Satsim || 1 || xyz || calipso scattering ratio cfad 15
|-
| CLCALIPSO || Satsim || 1 || xyz || calipso total cloud fraction
|-
| CLCALIPSO2 || Satsim || 1 || xyz || calipsonocloudsat cloud fraction
|-
| CLHCALIPSO || Satsim || 1 || xy || calipso high level cloud fraction
|-
| CLLCALIPSO || Satsim || 1 || xy || calipso low level cloud fraction
|-
| CLMCALIPSO || Satsim || 1 || xy || calipso mid level cloud fraction
|-
| CLOUDSATCFAD01 || Satsim || 1 || xyz || cloudsat radar reflectivity cfad
|-
| CLOUDSATCFAD02 || Satsim || 1 || xyz || cloudsat radar reflectivity cfad
|-
| CLOUDSATCFAD03 || Satsim || 1 || xyz || cloudsat radar reflectivity cfad
|-
| CLOUDSATCFAD04 || Satsim || 1 || xyz || cloudsat radar reflectivity cfad
|-
| CLOUDSATCFAD05 || Satsim || 1 || xyz || cloudsat radar reflectivity cfad
|-
| CLOUDSATCFAD06 || Satsim || 1 || xyz || cloudsat radar reflectivity cfad
|-
| CLOUDSATCFAD07 || Satsim || 1 || xyz || cloudsat radar reflectivity cfad
|-
| CLOUDSATCFAD08 || Satsim || 1 || xyz || cloudsat radar reflectivity cfad
|-
| CLOUDSATCFAD09 || Satsim || 1 || xyz || cloudsat radar reflectivity cfad
|-
| CLOUDSATCFAD10 || Satsim || 1 || xyz || cloudsat radar reflectivity cfad
|-
| CLOUDSATCFAD11 || Satsim || 1 || xyz || cloudsat radar reflectivity cfad
|-
| CLOUDSATCFAD12 || Satsim || 1 || xyz || cloudsat radar reflectivity cfad
|-
| CLOUDSATCFAD13 || Satsim || 1 || xyz || cloudsat radar reflectivity cfad
|-
| CLOUDSATCFAD14 || Satsim || 1 || xyz || cloudsat radar reflectivity cfad
|-
| CLOUDSATCFAD15 || Satsim || 1 || xyz || cloudsat radar reflectivity cfad
|-
| CLTCALIPSO || Satsim || 1 || xy || calipso total cloud fraction
|-
| CTPISCCP || Satsim || 1 || xy || isccp air pressure at cloud top
|-
| ISCCP1 || Satsim || 1 || xy || isccp output 0 180 hPa
|-
| ISCCP2 || Satsim || 1 || xy || isccp output 180 310 hPa
|-
| ISCCP3 || Satsim || 1 || xy || isccp output 310 440 hPa
|-
| ISCCP4 || Satsim || 1 || xy || isccp output 440 560 hPa
|-
| ISCCP5 || Satsim || 1 || xy || isccp output 560 680 hPa
|-
| ISCCP6 || Satsim || 1 || xy || isccp output 680 800 hPa
|-
| ISCCP7 || Satsim || 1 || xy || isccp output 800 SFC hPa
|-
| ISCCP_ACU_OA || Satsim || 1 || xy || fraction of thin higher altocumulus
|-
| ISCCP_ACU_OB || Satsim || 1 || xy || fraction of thick higher altocumulus
|-
| ISCCP_ACU_UA || Satsim || 1 || xy || fraction of thin lower altocumulus
|-
| ISCCP_ACU_UB || Satsim || 1 || xy || fraction of thick lower altocumulus
|-
| ISCCP_AST_OA || Satsim || 1 || xy || fraction of thin higher altostratus
|-
| ISCCP_AST_OB || Satsim || 1 || xy || fraction of thick higher altostratus
|-
| ISCCP_AST_UA || Satsim || 1 || xy || fraction of thin lower altostratus
|-
| ISCCP_AST_UB || Satsim || 1 || xy || fraction of thick lower altostratus
|-
| ISCCP_CB_MA || Satsim || 1 || xy || fraction of thin middle cumulonimbus
|-
| ISCCP_CB_MB || Satsim || 1 || xy || fraction of thick middle cumulonimbus
|-
| ISCCP_CB_OA || Satsim || 1 || xy || fraction of thin higher cumulonimbus
|-
| ISCCP_CB_OB || Satsim || 1 || xy || fraction of thick higher cumulonimbus
|-
| ISCCP_CB_UA || Satsim || 1 || xy || fraction of thin lower cumulonimbus
|-
| ISCCP_CB_UB || Satsim || 1 || xy || fraction of thick lower cumulonimbus
|-
| ISCCP_CIST_MA || Satsim || 1 || xy || fraction of thin middle cirrostratus
|-
| ISCCP_CIST_MB || Satsim || 1 || xy || fraction of thick middle cirrostratus
|-
| ISCCP_CIST_OA || Satsim || 1 || xy || fraction of thin higher cirrostratus
|-
| ISCCP_CIST_OB || Satsim || 1 || xy || fraction of thick higher cirrostratus
|-
| ISCCP_CIST_UA || Satsim || 1 || xy || fraction of thin lower cirrostratus
|-
| ISCCP_CIST_UB || Satsim || 1 || xy || fraction of thick lower cirrostratus
|-
| ISCCP_CI_MA || Satsim || 1 || xy || fraction of thin middle cirrus
|-
| ISCCP_CI_MB || Satsim || 1 || xy || fraction of thick middle cirrus
|-
| ISCCP_CI_OA || Satsim || 1 || xy || fraction of thin higher cirrus
|-
| ISCCP_CI_OB || Satsim || 1 || xy || fraction of thick higher cirrus
|-
| ISCCP_CI_UA || Satsim || 1 || xy || fraction of thin lower cirrus
|-
| ISCCP_CI_UB || Satsim || 1 || xy || fraction of thick lower cirrus
|-
| ISCCP_CU_OA || Satsim || 1 || xy || fraction of thin higher cumulus
|-
| ISCCP_CU_OB || Satsim || 1 || xy || fraction of thick higher cumulus
|-
| ISCCP_CU_UA || Satsim || 1 || xy || fraction of thin lower cumulus
|-
| ISCCP_CU_UB || Satsim || 1 || xy || fraction of thick lower cumulus
|-
| ISCCP_NST_OA || Satsim || 1 || xy || fraction of thin higher nimbostratus
|-
| ISCCP_NST_OB || Satsim || 1 || xy || fraction of thick higher nimbostratus
|-
| ISCCP_NST_UA || Satsim || 1 || xy || fraction of thin lower nimbostratus
|-
| ISCCP_NST_UB || Satsim || 1 || xy || fraction of thick lower nimbostratus
|-
| ISCCP_STCU_OA || Satsim || 1 || xy || fraction of thin higher stratocumulus
|-
| ISCCP_STCU_OB || Satsim || 1 || xy || fraction of thick higher stratocumulus
|-
| ISCCP_STCU_UA || Satsim || 1 || xy || fraction of thin lower stratocumulus
|-
| ISCCP_STCU_UB || Satsim || 1 || xy || fraction of thick lower stratocumulus
|-
| ISCCP_ST_OA || Satsim || 1 || xy || fraction of thin higher stratus
|-
| ISCCP_ST_OB || Satsim || 1 || xy || fraction of thick higher stratus
|-
| ISCCP_ST_UA || Satsim || 1 || xy || fraction of thin lower stratus
|-
| ISCCP_ST_UB || Satsim || 1 || xy || fraction of thick lower stratus
|-
| ISCCP_SUBV1 || Satsim || 1 || xy || fraction of subvisible cloud 0 180 hPa
|-
| ISCCP_SUBV2 || Satsim || 1 || xy || fraction of subvisible cloud 180 310 hPa
|-
| ISCCP_SUBV3 || Satsim || 1 || xy || fraction of subvisible cloud 310 440 hPa
|-
| ISCCP_SUBV4 || Satsim || 1 || xy || fraction of subvisible cloud 440 560 hPa
|-
| ISCCP_SUBV5 || Satsim || 1 || xy || fraction of subvisible cloud 560 680 hPa
|-
| ISCCP_SUBV6 || Satsim || 1 || xy || fraction of subvisible cloud 680 800 hPa
|-
| ISCCP_SUBV7 || Satsim || 1 || xy || fraction of subvisible cloud 800 SFC hPa
|-
| LIDARPMOL || Satsim || m-1 sr-1 || xyz || molecular attenuated backscatter lidar signal power
|-
| LIDARPTOT || Satsim || m-1 sr-1 || xyz || total attenuated backscatter lidar signal power
|-
| LIDARTAUTOT || Satsim || 1 || xyz || optical thickess integrated from top to level z
|-
| MDSCLDFRCH2O || Satsim || 1 || xy || modis cloud fraction water mean
|-
| MDSCLDFRCHI || Satsim || 1 || xy || modis cloud fraction high mean
|-
| MDSCLDFRCICE || Satsim || 1 || xy || modis cloud fraction ice mean
|-
| MDSCLDFRCLO || Satsim || 1 || xy || modis cloud fraction low mean
|-
| MDSCLDFRCMID || Satsim || 1 || xy || modis cloud fraction mid mean
|-
| MDSCLDFRCTTL || Satsim || 1 || xy || modis cloud fraction total mean
|-
| MDSCLDFRCWTR || Satsim || 1 || xy || modis cloud fraction water mean
|-
| MDSCLDSZH20 || Satsim || 1 || xy || modis cloud particle size water mean
|-
| MDSCLDSZICE || Satsim || 1 || xy || modis cloud particle size ice mean
|-
| MDSCLDSZWTR || Satsim || 1 || xy || modis cloud particle size water mean
|-
| MDSCLDTOPPS || Satsim || 1 || xy || modis cloud top pressure total mean
|-
| MDSH2OPATH || Satsim || 1 || xy || modis liquid water path mean
|-
| MDSICEPATH || Satsim || 1 || xy || modis ice water path mean
|-
| MDSOPTHCKH2O || Satsim || 1 || xy || modis optical thickness water mean
|-
| MDSOPTHCKH2OLG || Satsim || 1 || xy || modis optical thickness water logmean
|-
| MDSOPTHCKICE || Satsim || 1 || xy || modis optical thickness ice mean
|-
| MDSOPTHCKICELG || Satsim || 1 || xy || modis optical thickness ice logmean
|-
| MDSOPTHCKTTL || Satsim || 1 || xy || modis optical thickness total mean
|-
| MDSOPTHCKTTLLG || Satsim || 1 || xy || modis optical thickness total logmean
|-
| MDSOPTHCKWTR || Satsim || 1 || xy || modis optical thickness water mean
|-
| MDSOPTHCKWTRLG || Satsim || 1 || xy || modis optical thickness water logmean
|-
| MDSTAUPRSHIST11 || Satsim || 1 || xy || modis tau pressure histogram bin 1 1
|-
| MDSTAUPRSHIST12 || Satsim || 1 || xy || modis tau pressure histogram bin 1 2
|-
| MDSTAUPRSHIST13 || Satsim || 1 || xy || modis tau pressure histogram bin 1 3
|-
| MDSTAUPRSHIST14 || Satsim || 1 || xy || modis tau pressure histogram bin 1 4
|-
| MDSTAUPRSHIST15 || Satsim || 1 || xy || modis tau pressure histogram bin 1 5
|-
| MDSTAUPRSHIST16 || Satsim || 1 || xy || modis tau pressure histogram bin 1 6
|-
| MDSTAUPRSHIST17 || Satsim || 1 || xy || modis tau pressure histogram bin 1 7
|-
| MDSTAUPRSHIST21 || Satsim || 1 || xy || modis tau pressure histogram bin 2 1
|-
| MDSTAUPRSHIST22 || Satsim || 1 || xy || modis tau pressure histogram bin 2 2
|-
| MDSTAUPRSHIST23 || Satsim || 1 || xy || modis tau pressure histogram bin 2 3
|-
| MDSTAUPRSHIST24 || Satsim || 1 || xy || modis tau pressure histogram bin 2 4
|-
| MDSTAUPRSHIST25 || Satsim || 1 || xy || modis tau pressure histogram bin 2 5
|-
| MDSTAUPRSHIST26 || Satsim || 1 || xy || modis tau pressure histogram bin 2 6
|-
| MDSTAUPRSHIST27 || Satsim || 1 || xy || modis tau pressure histogram bin 2 7
|-
| MDSTAUPRSHIST31 || Satsim || 1 || xy || modis tau pressure histogram bin 3 1
|-
| MDSTAUPRSHIST32 || Satsim || 1 || xy || modis tau pressure histogram bin 3 2
|-
| MDSTAUPRSHIST33 || Satsim || 1 || xy || modis tau pressure histogram bin 3 3
|-
| MDSTAUPRSHIST34 || Satsim || 1 || xy || modis tau pressure histogram bin 3 4
|-
| MDSTAUPRSHIST35 || Satsim || 1 || xy || modis tau pressure histogram bin 3 5
|-
| MDSTAUPRSHIST36 || Satsim || 1 || xy || modis tau pressure histogram bin 3 6
|-
| MDSTAUPRSHIST37 || Satsim || 1 || xy || modis tau pressure histogram bin 3 7
|-
| MDSTAUPRSHIST41 || Satsim || 1 || xy || modis tau pressure histogram bin 4 1
|-
| MDSTAUPRSHIST42 || Satsim || 1 || xy || modis tau pressure histogram bin 4 2
|-
| MDSTAUPRSHIST43 || Satsim || 1 || xy || modis tau pressure histogram bin 4 3
|-
| MDSTAUPRSHIST44 || Satsim || 1 || xy || modis tau pressure histogram bin 4 4
|-
| MDSTAUPRSHIST45 || Satsim || 1 || xy || modis tau pressure histogram bin 4 5
|-
| MDSTAUPRSHIST46 || Satsim || 1 || xy || modis tau pressure histogram bin 4 6
|-
| MDSTAUPRSHIST47 || Satsim || 1 || xy || modis tau pressure histogram bin 4 7
|-
| MDSTAUPRSHIST51 || Satsim || 1 || xy || modis tau pressure histogram bin 5 1
|-
| MDSTAUPRSHIST52 || Satsim || 1 || xy || modis tau pressure histogram bin 5 2
|-
| MDSTAUPRSHIST53 || Satsim || 1 || xy || modis tau pressure histogram bin 5 3
|-
| MDSTAUPRSHIST54 || Satsim || 1 || xy || modis tau pressure histogram bin 5 4
|-
| MDSTAUPRSHIST55 || Satsim || 1 || xy || modis tau pressure histogram bin 5 5
|-
| MDSTAUPRSHIST56 || Satsim || 1 || xy || modis tau pressure histogram bin 5 6
|-
| MDSTAUPRSHIST57 || Satsim || 1 || xy || modis tau pressure histogram bin 5 7
|-
| MDSTAUPRSHIST61 || Satsim || 1 || xy || modis tau pressure histogram bin 6 1
|-
| MDSTAUPRSHIST62 || Satsim || 1 || xy || modis tau pressure histogram bin 6 2
|-
| MDSTAUPRSHIST63 || Satsim || 1 || xy || modis tau pressure histogram bin 6 3
|-
| MDSTAUPRSHIST64 || Satsim || 1 || xy || modis tau pressure histogram bin 6 4
|-
| MDSTAUPRSHIST65 || Satsim || 1 || xy || modis tau pressure histogram bin 6 5
|-
| MDSTAUPRSHIST66 || Satsim || 1 || xy || modis tau pressure histogram bin 6 6
|-
| MDSTAUPRSHIST67 || Satsim || 1 || xy || modis tau pressure histogram bin 6 7
|-
| MDSTAUPRSHIST71 || Satsim || 1 || xy || modis tau pressure histogram bin 7 1
|-
| MDSTAUPRSHIST72 || Satsim || 1 || xy || modis tau pressure histogram bin 7 2
|-
| MDSTAUPRSHIST73 || Satsim || 1 || xy || modis tau pressure histogram bin 7 3
|-
| MDSTAUPRSHIST74 || Satsim || 1 || xy || modis tau pressure histogram bin 7 4
|-
| MDSTAUPRSHIST75 || Satsim || 1 || xy || modis tau pressure histogram bin 7 5
|-
| MDSTAUPRSHIST76 || Satsim || 1 || xy || modis tau pressure histogram bin 7 6
|-
| MDSTAUPRSHIST77 || Satsim || 1 || xy || modis tau pressure histogram bin 7 7
|-
| MDSWTRPATH || Satsim || 1 || xy || modis liquid water path mean
|-
| MISRCLDAREA || Satsim || 1 || xy || MISR cloud area
|-
| MISRFQ0 || Satsim || 1 || xy || MISR cloud area
|-
| MISRFQ10000 || Satsim || 1 || xy || MISR layer top
|-
| MISRFQ12000 || Satsim || 1 || xy || MISR layer top
|-
| MISRFQ1250 || Satsim || 1 || xy || MISR cloud area
|-
| MISRFQ14000 || Satsim || 1 || xy || MISR layer top
|-
| MISRFQ16000 || Satsim || 1 || xy || MISR layer top
|-
| MISRFQ1750 || Satsim || 1 || xy || MISR cloud area
|-
| MISRFQ18000 || Satsim || 1 || xy || MISR layer top
|-
| MISRFQ2250 || Satsim || 1 || xy || MISR cloud area
|-
| MISRFQ250 || Satsim || 1 || xy || MISR cloud area
|-
| MISRFQ2750 || Satsim || 1 || xy || MISR cloud area
|-
| MISRFQ3500 || Satsim || 1 || xy || MISR layer top
|-
| MISRFQ4500 || Satsim || 1 || xy || MISR layer top
|-
| MISRFQ6000 || Satsim || 1 || xy || MISR layer top
|-
| MISRFQ750 || Satsim || 1 || xy || MISR cloud area
|-
| MISRFQ8000 || Satsim || 1 || xy || MISR layer top
|-
| MISRLYRTP0 || Satsim || 1 || xy || MISR layer top
|-
| MISRLYRTP10000 || Satsim || 1 || xy || MISR layer top
|-
| MISRLYRTP12000 || Satsim || 1 || xy || MISR layer top
|-
| MISRLYRTP1250 || Satsim || 1 || xy || MISR layer top
|-
| MISRLYRTP14000 || Satsim || 1 || xy || MISR layer top
|-
| MISRLYRTP16000 || Satsim || 1 || xy || MISR layer top
|-
| MISRLYRTP1750 || Satsim || 1 || xy || MISR layer top
|-
| MISRLYRTP18000 || Satsim || 1 || xy || MISR layer top
|-
| MISRLYRTP2250 || Satsim || 1 || xy || MISR layer top
|-
| MISRLYRTP250 || Satsim || 1 || xy || MISR layer top
|-
| MISRLYRTP2750 || Satsim || 1 || xy || MISR layer top
|-
| MISRLYRTP3500 || Satsim || 1 || xy || MISR layer top
|-
| MISRLYRTP4500 || Satsim || 1 || xy || MISR layer top
|-
| MISRLYRTP6000 || Satsim || 1 || xy || MISR layer top
|-
| MISRLYRTP750 || Satsim || 1 || xy || MISR layer top
|-
| MISRLYRTP8000 || Satsim || 1 || xy || MISR layer top
|-
| MISRMNCLDTP || Satsim || m || xy || MISR mead cloud top height
|-
| PARASOLREFL0 || Satsim || 1 || xy || parasol reflectance
|-
| PARASOLREFL1 || Satsim || 1 || xy || parasol reflectance 1
|-
| PARASOLREFL2 || Satsim || 1 || xy || parasol reflectance 2
|-
| PARASOLREFL3 || Satsim || 1 || xy || parasol reflectance 3
|-
| PARASOLREFL4 || Satsim || 1 || xy || parasol reflectance 4
|-
| PARASOLREFL5 || Satsim || 1 || xy || parasol reflectance 5
|-
| RADARLTCC || Satsim || 1 || xy || Radar and lidar total cloud amount
|-
| RADARZETOT || Satsim || 1 || xyz || radar output
|-
| SGFCLD || Satsim || 1 || xyz || summed subgrid cloud fraction from scops
|-
| TCLISCCP || Satsim || 1 || xy || isccp total  cloud area fraction
|-
| self%newvar_name(m) || Satsim || units || unk || long name
|-
| self%newvar_name(m) || Satsim || units || unk || long name
|-
| ALBEDO || Solar || 1 || xy || surface albedo
|-
| ALBNF || Solar || 1 || xy || surface albedo for near infrared diffuse
|-
| ALBNR || Solar || 1 || xy || surface albedo for near infrared beam
|-
| ALBVF || Solar || 1 || xy || surface albedo for visible diffuse
|-
| ALBVR || Solar || 1 || xy || surface albedo for visible beam
|-
| CLDHI || Solar || 1 || xy || cloud area fraction for high clouds
|-
| CLDLO || Solar || 1 || xy || cloud area fraction for low clouds
|-
| CLDMD || Solar || 1 || xy || cloud area fraction for middle clouds
|-
| CLDPRS || Solar || Pa || xy || cloud top pressure
|-
| CLDTMP || Solar || K || xy || cloud top temperature
|-
| CLDTT || Solar || 1 || xy || total cloud area fraction
|-
| COSZ || Solar || 1 || xy || cosine of the solar zenith angle
|-
| DFNIR || Solar || W m-2 || xy || surface downwelling nearinfrared diffuse flux
|-
| DFNIRN || Solar || 1 || xy || normalized surface downwelling nearinfrared diffuse flux
|-
| DFPAR || Solar || W m-2 || xy || surface downwelling par diffuse flux
|-
| DFPARN || Solar || 1 || xy || normalized surface downwelling par diffuse flux
|-
| DFUVR || Solar || W m-2 || xy || surface downwelling ultraviolet diffuse flux
|-
| DFUVRN || Solar || 1 || xy || normalized surface downwelling ultraviolet diffuse flux
|-
| DRNIR || Solar || W m-2 || xy || surface downwelling nearinfrared beam flux
|-
| DRNIRN || Solar || 1 || xy || normalized surface downwelling nearinfrared beam flux
|-
| DRNNIR || Solar || W m-2 || xy || surface downwelling nearinfrared beam normal flux
|-
| DRNPAR || Solar || W m-2 || xy || surface downwelling par beam normal flux
|-
| DRNUVR || Solar || W m-2 || xy || surface downwelling ultraviolet beam normal flux
|-
| DRPAR || Solar || W m-2 || xy || surface downwelling par beam flux
|-
| DRPARN || Solar || 1 || xy || normalized surface downwelling par beam flux
|-
| DRUVR || Solar || W m-2 || xy || surface downwelling ultraviolet beam flux
|-
| DRUVRN || Solar || 1 || xy || normalized surface downwelling ultraviolet beam flux
|-
| FCLD || Solar || 1 || xyz || cloud area fraction
|-
| FSC || Solar || W m-2 || xyz || net downward shortwave flux in air assuming clear sky
|-
| FSCD || Solar || W m-2 || xyz || downward shortwave flux in air assuming clear sky
|-
| FSCDNA || Solar || W m-2 || xyz || downward shortwave flux in air assuming clear sky and no aerosol
|-
| FSCNA || Solar || W m-2 || xyz || net downward shortwave flux in air assuming clear sky and no aerosol
|-
| FSCU || Solar || W m-2 || xyz || upward shortwave flux in air assuming clear sky
|-
| FSCUNA || Solar || W m-2 || xyz || upward shortwave flux in air assuming clear sky and no aerosol
|-
| FSW || Solar || W m-2 || xyz || net downward shortwave flux in air
|-
| FSWBAND || Solar || W m-2 || xy || net surface downward shortwave flux per band in air
|-
| FSWBANDNA || Solar || W m-2 || xy || net surface downward shortwave flux per band in air assuming no aerosol
|-
| FSWD || Solar || W m-2 || xyz || downward shortwave flux in air
|-
| FSWDNA || Solar || W m-2 || xyz || downward shortwave flux in air assuming no aerosol
|-
| FSWNA || Solar || W m-2 || xyz || net downward shortwave flux in air assuming no aerosol
|-
| FSWU || Solar || W m-2 || xyz || upward shortwave flux in air
|-
| FSWUNA || Solar || W m-2 || xyz || upward shortwave flux in air assuming no aerosol
|-
| MCOSZ || Solar || 1 || xy || mean cosine of the solar zenith angle
|-
| OSR || Solar || W m-2 || xy || toa outgoing shortwave flux
|-
| OSRCLR || Solar || W m-2 || xy || toa outgoing shortwave flux assuming clear sky
|-
| OSRCNA || Solar || W m-2 || xy || toa outgoing shortwave flux no aerosol  clear sky
|-
| OSRNA || Solar || W m-2 || xy || toa outgoing shortwave flux no aerosol
|-
| RSC || Solar || W m-2 || xy || toa net downward shortwave flux assuming clear sky
|-
| RSCNA || Solar || W m-2 || xy || toa net downward shortwave flux assuming clear sky and no aerosol
|-
| RSCS || Solar || W m-2 || xy || surface net downward shortwave flux assuming clear sky
|-
| RSCSNA || Solar || W m-2 || xy || surface net downward shortwave flux assuming clear sky and no aerosol
|-
| RSR || Solar || W m-2 || xy || toa net downward shortwave flux
|-
| RSRNA || Solar || W m-2 || xy || toa net downward shortwave flux assuming no aerosol
|-
| RSRS || Solar || W m-2 || xy || surface net downward shortwave flux
|-
| RSRSNA || Solar || W m-2 || xy || surface net downward shortwave flux assuming no aerosol
|-
| SLRSF || Solar || W m-2 || xy || surface incoming shortwave flux
|-
| SLRSFC || Solar || W m-2 || xy || surface incoming shortwave flux assuming clear sky
|-
| SLRSFCNA || Solar || W m-2 || xy || surface incoming shortwave flux assuming clear clean sky
|-
| SLRSFNA || Solar || W m-2 || xy || surface incoming shortwave flux assuming clean sky
|-
| SLRSUF || Solar || W m-2 || xy || surface outgoing shortwave flux
|-
| SLRSUFC || Solar || W m-2 || xy || surface outgoing shortwave flux assuming clear sky
|-
| SLRSUFCNA || Solar || W m-2 || xy || surface outgoing shortwave flux assuming clear clean sky
|-
| SLRSUFNA || Solar || W m-2 || xy || surface outgoing shortwave flux assuming clean sky
|-
| SLRTP || Solar || W m-2 || xy || toa incoming shortwave flux
|-
| TAUA1 || Solar || 1 || xyz || aerosol optical thickness in 0.225-0.285 band
|-
| TAUA2 || Solar || 1 || xyz || aerosol optical thickness in 0.175-0.225 0.285-0.300 band
|-
| TAUA3 || Solar || 1 || xyz || aerosol optical thickness in 0.300-0.325 band
|-
| TAUA4 || Solar || 1 || xyz || aerosol optical thickness in 0.325-0.4 band
|-
| TAUA5 || Solar || 1 || xyz || aerosol optical thickness in  0.4-0.690 band
|-
| TAUA6 || Solar || 1 || xyz || aerosol optical thickness in 0.690-1.220 band
|-
| TAUA7 || Solar || 1 || xyz || aerosol optical thickness in 1.220-2.270 band
|-
| TAUA8 || Solar || 1 || xyz || aerosol optical thickness in 2.270-3.850 band
|-
| TAUBC || Solar || 1 || xyz || black carbon optical thickness in 0.4-0.690 band
|-
| TAUCLI || Solar || 1 || xyz || optical thickness for ice clouds
|-
| TAUCLR || Solar || 1 || xyz || optical thickness for falling rain
|-
| TAUCLS || Solar || 1 || xyz || optical thickness for falling snow
|-
| TAUCLW || Solar || 1 || xyz || optical thickness for liquid clouds
|-
| TAUDU || Solar || 1 || xyz || dust optical thickness in 0.4-0.690 band
|-
| TAUHI || Solar || 1 || xy || optical thickness of high clouds(EXPORT)
|-
| TAULO || Solar || 1 || xy || optical thickness of low clouds
|-
| TAUMD || Solar || 1 || xy || optical thickness of middle clouds
|-
| TAUOC || Solar || 1 || xyz || organic carbon optical thickness in 0.4-0.690 band
|-
| TAUSO || Solar || 1 || xyz || sulfate optical thickness in 0.4-0.690 band
|-
| TAUSS || Solar || 1 || xyz || salt optical thickness in 0.4-0.690 band
|-
| TAUTT || Solar || 1 || xy || optical thickness of all clouds
|-
| TBC || Solar || kg m-2 || xy || total black carbon aerosol loading
|-
| TDUST || Solar || kg m-2 || xy || total dust aerosol loading
|-
| TOC || Solar || kg m-2 || xy || total organic carbon aerosol loading
|-
| TSALT || Solar || kg m-2 || xy || total sea salt aerosol loading
|-
| TSO4 || Solar || kg m-2 || xy || total sulfate aerosol loading
|-
| TTAUBC || Solar || 1 || xy || total black carbon optical thickness in 0.4-0.690 band
|-
| TTAUDU || Solar || 1 || xy || total dust optical thickness in 0.4-0.690 band
|-
| TTAUOC || Solar || 1 || xy || total organic carbon optical thickness in 0.4-0.690 band
|-
| TTAUSO || Solar || 1 || xy || total sulfate optical thickness in 0.4-0.690 band
|-
| TTAUSS || Solar || 1 || xy || total salt optical thickness in 0.4-0.690 band
|-
| AGCMTROPP || StratChem || Pa || xy || tropopause pressure imported into StratChem
|-
| AOADAYS_SCTEND || StratChem || days s-1 || xyz || chemical rate of change AOADAYS
|-
| BRCL_SCTEND || StratChem || mol mol-1 s-1 || xyz || chemical rate of change BRCL
|-
| BRONO2_SCTEND || StratChem || mol mol-1 s-1 || xyz || chemical rate of change BRONO2
|-
| BRX_SCTEND || StratChem || mol mol-1 s-1 || xyz || chemical rate of change BRX
|-
| CCL4FLX || StratChem || kg s-1 || xy || derived CCl4 surface flux
|-
| CCL4_SCTEND || StratChem || mol mol-1 s-1 || xyz || chemical rate of change CCL4
|-
| CFC113_SCTEND || StratChem || mol mol-1 s-1 || xyz || chemical rate of change CFC113
|-
| CFC11_SCTEND || StratChem || mol mol-1 s-1 || xyz || chemical rate of change CFC11
|-
| CFC12_SCTEND || StratChem || mol mol-1 s-1 || xyz || chemical rate of change CFC12
|-
| CH3BRFLX || StratChem || kg s-1 || xy || derived CH3Br surface flux
|-
| CH3BR_SCTEND || StratChem || mol mol-1 s-1 || xyz || chemical rate of change CH3BR
|-
| CH3CCL3_SCTEND || StratChem || mol mol-1 s-1 || xyz || chemical rate of change CH3CCL3
|-
| CH3CLFLX || StratChem || kg s-1 || xy || derived CH3Cl surface flux
|-
| CH3CL_SCTEND || StratChem || mol mol-1 s-1 || xyz || chemical rate of change CH3CL
|-
| CH3OOH_SCTEND || StratChem || mol mol-1 s-1 || xyz || chemical rate of change CH3OOH
|-
| CH4FLX || StratChem || kg s-1 || xy || derived CH4 surface flux
|-
| CH4_SCTEND || StratChem || mol mol-1 s-1 || xyz || chemical rate of change CH4
|-
| CL2_SCTEND || StratChem || mol mol-1 s-1 || xyz || chemical rate of change CL2
|-
| CLONO2_SCTEND || StratChem || mol mol-1 s-1 || xyz || chemical rate of change CLONO2
|-
| CLX_SCTEND || StratChem || mol mol-1 s-1 || xyz || chemical rate of change CLX
|-
| CO_SCTEND || StratChem || mol mol-1 s-1 || xyz || chemical rate of change CO
|-
| F113FLX || StratChem || kg s-1 || xy || derived CFC-113 surface flux
|-
| F11FLX || StratChem || kg s-1 || xy || derived CFC-11 surface flux
|-
| F12FLX || StratChem || kg s-1 || xy || derived CFC-12 surface flux
|-
| H1224FLX || StratChem || kg s-1 || xy || derived H1224 surface flux
|-
| H12_24_SCTEND || StratChem || mol mol-1 s-1 || xyz || chemical rate of change H12 24
|-
| H1301FLX || StratChem || kg s-1 || xy || derived H1301 surface flux
|-
| H1301_SCTEND || StratChem || mol mol-1 s-1 || xyz || chemical rate of change H1301
|-
| H2O2_SCTEND || StratChem || mol mol-1 s-1 || xyz || chemical rate of change H2O2
|-
| H2O_TEND || StratChem || kg kg-1 s-1 || xyz || tendency of water vapor mixing ratio due to chemistry
|-
| HBR_SCTEND || StratChem || mol mol-1 s-1 || xyz || chemical rate of change HBR
|-
| HCFC22_SCTEND || StratChem || mol mol-1 s-1 || xyz || chemical rate of change HCFC22
|-
| HCFCFLX || StratChem || kg s-1 || xy || derived HCFC surface flux
|-
| HCFC_SCTEND || StratChem || mol mol-1 s-1 || xyz || chemical rate of change HCFC
|-
| HCL_SCTEND || StratChem || mol mol-1 s-1 || xyz || chemical rate of change HCL
|-
| HNO3COND_SCTEND || StratChem || mol mol-1 s-1 || xyz || chemical rate of change HNO3COND
|-
| HNO3_SCTEND || StratChem || mol mol-1 s-1 || xyz || chemical rate of change HNO3
|-
| HO2NO2_SCTEND || StratChem || mol mol-1 s-1 || xyz || chemical rate of change HO2NO2
|-
| HOBR_SCTEND || StratChem || mol mol-1 s-1 || xyz || chemical rate of change HOBR
|-
| HOCL_SCTEND || StratChem || mol mol-1 s-1 || xyz || chemical rate of change HOCL
|-
| ICESAD || StratChem || m-1 || xyz || surface area density water ice PSC
|-
| MCFFLX || StratChem || kg s-1 || xy || derived CH3CCl3 surface flux
|-
| N2O5_SCTEND || StratChem || mol mol-1 s-1 || xyz || chemical rate of change N2O5
|-
| N2OFLX || StratChem || kg s-1 || xy || derived N2O surface flux
|-
| N2O_SCTEND || StratChem || mol mol-1 s-1 || xyz || chemical rate of change N2O
|-
| NATSAD || StratChem || m-1 || xyz || surface area density nitric acid trihydrate PSC
|-
| NOX_SCTEND || StratChem || mol mol-1 s-1 || xyz || chemical rate of change NOX
|-
| O3 || StratChem || kg kg-1 || xyz || ozone mass mixing ratio
|-
| O3PPMV || StratChem || ppmv || xyz || ozone volume mixing ratio
|-
| OCLO_SCTEND || StratChem || mol mol-1 s-1 || xyz || chemical rate of change OCLO
|-
| OX_SCTEND || StratChem || mol mol-1 s-1 || xyz || chemical rate of change OX
|-
| OX_TEND || StratChem || kg kg-1 s-1 || xyz || tendency of odd oxygen mixing ratio due to chemistry
|-
| SCBASEK || StratChem || 1 || xy || stratosphere base layer
|-
| SCTO3 || StratChem || dobsons || xy || total ozone from StratChem
|-
| SCTROPP || StratChem || Pa || xy || tropopause pressure used in StratChem
|-
| SCTTO3 || StratChem || dobsons || xy || tropospheric total ozone from StratChem
|-
| SZARAD || StratChem || rad || xy || solar zenith angle
|-
| AK || Superdyn || Pa K s-1 || xyz || delta-p weighted temperature tendency
|-
| AREA || Superdyn || Pa K s-1 || xyz || delta-p weighted temperature tendency
|-
| BK || Superdyn || Pa K s-1 || xyz || delta-p weighted temperature tendency
|-
| DOXDTANAINT || Superdyn || Pa K s-1 || xyz || delta-p weighted temperature tendency
|-
| DQIDTANAINT || Superdyn || Pa K s-1 || xyz || delta-p weighted temperature tendency
|-
| DQLDTANAINT || Superdyn || Pa K s-1 || xyz || delta-p weighted temperature tendency
|-
| DQVDTANAINT || Superdyn || Pa K s-1 || xyz || delta-p weighted temperature tendency
|-
| DTHVDTANAINT || Superdyn || Pa K s-1 || xyz || delta-p weighted temperature tendency
|-
| DTHVDTPHYINT || Superdyn || Pa K s-1 || xyz || delta-p weighted temperature tendency
|-
| DZ || Superdyn || Pa K s-1 || xyz || delta-p weighted temperature tendency
|-
| EPV || Superdyn || Pa K s-1 || xyz || delta-p weighted temperature tendency
|-
| OMEGA || Superdyn || Pa K s-1 || xyz || delta-p weighted temperature tendency
|-
| PE || Superdyn || Pa K s-1 || xyz || delta-p weighted temperature tendency
|-
| PEANA || Superdyn || Pa K s-1 || xyz || delta-p weighted temperature tendency
|-
| PEPHY || Superdyn || Pa K s-1 || xyz || delta-p weighted temperature tendency
|-
| PL || Superdyn || Pa K s-1 || xyz || delta-p weighted temperature tendency
|-
| PLE || Superdyn || Pa K s-1 || xyz || delta-p weighted temperature tendency
|-
| PLK || Superdyn || Pa K s-1 || xyz || delta-p weighted temperature tendency
|-
| PREF || Superdyn || Pa K s-1 || xyz || delta-p weighted temperature tendency
|-
| PS || Superdyn || Pa K s-1 || xyz || delta-p weighted temperature tendency
|-
| PT || Superdyn || Pa K s-1 || xyz || delta-p weighted temperature tendency
|-
| PV || Superdyn || Pa K s-1 || xyz || delta-p weighted temperature tendency
|-
| QA || Superdyn || Pa K s-1 || xyz || delta-p weighted temperature tendency
|-
| S || Superdyn || Pa K s-1 || xyz || delta-p weighted temperature tendency
|-
| SPEED || Superdyn || Pa K s-1 || xyz || delta-p weighted temperature tendency
|-
| T || Superdyn || Pa K s-1 || xyz || delta-p weighted temperature tendency
|-
| TA || Superdyn || Pa K s-1 || xyz || delta-p weighted temperature tendency
|-
| TH || Superdyn || Pa K s-1 || xyz || delta-p weighted temperature tendency
|-
| TROPP_BLENDED || Superdyn || Pa K s-1 || xyz || delta-p weighted temperature tendency
|-
| TV || Superdyn || Pa K s-1 || xyz || delta-p weighted temperature tendency
|-
| U || Superdyn || Pa K s-1 || xyz || delta-p weighted temperature tendency
|-
| U_DGRID || Superdyn || Pa K s-1 || xyz || delta-p weighted temperature tendency
|-
| V || Superdyn || Pa K s-1 || xyz || delta-p weighted temperature tendency
|-
| V_DGRID || Superdyn || Pa K s-1 || xyz || delta-p weighted temperature tendency
|-
| ZLE || Superdyn || Pa K s-1 || xyz || delta-p weighted temperature tendency
|-
| ACCUM || Surface || kg m-2 s-1 || xy || net ice accumulation rate
|-
| ALBNF || Surface || 1 || xy || surface albedo for nearinfraed diffuse
|-
| ALBNR || Surface || 1 || xy || surface albedo for nearinfrared beam
|-
| ALBVF || Surface || 1 || xy || surface albedo for visible diffuse
|-
| ALBVR || Surface || 1 || xy || surface albedo for visible beam
|-
| ASNOW || Surface || 1 || xy || fractional area of land snowcover
|-
| AVETSNOW || Surface || K || xy || averaged snow temperature
|-
| BASEFLOW || Surface || kg m-2 s-1 || xy || baseflow flux
|-
| BCOOL || Surface || m+2 s-3 || xy || bouyancy generation in cool layer
|-
| BSTAR || Surface || m s-2 || xy || surface bouyancy scale
|-
| CAPAC || Surface || kg m-2 || xy || interception reservoir capac
|-
| CDCR2 || Surface || kg m-2 || xy || max water content
|-
| CONGEL || Surface || m s-1 || xy || congelation ice growth
|-
| DAIDTD || Surface || \% day-1 || xy || ice area tendency dueto dynamics
|-
| DAIDTT || Surface || \% day-1 || xy || ice area tendency dueto thermodynamics
|-
| DCOOL || Surface || m || xy || depth of cool layer
|-
| DELQS || Surface || kg kg-1 || xy || change of surface specific humidity
|-
| DELSS || Surface || m+2 s-2 || xy || change of surface dry static energy
|-
| DELTS || Surface || K || xy || change of surface skin temperature
|-
| DELUS || Surface || m s-1 || xy || change of surface eastward velocity
|-
| DELVS || Surface || m s-1 || xy || change of surface northward velocity
|-
| DHLAND || Surface || W m-2 || xy || rate of change of total land energy
|-
| DISCHARGE || Surface || kg m-2 s-1 || xy || river discharge at ocean points
|-
| DISCHARGE_IN || Surface || kg m-2 s-1 || xy || river discharge at ocean points
|-
| DISCHARGE_OUT || Surface || kg m-2 s-1 || xy || river discharge at ocean points
|-
| DLQIL || Surface || kg kg-1 || xy || change of surface frozen condensate
|-
| DLQLL || Surface || kg kg-1 || xy || change of surface liquid condensate
|-
| DRAINAGE || Surface || kg m-2 s-1 || xy || river drainage at ocean points
|-
| DVIDTD || Surface || cm day-1 || xy || ice volume tendency dueto dynamics
|-
| DVIDTT || Surface || cm day-1 || xy || ice volume tendency dueto thermodynamics
|-
| DWARM || Surface || m || xy || depth at base of warm layer
|-
| DWLAND || Surface || kg m-2 s-1 || xy || rate of change of total land water
|-
| EMIS || Surface || 1 || xy || surface emissivity
|-
| EVAP || Surface || kg m-2 s-1 || xy || evaporation from turbulence
|-
| EVAPOUT || Surface || kg m-2 s-1 || xy || evaporation
|-
| EVLAND || Surface || kg m-2 s-1 || xy || Evaporation land
|-
| EVPICE || Surface || W m-2 || xy || snow ice evaporation energy flux
|-
| EVPINT || Surface || W m-2 || xy || interception loss energy flux
|-
| EVPSNO || Surface || W m-2 || xy || snowpack evaporation energy flux
|-
| EVPSOI || Surface || W m-2 || xy || baresoil evap energy flux
|-
| EVPVEG || Surface || W m-2 || xy || transpiration energy flux
|-
| FBOT || Surface || W m-2 || xy || net downward heat flux from ice to ocean
|-
| FHOCN || Surface || W m-2 || xy || actual ocean ice flux
|-
| FRACI || Surface || 1 || xy || ice covered fraction of tile
|-
| FRAZIL || Surface || m s-1 || xy || frazil ice growth
|-
| FRLAKE || Surface || 1 || xy || fraction of lake
|-
| FRLAND || Surface || 1 || xy || fraction of land
|-
| FRLANDICE || Surface || 1 || xy || fraction of land ice
|-
| FROCEAN || Surface || 1 || xy || fraction of ocean
|-
| FRSAT || Surface || 1 || xy || fractional area of saturated zone
|-
| FRUST || Surface || 1 || xy || fractional area of unsaturated zone
|-
| FRWLT || Surface || 1 || xy || fractional area of wilting zone
|-
| FRZMLT || Surface || W m-2 || xy || freezing melting potential
|-
| FSWABS || Surface || W m-2 || xy || SW flux absorbed by skin layer
|-
| FSWTHRU || Surface || W m-2 || xy || SW flux thru ice to ocean
|-
| GHLAND || Surface || W m-2 || xy || Ground heating land
|-
| GRN || Surface || 1 || xy || greeness fraction
|-
| GUST || Surface || m s-1 || xy || gustiness
|-
| HFLUX || Surface || W m-2 || xy || heat flux bw saltwater ocean
|-
| HICE || Surface || m || xy || grid cell mean ice thickness
|-
| HLATICE || Surface || W m-2 || xy || sea ice latent energy flux
|-
| HLATWTR || Surface || W m-2 || xy || open water latent energy flux
|-
| HLWUP || Surface || W m-2 || xy || surface outgoing longwave flux
|-
| HSNO || Surface || m || xy || grid cell mean snow thickness
|-
| ICESOI || Surface || kg m-2 || xy || soil frozen water content
|-
| ISTSFC || Surface || C || xy || snow or ice surface temperature
|-
| ITY || Surface || 1 || xy || vegetation type
|-
| LAI || Surface || 1 || xy || leaf area index
|-
| LCOOL || Surface || 1 || xy || Saunders parameter
|-
| LHFX || Surface || W m-2 || xy || total latent energy flux
|-
| LHLAND || Surface || W m-2 || xy || Latent heat flux land
|-
| LST || Surface || K || xy || land surface skin temperature
|-
| LWI || Surface || 1 || xy || land(1) water(0) ice(2) flag
|-
| LWLAND || Surface || W m-2 || xy || Net longwave land
|-
| LWNDICE || Surface || W m-2 || xy || sea ice net downward longwave flux
|-
| LWNDSRF || Surface || W m-2 || xy || surface net downward longwave flux
|-
| LWNDWTR || Surface || W m-2 || xy || open water net downward longwave flux
|-
| MELTB || Surface || m s-1 || xy || basal ice melt
|-
| MELTL || Surface || m s-1 || xy || lateral ice melt
|-
| MELTS || Surface || m s-1 || xy || snow melt
|-
| MELTT || Surface || m s-1 || xy || top ice melt
|-
| NITY || Surface || 1 || xy || NCEP vegetation type
|-
| PCU || Surface || kg m-2 s-1 || xy || liquid water convective precipitation
|-
| PLS || Surface || kg m-2 s-1 || xy || liquid water large scale precipitation
|-
| Q10M || Surface || kg kg-1 || xy || 10-meter specific humidity
|-
| Q2M || Surface || kg kg-1 || xy || 2-meter specific humidity
|-
| QA || Surface || kg kg-1 || xy || surface air specific humidity
|-
| QCOOL || Surface || W m-2 || xy || net cooling in cool layer
|-
| QDWL || Surface || kg kg-1 || xy || surface liquid condensate
|-
| QFRL || Surface || kg kg-1 || xy || surface ice condensate
|-
| QINFIL || Surface || kg m-2 s-1 || xy || Soil water infiltration rate
|-
| QSTAR || Surface || kg kg-1 || xy || surface moisture scale
|-
| RAINOCN || Surface || kg m-2 s-1 || xy || ocean rainfall
|-
| RE || Surface || 1 || xy || surface reynolds number
|-
| RH2M || Surface || % || xy || near-surface relative humidity
|-
| RH2MMAX || Surface || % || xy || daily maximum near-surface relative humidity
|-
| RH2MMIN || Surface || % || xy || daily minimum near-surface relative humidity
|-
| RI || Surface || 1 || xy || surface bulk richardson number
|-
| ROOTL || Surface || m m-3 || xy || root length
|-
| RUNOFF || Surface || kg m-2 s-1 || xy || runoff flux
|-
| RUNSURF || Surface || kg m-2 s-1 || xy || surface runoff flux
|-
| SALTFLUX || Surface || kg m-2 s-1 || xy || salt flux bw saltwater ocean
|-
| SH || Surface || W m-2 || xy || sensible heat flux from turbulence
|-
| SHAT || Surface || m+2 s-2 || xy || effective surface dry static energy
|-
| SHICE || Surface || W m-2 || xy || sea ice upward sensible heat flux
|-
| SHLAND || Surface || W m-2 || xy || Sensible heat flux land
|-
| SHOUT || Surface || W m-2 || xy || upward sensible heat flux
|-
| SHSNOW || Surface || W m-2 || xy || downward heat flux into snow
|-
| SHWTR || Surface || W m-2 || xy || open water upward sensible heat flux
|-
| SMELT || Surface || kg m-2 s-1 || xy || snowmelt flux
|-
| SMLAND || Surface || kg m-2 s-1 || xy || Snowmelt flux land
|-
| SNO || Surface || kg m-2 s-1 || xy || snowfall
|-
| SNOICE || Surface || m s-1 || xy || snow-ice formation
|-
| SNOMAS || Surface || kg m-2 || xy || snow mass
|-
| SNOWDP || Surface || m || xy || snow depth
|-
| SNOWOCN || Surface || kg m-2 s-1 || xy || ocean snowfall
|-
| SPLAND || Surface || W m-2 || xy || rate of spurious land energy source
|-
| SPSNOW || Surface || W m-2 || xy || rate of spurious snow energy
|-
| SPWATR || Surface || kg m-2 s-1 || xy || rate of spurious land water source
|-
| SSKINW || Surface || psu || xy || sea skin layer salinity
|-
| SUBLIM || Surface || kg m-2 s-1 || xy || sublimation
|-
| SWCOOL || Surface || W m-2 || xy || solar heating in cool layer
|-
| SWLAND || Surface || W m-2 || xy || Net shortwave land
|-
| SWNDICE || Surface || W m-2 || xy || sea ice net downward shortwave flux
|-
| SWNDSRF || Surface || W m-2 || xy || surface net downward shortwave flux
|-
| SWNDWTR || Surface || W m-2 || xy || open water net downward shortwave flux
|-
| T10M || Surface || K || xy || 10-meter air temperature
|-
| T2M || Surface || K || xy || 2-meter air temperature
|-
| T2MMAX || Surface || K || xy || daily maximum near-surface air temperature
|-
| T2MMIN || Surface || K || xy || daily minimum near-surface air temperature
|-
| TA || Surface || K || xy || surface air temperature
|-
| TAUX || Surface || N m-2 || xy || eastward surface stress
|-
| TAUXI || Surface || N m-2 || xy || eastward stress over ice
|-
| TAUXW || Surface || N m-2 || xy || eastward stress over water
|-
| TAUY || Surface || N m-2 || xy || northward surface stress
|-
| TAUYI || Surface || N m-2 || xy || northward stress over ice
|-
| TAUYW || Surface || N m-2 || xy || northward stress over water
|-
| TBAR || Surface || K || xy || mean temperature of interface layer
|-
| TDEL || Surface || K || xy || temperature at base of cool layer
|-
| TDROP || Surface || K || xy || temperature drop across cool layer
|-
| TELAND || Surface || J m-2 || xy || Total energy storage land
|-
| TPSAT || Surface || K || xy || surface temperature of saturated zone
|-
| TPSNOW || Surface || K || xy || surface temperature of snow
|-
| TPSURF || Surface || K || xy || surface temperature of land incl snow
|-
| TPUNST || Surface || K || xy || surface temperature of unsaturated zone
|-
| TPWLT || Surface || K || xy || surface temperature of wilted zone
|-
| TSKINW || Surface || K || xy || open water skin temperature
|-
| TSKINWCICE || Surface || K || xy || CICE water skin temperature
|-
| TSLAND || Surface || kg m-2 || xy || Total snow storage land
|-
| TSOIL1 || Surface || K || xy || soil temperatures layer 1
|-
| TSOIL2 || Surface || K || xy || soil temperatures layer 2
|-
| TSOIL3 || Surface || K || xy || soil temperatures layer 3
|-
| TSOIL4 || Surface || K || xy || soil temperatures layer 4
|-
| TSOIL5 || Surface || K || xy || soil temperatures layer 5
|-
| TSOIL6 || Surface || K || xy || soil temperatures layer 6
|-
| TSTAR || Surface || K || xy || surface temperature scale
|-
| TS_FOUND || Surface || K || xy || foundation temperature for interface layer
|-
| TWLAND || Surface || kg m-2 || xy || Avail water storage land
|-
| U10M || Surface || m s-1 || xy || 10-meter eastward wind
|-
| U10N || Surface || m s-1 || xy || equivalent neutral 10-meter eastward wind
|-
| U2M || Surface || m s-1 || xy || 2-meter eastward wind
|-
| U50M || Surface || m s-1 || xy || 50-meter eastward wind
|-
| UA || Surface || m s-1 || xy || surface eastward wind
|-
| UCOOL || Surface || m s-1 || xy || ustarw at cool layer
|-
| USTAR || Surface || m s-1 || xy || surface velocity scale
|-
| USTARI || Surface || m s-1 || xy || ice ocean friction velocity
|-
| UU10M || Surface || m s-1 || xy || near-surface wind speed
|-
| UU10MMAX || Surface || m s-1 || xy || daily maximum near-surface wind speed
|-
| V10M || Surface || m s-1 || xy || 10-meter northward wind
|-
| V10N || Surface || m s-1 || xy || equivalent neutral 10-meter northward wind
|-
| V2M || Surface || m s-1 || xy || 2-meter northward wind
|-
| V50M || Surface || m s-1 || xy || 50-meter northward wind
|-
| VA || Surface || m s-1 || xy || surface northward wind
|-
| VENT || Surface || m s-1 || xy || surface ventilation velocity
|-
| WAT10CM || Surface || kg m-2 || xy || soil moisture in Upper 10cm
|-
| WATERFLUX || Surface || kg m-2 s-1 || xy || FRESHWATER flux bw saltwater ocean
|-
| WATSOI || Surface || kg m-2 || xy || total soil moisture
|-
| WCPR || Surface || m-3 m-3 || xy || water profile
|-
| WCRZ || Surface || m-3 m-3 || xy || water root zone
|-
| WCSF || Surface || m-3 m-3 || xy || water surface layer
|-
| WESNN1 || Surface || kg m-2 || xy || snow mass layer 1
|-
| WESNN2 || Surface || kg m-2 || xy || snow mass layer 2
|-
| WESNN3 || Surface || kg m-2 || xy || snow mass layer 3
|-
| WET1 || Surface || 1 || xy || surface soil wetness
|-
| WET2 || Surface || 1 || xy || root zone soil wetness
|-
| WET3 || Surface || 1 || xy || ave prof soil moisture
|-
| Z0 || Surface || m || xy || surface roughness
|-
| Z0H || Surface || m || xy || surface roughness for heat
|-
| Z2CH || Surface || m || xy || canopy height
|-
| AKQODT || Turbulence || 1 || xyz || matrix diagonal ak for moisture over dt
|-
| AKSODT || Turbulence || 1 || xyz || matrix diagonal ak for scalars over dt
|-
| AKVODT || Turbulence || 1 || xyz || matrix diagonal ak for winds over dt
|-
| ALH || Turbulence || m || xyz || Blackadar length scale for scalars
|-
| CHIS || Turbulence || 1 || xy || optimal mixture fraction for BRV
|-
| CKQODT || Turbulence || 1 || xyz || matrix diagonal ck for moisture over dt
|-
| CKSODT || Turbulence || 1 || xyz || matrix diagonal ck for scalars over dt
|-
| CKVODT || Turbulence || 1 || xyz || matrix diagonal ck for winds over dt
|-
| CLDRF || Turbulence || W m-2 || xy || cloud top radiative forcing
|-
| DBUOY || Turbulence || m s-2 || xy || Buoyancy jump across inversion
|-
| DELSINV || Turbulence || K || xy || Scaled Del s at Cloud top
|-
| DFSTAR || Turbulence || kg m-2 s-1 || xy || change of surface fluxes for unit change of surface value
|-
| DSIEMS || Turbulence || 1 || xy || Siems buoy rev parameter
|-
| DU || Turbulence || s-1 || xyz || bulk shear from Louis
|-
| EKH || Turbulence || m+2 s-1 || xyz || entrainment heat diffusivity from Lock
|-
| EKM || Turbulence || m+2 s-1 || xyz || entrainment momentum diffusivity from Lock
|-
| FSTAR || Turbulence || X kg m-2 s-1 || xy || surface fluxes
|-
| INTDIS || Turbulence || K s-1 Pa || xyz || p-weighted frictional heating rate from diffusion
|-
| KEINT || Turbulence || W m-2 || xy || vertically integrated kinetic energy dissipation due to diffusion
|-
| KERAD || Turbulence || m+2 s-1 || xy || turbulent entrainment diff from cooling
|-
| KESRF || Turbulence || W m-2 || xy || vertically integrated kinetic energy dissipation due to surface friction
|-
| KETOP || Turbulence || W m-2 || xy || vertically integrated kinetic energy dissipation due to topographic friction
|-
| KETRB || Turbulence || W m-2 || xy || vertically integrated kinetic energy tendency across turbulence
|-
| KH || Turbulence || m+2 s-1 || xyz || total scalar diffusivity
|-
| KHLS || Turbulence || m+2 s-1 || xyz || scalar diffusivity from Louis
|-
| KHRAD || Turbulence || m+2 s-1 || xyz || radiation driven scalar diffusivity from Lock scheme
|-
| KHSFC || Turbulence || m+2 s-1 || xyz || surface driven scalar diffusivity from Lock scheme
|-
| KM || Turbulence || m+2 s-1 || xyz || total momentum diffusivity
|-
| KMLS || Turbulence || m+2 s-1 || xyz || momentum diffusivity from Louis
|-
| LWCRT || Turbulence || K s-1 || xyz || cloudy LW radiation tendency used by Lock scheme
|-
| PPBL || Turbulence || Pa || xy || pbltop pressure
|-
| QV || Turbulence || kg kg-1 || xyz || specific humidity
|-
| RADRCODE || Turbulence || 1 || xy || Return codes for Lock top driven plume
|-
| RI || Turbulence || 1 || xyz || Richardson number from Louis
|-
| SMIXT || Turbulence || J kg-1 || xy || s of optimal mixture for BRV
|-
| SRFDIS || Turbulence || K s-1 Pa || xy || p-weighted frictional heating rate from surface drag
|-
| T || Turbulence || K || xyz || air temperature
|-
| TCZPBL || Turbulence || m || xy || transcom planetary boundary layer height
|-
| TOPDIS || Turbulence || K s-1 Pa || xyz || p-weighted frictional heating rate from orographic drag
|-
| TRI || Turbulence || X kg m-2 s-1 || xyz || diffusion tendencies
|-
| U || Turbulence || m s-1 || xyz || eastward wind
|-
| V || Turbulence || m s-1 || xyz || northward wind
|-
| VSCBRV || Turbulence || m s-1 || xy || turbulent velocity scale for buoy rev
|-
| VSCRAD || Turbulence || m s-1 || xy || turbulent velocity scale for cooling
|-
| VSCSFC || Turbulence || m s-1 || xy || turbulent velocity scale for sfc
|-
| WEBRV || Turbulence || m s-1 || xy || entrainment velocity from buoy rev
|-
| WERAD || Turbulence || m s-1 || xy || entrainment velocity from radiation
|-
| WESFC || Turbulence || m s-1 || xy || entrainment velocity from surface plume
|-
| ZCLD || Turbulence || m || xy || pbltop cloud depth LOCK
|-
| ZCLDTOP || Turbulence || m || xy || pbltop cloud top height LOCK
|-
| ZRADBS || Turbulence || m || xy || hght of base for radbrv plume LOCK
|-
| ZRADML || Turbulence || m || xy || depth for radbrv plume LOCK
|-
| ZSML || Turbulence || m || xy || pbltop height for sfc plume LOCK
|-
| GRN || Vegdyn || 1 || tile || greeness fraction
|-
| LAI || Vegdyn || 1 || tile || leaf area index
|-
| ROOTL || Vegdyn || m+2 || tile || root length density
|-
| Z2CH || Vegdyn || m || tile || canopy height
|-
| DO3DT || mkiau || ppmv || xyz || ozone analysis increment
|-
| DPEDT || mkiau || Pa || xyz || edge pressure analysis increment
|-
| DQVDT || mkiau || kg kg-1 || xyz || specific humidity analysis increment
|-
| DTDT || mkiau || K || xyz || temperature analysis increment
|-
| DTSDT || mkiau || K || xy || skin temparature increment
|-
| DUDT || mkiau || m s-1 || xyz || eastward wind analysis increment
|-
| DVDT || mkiau || m s-1 || xyz || northward wind analysis increment
|}
 
 
__FORCETOC__
===Internal States===
 
Sorted 480 states by Component name - within each component, variables are sorted by their short name
{| class="wikitable"
|+ List of GEOS-5 [IN] State variables
! Name !! Component !! Units !! Dim !! Long name
|-
| AK || ARIESg3 || Pa || z || hybrid sigma pressure a
|-
| BK || ARIESg3 || 1 || z || hybrid sigma pressure b
|-
| PE || ARIESg3 || Pa || xyz || air pressure
|-
| PKZ || ARIESg3 || Pa$^\kappa$ || xyz || pressure to kappa
|-
| PT || ARIESg3 || K Pa$^{-\kappa}$ || xyz || scaled potential temperature
|-
| U || ARIESg3 || m s-1 || xyz || eastward wind
|-
| V || ARIESg3 || m s-1 || xyz || northward wind
|-
| DO3DT || Agcm || ppmv s-1 || xyz || ozone bias tendency
|-
| DPEDT || Agcm || Pa s-1 || xyz || edge pressure bias tendency
|-
| DQVDT || Agcm || kg kg-1 s-1 || xyz || specific humidity bias tendency
|-
| DTDT || Agcm || K s-1 || xyz || temperature bias tendency
|-
| DTSDT || Agcm || K s-1 || xy || skin temperature tendency
|-
| DUDT || Agcm || m s-2 || xyz || eastward wind bias tendency
|-
| DVDT || Agcm || m s-2 || xyz || northward wind bias tendency
|-
| UNKNOWN || CARMAchem || kgkg || xyz || UNKNOWN
|-
| UNKNOWN || CARMAchem || kgkg || xyz || UNKNOWN
|-
| UNKNOWN || CARMAchem || K || xyz || UNKNOWN
|-
| UNKNOWN || CARMAchem || kgkg || xyz || UNKNOWN
|-
| UNKNOWN || CARMAchem || 1 || xyz || UNKNOWN
|-
| UNKNOWN || CARMAchem || 1 || xyz || UNKNOWN
|-
| ARA1 || Catch || m+2 kg-1 || tile || shape param 1
|-
| ARA2 || Catch || 1 || tile || shape param 2
|-
| ARA3 || Catch || m+2 kg-1 || tile || shape param 3
|-
| ARA4 || Catch || 1 || tile || shape param 4
|-
| ARS1 || Catch || m+2 kg-1 || tile || wetness param 1
|-
| ARS2 || Catch || m+2 kg-1 || tile || wetness param 2
|-
| ARS3 || Catch || m+4 kg-2 || tile || wetness param 3
|-
| ARW1 || Catch || m+2 kg-1 || tile || min theta param 1
|-
| ARW2 || Catch || m+2 kg-1 || tile || min theta param 2
|-
| ARW3 || Catch || m+4 kg-2 || tile || min theta param 3
|-
| ARW4 || Catch || 1 || tile || min theta param 4
|-
| ATAU || Catch || 1 || tile || water transfer param 5
|-
| BEE || Catch || 1 || tile || clapp hornberger b
|-
| BF1 || Catch || kg m-4 || tile || topo baseflow param 1
|-
| BF2 || Catch || m || tile || topo baseflow param 2
|-
| BF3 || Catch || log(m) || tile || topo baseflow param 3
|-
| BTAU || Catch || 1 || tile || water transfer param 6
|-
| CAPAC || Catch || kg m-2 || tile || interception reservoir capac
|-
| CATDEF || Catch || kg m-2 || tile || catchment deficit
|-
| CDCR1 || Catch || kg m-2 || tile || moisture threshold
|-
| CDCR2 || Catch || kg m-2 || tile || max water content
|-
| CH || Catch || kg m-2 s-1 || tile2 || surface heat exchange coefficient
|-
| CM || Catch || kg m-2 s-1 || tile2 || surface momentum exchange coefficient
|-
| COND || Catch || m s-1 || tile || sfc sat hydraulic conduct
|-
| CQ || Catch || kg m-2 s-1 || tile2 || surface moisture exchange coffiecient
|-
| FR || Catch || 1 || tile2 || subtile fractions
|-
| GHTCNT1 || Catch || J m-2 || tile || soil heat content layer 1
|-
| GHTCNT2 || Catch || J_m-2 || tile || soil heat content layer 2
|-
| GHTCNT3 || Catch || J m-2 || tile || soil heat content layer 3
|-
| GHTCNT4 || Catch || J m-2 || tile || soil heat content layer 4
|-
| GHTCNT5 || Catch || J m-2 || tile || soil heat content layer 5
|-
| GHTCNT6 || Catch || J m-2 || tile || soil heat content layer 6
|-
| GNU || Catch || m-1 || tile || vertical transmissivity
|-
| HTSNNN1 || Catch || J m-2 || tile || heat content snow layer 1
|-
| HTSNNN2 || Catch || J m-2 || tile || heat content snow layer 2
|-
| HTSNNN3 || Catch || J m-2 || tile || heat content snow layer 3
|-
| OLD_ITY || Catch || 1 || tile || Placeholder. Used to be vegetation type.
|-
| POROS || Catch || 1 || tile || soil porosity
|-
| PSIS || Catch || m || tile || saturated matric potential
|-
| QC || Catch || kg kg-1 || tile2 || canopy specific humidity
|-
| RZEXC || Catch || kg m-2 || tile || root zone excess
|-
| SNDZN1 || Catch || m || tile || snow depth layer 1
|-
| SNDZN2 || Catch || m || tile || snow depth layer 2
|-
| SNDZN3 || Catch || m || tile || snow depth layer 3
|-
| SRFEXC || Catch || kg m-2 || tile || surface excess
|-
| TC || Catch || K || tile2 || canopy temperature
|-
| TSA1 || Catch || 1 || tile || water transfer param 1
|-
| TSA2 || Catch || 1 || tile || water transfer param 2
|-
| TSB1 || Catch || 1 || tile || water transfer param 3
|-
| TSB2 || Catch || 1 || tile || water transfer param 4
|-
| TSURF || Catch || K || tile || mean catchment temp incl snw
|-
| VGWMAX || Catch || kg m-2 || tile || max rootzone water content
|-
| WESNN1 || Catch || kg m-2 || tile || snow mass layer 1
|-
| WESNN2 || Catch || kg m-2 || tile || snow mass layer 2
|-
| WESNN3 || Catch || kg m-2 || tile || snow mass layer 3
|-
| WPWET || Catch || 1 || tile || wetness at wilting point
|-
| WW || Catch || m+2 s-2 || tile2 || vertical velocity scale squared
|-
| CHEM_TRACERS || Chem || X ||  || chemistry friendly tracers
|-
| OX || DFI || ppmv || xyz || molecular oxigen
|-
| PE || DFI || Pa || xyz || air pressure
|-
| PT || DFI || K Pa$^{-\kappa}$ || xyz || scaled potential temperature
|-
| Q || DFI || kg kg^${-1}$ || xyz || specific humidity
|-
| U_DGRID || DFI || m s-1 || xyz || eastward wind
|-
| V_DGRID || DFI || m s-1 || xyz || northward wind
|-
| OM || DatmoDyn || Pas || xyz || pressure velocity
|-
| PLE || DatmoDyn || Pascals || xyz || Pressure at the edges
|-
| PREF || DatmoDyn || Pa || z || reference air pressure
|-
| T || DatmoDyn || K || xyz || air temperature
|-
| U || DatmoDyn || ms || xyz || Zonal wind
|-
| V || DatmoDyn || ms || xyz || meridional wind
|-
| AK || DynCore || Pa || z || hybrid sigma pressure a
|-
| BK || DynCore || 1 || z || hybrid sigma pressure b
|-
| DZ || DynCore || m || xyz || height thickness
|-
| PE || DynCore || Pa || xyz || air pressure
|-
| PKZ || DynCore || Pa$^\kappa$ || xyz || pressure to kappa
|-
| PT || DynCore || K Pa$^{-\kappa}$ || xyz || scaled potential temperature
|-
| U || DynCore || m s-1 || xyz || eastward wind
|-
| V || DynCore || m s-1 || xyz || northward wind
|-
| W || DynCore || m s-1 || xyz || vertical velocity
|-
| AK || FVdycore || Pa || z || hybrid sigma pressure a
|-
| BK || FVdycore || 1 || z || hybrid sigma pressure b
|-
| PE || FVdycore || Pa || xyz || air pressure
|-
| PKZ || FVdycore || Pa$^\kappa$ || xyz || pressure to kappa
|-
| PT || FVdycore || K Pa$^{-\kappa}$ || xyz || scaled potential temperature
|-
| U || FVdycore || m s-1 || xyz || eastward wind
|-
| V || FVdycore || m s-1 || xyz || northward wind
|-
| A3O2 || GMICHEM || mol mol-1 || xyz || Primary RO2 (C3H7O2) from propane
|-
| ACET || GMICHEM || mol mol-1 || xyz || Acetone
|-
| ACTA || GMICHEM || mol mol-1 || xyz || Acetic acid (C2H4O2)
|-
| ALD2 || GMICHEM || mol mol-1 || xyz || Acetaldehyde (C2H4O)
|-
| ALK4 || GMICHEM || mol mol-1 || xyz || C45 alkanes (C4H10)
|-
| AOADAYS || GMICHEM || days || xyz || Age-of-air
|-
| ATO2 || GMICHEM || mol mol-1 || xyz || RO2 from acetone (C3H6O3)
|-
| B3O2 || GMICHEM || mol mol-1 || xyz || Secondary RO2 (C3H7O2) from propane
|-
| Br || GMICHEM || mol mol-1 || xyz || Ground state atomic bromine (2P32)
|-
| BrCl || GMICHEM || mol mol-1 || xyz || Bromine chloride
|-
| BrO || GMICHEM || mol mol-1 || xyz || Bromine monoxide radical
|-
| BrONO2 || GMICHEM || mol mol-1 || xyz || Bromine nitrate
|-
| C2H6 || GMICHEM || mol mol-1 || xyz || Ethane
|-
| C3H8 || GMICHEM || mol mol-1 || xyz || Propane
|-
| CCl4 || GMICHEM || mol mol-1 || xyz || Carbon tetrachloride
|-
| CF2Br2 || GMICHEM || mol mol-1 || xyz || Halon 1202
|-
| CF2ClBr || GMICHEM || mol mol-1 || xyz || Halon 1211
|-
| CF3Br || GMICHEM || mol mol-1 || xyz || Halon 1301
|-
| CFC11 || GMICHEM || mol mol-1 || xyz || CFC11 (CFCl3)
|-
| CFC113 || GMICHEM || mol mol-1 || xyz || CFC113 (C2Cl3F3)
|-
| CFC114 || GMICHEM || mol mol-1 || xyz || CFC114 (C2Cl2F4)
|-
| CFC115 || GMICHEM || mol mol-1 || xyz || CFC115 (C2ClF5)
|-
| CFC12 || GMICHEM || mol mol-1 || xyz || CFC12 (CF2Cl2)
|-
| CH2O || GMICHEM || mol mol-1 || xyz || Formaldehyde
|-
| CH3Br || GMICHEM || mol mol-1 || xyz || Methyl bromide
|-
| CH3CCl3 || GMICHEM || mol mol-1 || xyz || Methyl chloroform
|-
| CH3Cl || GMICHEM || mol mol-1 || xyz || Methyl chloride
|-
| CH4 || GMICHEM || mol mol-1 || xyz || Methane
|-
| CO || GMICHEM || mol mol-1 || xyz || Carbon monoxyde
|-
| Cl || GMICHEM || mol mol-1 || xyz || Ground state atomic chlorine (2P32)
|-
| Cl2 || GMICHEM || mol mol-1 || xyz || Molecular chlorine
|-
| Cl2O2 || GMICHEM || mol mol-1 || xyz || Chlorine peroxide
|-
| ClO || GMICHEM || mol mol-1 || xyz || Chlorine monoxide radical
|-
| ClONO2 || GMICHEM || mol mol-1 || xyz || Chlorine nitrate
|-
| EOH || GMICHEM || mol mol-1 || xyz || Ethanol
|-
| ETO2 || GMICHEM || mol mol-1 || xyz || Ethylperoxy radical (C2H5O2)
|-
| ETP || GMICHEM || mol mol-1 || xyz || Ethylhydroperoxide
|-
| GCO3 || GMICHEM || mol mol-1 || xyz || Hydroxy peroxyacetyl radical (C2H3O4)
|-
| GLYC || GMICHEM || mol mol-1 || xyz || Glycoaldehyde (Hydroxyacetaldehyde C2H4O2)
|-
| GLYX || GMICHEM || mol mol-1 || xyz || Glyoxal (2CHO)
|-
| GP || GMICHEM || mol mol-1 || xyz || Peroxide (C2H4O4) from GCO3
|-
| GPAN || GMICHEM || mol mol-1 || xyz || Peroxyacylnitrate (C2H3O6)
|-
| H || GMICHEM || mol mol-1 || xyz || Ground state atomic hydrogen (2S)
|-
| H2 || GMICHEM || mol mol-1 || xyz || Molecular hydrogen
|-
| H2402 || GMICHEM || mol mol-1 || xyz || Halon 24O2 (C2Br2F4)
|-
| H2O2 || GMICHEM || mol mol-1 || xyz || Hydrogen peroxide
|-
| HAC || GMICHEM || mol mol-1 || xyz || Hydroxyacetone (C3H6O2)
|-
| HBr || GMICHEM || mol mol-1 || xyz || Hydrogen bromide
|-
| HCFC141b || GMICHEM || mol mol-1 || xyz || HCFC141b (C2Cl2FH3)
|-
| HCFC142b || GMICHEM || mol mol-1 || xyz || HCFC142b (C2ClF2H3)
|-
| HCFC22 || GMICHEM || mol mol-1 || xyz || HCFC22 (CClF2H)
|-
| HCOOH || GMICHEM || mol mol-1 || xyz || Formic acid (CH3O2)
|-
| HCl || GMICHEM || mol mol-1 || xyz || Hydrochloric acid
|-
| HNO2 || GMICHEM || mol mol-1 || xyz || Nitrous acid
|-
| HNO3 || GMICHEM || mol mol-1 || xyz || Nitric acid
|-
| HNO3COND || GMICHEM || mol mol-1 || xyz || Condensed nitric acid
|-
| HNO4 || GMICHEM || mol mol-1 || xyz || Pernitric acid
|-
| HO2 || GMICHEM || mol mol-1 || xyz || Perhydroxyl radical
|-
| HOBr || GMICHEM || mol mol-1 || xyz || Hypobromous acid
|-
| HOCl || GMICHEM || mol mol-1 || xyz || Hypochlorous acid
|-
| IALD || GMICHEM || mol mol-1 || xyz || Hydroxy carbonyl alkenes (C5H8O2) from isoprene
|-
| IAO2 || GMICHEM || mol mol-1 || xyz || RO2 (C5H9O8) from isoprene oxidation products
|-
| IAP || GMICHEM || mol mol-1 || xyz || Peroxide (C5H10O5) from IAO2
|-
| INO2 || GMICHEM || mol mol-1 || xyz || RO2 (C5H8O3N) from ISOP+NO3
|-
| INPN || GMICHEM || mol mol-1 || xyz || Peroxide (C5H8O6N2) from INO2
|-
| ISN1 || GMICHEM || mol mol-1 || xyz || RO2 (C4H7O4N) from ISN2
|-
| ISNP || GMICHEM || mol mol-1 || xyz || Peroxide (C4H7O4N) from ISN1
|-
| ISOP || GMICHEM || mol mol-1 || xyz || Isoprene
|-
| KO2 || GMICHEM || mol mol-1 || xyz || RO2 (C4H7O3) from C3 ketones
|-
| MACR || GMICHEM || mol mol-1 || xyz || Methacrolein (C4H6O)
|-
| MAN2 || GMICHEM || mol mol-1 || xyz || RO2 (C4H6O6N) from MACR+NO3
|-
| MAO3 || GMICHEM || mol mol-1 || xyz || Peroxyacyl (C4H5O3) from MVK+MACR
|-
| MAOP || GMICHEM || mol mol-1 || xyz || Peroxide (C4H6O3) from MAO3
|-
| MAP || GMICHEM || mol mol-1 || xyz || Peroxyacetic acid (C2H4O3)
|-
| MCO3 || GMICHEM || mol mol-1 || xyz || Peroxyacetyl radical (C2H3O3)
|-
| MEK || GMICHEM || mol mol-1 || xyz || Methyl ethyl ketone (C4H8O)
|-
| MGLY || GMICHEM || mol mol-1 || xyz || Methylglyoxal (C3H4O2)
|-
| MO2 || GMICHEM || mol mol-1 || xyz || Methylperoxy radical (CH3O2)
|-
| MOH || GMICHEM || mol mol-1 || xyz || Methanol
|-
| MP || GMICHEM || mol mol-1 || xyz || Methyl hydroperoxide
|-
| MRO2 || GMICHEM || mol mol-1 || xyz || RO2 (C4H7O4) from MACR+OH
|-
| MRP || GMICHEM || mol mol-1 || xyz || Peroxide (C4H8O4) from MRO2
|-
| MVK || GMICHEM || mol mol-1 || xyz || Methyl vinyl ketone (C4H6O)
|-
| MVN2 || GMICHEM || mol mol-1 || xyz || C4H6O4N
|-
| N || GMICHEM || mol mol-1 || xyz || Ground state atomic nitrogen
|-
| N2 || GMICHEM || m^-3 || xyz || Molecular nitrogen
|-
| N2O || GMICHEM || mol mol-1 || xyz || Nitrous oxide
|-
| N2O5 || GMICHEM || mol mol-1 || xyz || Dinitrogen pentoxide
|-
| NO || GMICHEM || mol mol-1 || xyz || Nitric oxide
|-
| NO2 || GMICHEM || mol mol-1 || xyz || Nitrogen dioxide
|-
| NO3 || GMICHEM || mol mol-1 || xyz || Nitrogen trixide
|-
| NUMDENS || GMICHEM || m^-3 || xyz || Total number density
|-
| O || GMICHEM || mol mol-1 || xyz || Ground state atomic oxygen (3P)
|-
| O1D || GMICHEM || mol mol-1 || xyz || First excited state of atomic oxygen (1D)
|-
| O2 || GMICHEM || m^-3 || xyz || Molecular oxygen
|-
| OClO || GMICHEM || mol mol-1 || xyz || Symmetrical chlorine dioxide
|-
| OH || GMICHEM || mol mol-1 || xyz || Hydroxyl radical
|-
| OX || GMICHEM || mol mol-1 || xyz || Ozone
|-
| PAN || GMICHEM || mol mol-1 || xyz || Peroxyacetyl nitrate (C2H3NO5)
|-
| PMN || GMICHEM || mol mol-1 || xyz || Peroxymethacryloyl nitrate (C4H5O5N)
|-
| PO2 || GMICHEM || mol mol-1 || xyz || RO2 (C3H7O3) from propene
|-
| PP || GMICHEM || mol mol-1 || xyz || Peroxide (C3H8O3) from PO2
|-
| PPN || GMICHEM || mol mol-1 || xyz || Prexypropionyl nitrate (C3H5O5N)
|-
| PRN1 || GMICHEM || mol mol-1 || xyz || RO2 (C3H5O5N) from propene+NO3
|-
| PRPE || GMICHEM || mol mol-1 || xyz || Propene (C3H6)
|-
| PRPN || GMICHEM || mol mol-1 || xyz || Peroxide (C3H6O3N) from PRN1
|-
| R4N1 || GMICHEM || mol mol-1 || xyz || RO2 (C4H9O3N) from R4N2
|-
| R4N2 || GMICHEM || mol mol-1 || xyz || C4-C5 alkylnitrates (C4H9O3N)
|-
| R4O2 || GMICHEM || mol mol-1 || xyz || RO2 (C4H9O2) from ALK4
|-
| R4P || GMICHEM || mol mol-1 || xyz || Peroxide (C4H10O2) from R4O2
|-
| RA3P || GMICHEM || mol mol-1 || xyz || Peroxypropyl alcohol (C3H8O2) from A3O2
|-
| RB3P || GMICHEM || mol mol-1 || xyz || Peroxide from B3O2
|-
| RCHO || GMICHEM || mol mol-1 || xyz || C2 aldehydes (C3H6O)
|-
| RCO3 || GMICHEM || mol mol-1 || xyz || Peroxypropionyl radical (C3H5O3)
|-
| RCOOH || GMICHEM || mol mol-1 || xyz || C2 organic acids
|-
| RIO1 || GMICHEM || mol mol-1 || xyz || RO2 (C5H9O3) from isoprene oxidation products
|-
| RIO2 || GMICHEM || mol mol-1 || xyz || RO2 (C5H9O3) from isoprene
|-
| RIP || GMICHEM || mol mol-1 || xyz || Peroxide (C5H10O3) from RIO2
|-
| ROH || GMICHEM || mol mol-1 || xyz || C2 alcohols
|-
| RP || GMICHEM || mol mol-1 || xyz || Methacrolein peroxy acid (C4H6O3)
|-
| T2M15d || GMICHEM || K || xyz || Daily averages of T2M
|-
| VRO2 || GMICHEM || mol mol-1 || xyz || RO2 (C4H7O4) from MVK+OH
|-
| VRP || GMICHEM || mol mol-1 || xyz || Peroxide (C4H8O4) from VRO2
|-
| UNKNOWN || GMIchem || UNKNOWN || xyz || UNKNOWN
|-
| UNKNOWN || GMIchem || UNKNOWN || xyz || UNKNOWN
|-
| UNKNOWN || GOCART || r%vunits(n) || xyz || r%vtitle(n)
|-
| DO3DT || IAU || ppmv || xyz || ozone analysis increment
|-
| DPEDT || IAU || Pa || xyz || edge pressure analysis increment
|-
| DQVDT || IAU || kg kg-1 || xyz || specific humidity analysis increment
|-
| DTDT || IAU || K || xyz || temperature analysis increment
|-
| DTSDT || IAU || K || xy || skin temparature increment
|-
| DUDT || IAU || m s-1 || xyz || eastward wind analysis increment
|-
| DVDT || IAU || m s-1 || xyz || northward wind analysis increment
|-
| DFDTS || Irrad || W m-2 K-1 || xyz || sensitivity of net downward longwave flux in air to surface temperature
|-
| DFDTSC || Irrad || W m-2 K-1 || xyz || sensitivity of net downward longwave flux in air to surface temperature for clear sky
|-
| FLA || Irrad || W m-2 || xyz || net downward longwave flux in air for clear sky and no aerosol
|-
| FLAD || Irrad || W m-2 || xyz || downward longwave flux in air for clear sky and no aerosol
|-
| FLAU || Irrad || W m-2 || xyz || upward longwave flux in air for clear sky and no aerosol
|-
| FLC || Irrad || W m-2 || xyz || net downward longwave flux in air for clear sky(INTERNAL)
|-
| FLCD || Irrad || W m-2 || xyz || downward longwave flux in air for clear sky
|-
| FLCU || Irrad || W m-2 || xyz || upward longwave flux in air for clear sky
|-
| FLX || Irrad || W m-2 || xyz || net downward longwave flux in air
|-
| FLXD || Irrad || W m-2 || xyz || downward longwave flux in air
|-
| FLXU || Irrad || W m-2 || xyz || upward longwave flux in air
|-
| SFCEM || Irrad || W m-2 || xy || longwave flux emitted from surface
|-
| TS || Irrad || K || xy || surface temperature
|-
| CH || Lake || kg m-2 s-1 || tile2 || surface heat exchange coefficient
|-
| CM || Lake || kg m-2 s-1 || tile2 || surface momentum exchange coefficient
|-
| CQ || Lake || kg m-2 s-1 || tile2 || surface moisture exchange coefficient
|-
| FR || Lake || 1 || tile2 || ice fraction
|-
| QS || Lake || kg kg-1 || tile2 || surface specific humidity
|-
| TS || Lake || K || tile2 || surface skin temperature
|-
| CH || Landice || kg m-2 s-1 || tile || surface heat exchange coefficient
|-
| CM || Landice || kg m-2 s-1 || tile || surface momentum exchange coefficient
|-
| CQ || Landice || kg m-2 s-1 || tile || surface moisture exchange coefficient
|-
| FR || Landice || 1 || tile || ice fraction
|-
| HTSN || Landice || J m-2 || tile || snow layer heat content
|-
| QS || Landice || kg kg-1 || tile || surface specific humidity
|-
| SNDZ || Landice || m || tile || snow layer depth
|-
| TICE || Landice || k || tile || ice layer temperature
|-
| TS || Landice || K || tile || surface skin temperature
|-
| WESN || Landice || kg m-2 || tile || snow layer mass
|-
| AMM_A_ACC || MAMchem || kgkg || xyz || ammonium mass mixing ratio (accumulation mode  interstitial)
|-
| AMM_A_AIT || MAMchem || kgkg || xyz || ammonium mass mixing ratio (aitken mode  interstitial)
|-
| AMM_A_CDU || MAMchem || kgkg || xyz || ammonium mass mixing ratio (coarse dust mode interstitial)
|-
| AMM_A_CSS || MAMchem || kgkg || xyz || ammonium mass mixing ratio (coarse seasalt mode interstitial)
|-
| AMM_A_FDU || MAMchem || kgkg || xyz || ammonium mass mixing ratio (fine dust mode interstitial)
|-
| AMM_A_FSS || MAMchem || kgkg || xyz || ammonium mass mixing ratio (fine seasalt mode interstitial)
|-
| AMM_C_ACC || MAMchem || kgkg || xyz || ammonium mass mixing ratio (accumulation mode  cloud-borne)
|-
| AMM_C_AIT || MAMchem || kgkg || xyz || ammonium mass mixing ratio (aitken mode  cloud-borne)
|-
| AMM_C_CDU || MAMchem || kgkg || xyz || ammonium mass mixing ratio (coarse dust mode cloud-borne)
|-
| AMM_C_CSS || MAMchem || kgkg || xyz || ammonium mass mixing ratio (coarse seasalt mode cloud-borne)
|-
| AMM_C_FDU || MAMchem || kgkg || xyz || ammonium mass mixing ratio (fine dust mode cloud-borne)
|-
| AMM_C_FSS || MAMchem || kgkg || xyz || ammonium mass mixing ratio (fine seasalt mode cloud-borne)
|-
| BC_A_ACC || MAMchem || kgkg || xyz || black carbon mass mixing ratio (accumulation mode interstitial)
|-
| BC_A_PCM || MAMchem || kgkg || xyz || black carbon mass mixing ratio (primary carbon mode interstitial)
|-
| BC_C_ACC || MAMchem || kgkg || xyz || black carbon mass mixing ratio (accumulation mode cloud-borne)
|-
| BC_C_PCM || MAMchem || kgkg || xyz || black carbon mass mixing ratio (primary carbon mode cloud-borne)
|-
| DGN_DRY_ACC || MAMchem || m || xyz || dry geometric mean diameter of accumulation mode number size distribution
|-
| DGN_DRY_AIT || MAMchem || m || xyz || dry geometric mean diameter of aitken mode number size distribution
|-
| DGN_DRY_CDU || MAMchem || m || xyz || dry geometric mean diameter of coarse dust mode number size distribution
|-
| DGN_DRY_CSS || MAMchem || m || xyz || dry geometric mean diameter of coarse seasalt mode number size distribution
|-
| DGN_DRY_FDU || MAMchem || m || xyz || dry geometric mean diameter of fine dust mode number size distribution
|-
| DGN_DRY_FSS || MAMchem || m || xyz || dry geometric mean diameter of fine seasalt mode number size distribution
|-
| DGN_DRY_PCM || MAMchem || m || xyz || dry geometric mean diameter of primary carbon mode number size distribution
|-
| DGN_WET_ACC || MAMchem || m || xyz || wet diameter of accumulation mode number size distribution
|-
| DGN_WET_AIT || MAMchem || m || xyz || wet geometric mean diameter of aitken mode number size distribution
|-
| DGN_WET_CDU || MAMchem || m || xyz || wet diameter of coarse dust mode number size distribution
|-
| DGN_WET_CSS || MAMchem || m || xyz || wet diameter of coarse seasalt mode number size distribution
|-
| DGN_WET_FDU || MAMchem || m || xyz || wet diameter of fine dust mode number size distribution
|-
| DGN_WET_FSS || MAMchem || m || xyz || wet diameter of fine seasalt mode number size distribution
|-
| DGN_WET_PCM || MAMchem || m || xyz || wet diameter of primary carbon mode number size distribution
|-
| DMS || MAMchem || molmol || xyz || DMS mass mixing ratio
|-
| DU_A_CDU || MAMchem || kgkg || xyz || dust mass mixing ratio (coarse dust mode interstitial)
|-
| DU_A_FDU || MAMchem || kgkg || xyz || dust mass mixing ratio (fine dust mode interstitial)
|-
| DU_C_CDU || MAMchem || kgkg || xyz || dust mass mixing ratio (coarse dust mode cloud-borne)
|-
| DU_C_FDU || MAMchem || kgkg || xyz || dust mass mixing ratio (fine dust mode cloud-borne)
|-
| H2O2 || MAMchem || molmol || xyz || H2O2 mass mixing ratio
|-
| H2SO4 || MAMchem || molmol || xyz || H2SO4 mass mixing ratio
|-
| NH3 || MAMchem || molmol || xyz || NH3 mass mixing ratio
|-
| NUM_A_ACC || MAMchem || #kg || xyz || number of particles (accumulation mode interstitial)
|-
| NUM_A_AIT || MAMchem || #kg || xyz || number of particles (aitken mode interstitial)
|-
| NUM_A_CDU || MAMchem || #kg || xyz || number of particles (coarse dust mode interstitial)
|-
| NUM_A_CSS || MAMchem || #kg || xyz || number of particles (coarse seasalt mode interstitial)
|-
| NUM_A_FDU || MAMchem || #kg || xyz || number of particles (fine dust mode interstitial)
|-
| NUM_A_FSS || MAMchem || #kg || xyz || number of particles (fine seasalt mode interstitial)
|-
| NUM_A_PCM || MAMchem || #kg || xyz || number of particles (primary carbon mode interstitial)
|-
| NUM_C_ACC || MAMchem || #kg || xyz || number of particles (accumulation mode cloud-borne)
|-
| NUM_C_AIT || MAMchem || #kg || xyz || number of particles (aitken mode cloud-borne)
|-
| NUM_C_CDU || MAMchem || #kg || xyz || number of particles (coarse dust mode cloud-borne)
|-
| NUM_C_CSS || MAMchem || #kg || xyz || number of particles (coarse seasalt mode cloud-borne)
|-
| NUM_C_FDU || MAMchem || #kg || xyz || number of particles (fine dust mode cloud-borne)
|-
| NUM_C_FSS || MAMchem || #kg || xyz || number of particles (fine seasalt mode cloud-borne)
|-
| NUM_C_PCM || MAMchem || #kg || xyz || number of particles (primary carbon mode cloud-borne)
|-
| POM_A_ACC || MAMchem || kgkg || xyz || primary OM mass mixing ratio (accumulation mode interstitial)
|-
| POM_A_PCM || MAMchem || kgkg || xyz || primary OM mass mixing ratio (primary carbon mode interstitial)
|-
| POM_C_ACC || MAMchem || kgkg || xyz || primary OM mass mixing ratio (accumulation mode cloud-borne)
|-
| POM_C_PCM || MAMchem || kgkg || xyz || primary OM mass mixing ratio (primary carbon mode cloud-borne)
|-
| SO2 || MAMchem || molmol || xyz || SO2 mass mixing ratio
|-
| SOA_A_ACC || MAMchem || kgkg || xyz || secondary OM mass mixing ratio (accumulation mode interstitial)
|-
| SOA_A_AIT || MAMchem || kgkg || xyz || secondary OM mass mixing ratio (aitken mode interstitial)
|-
| SOA_C_ACC || MAMchem || kgkg || xyz || secondary OM mass mixing ratio (accumulation mode cloud-borne)
|-
| SOA_C_AIT || MAMchem || kgkg || xyz || secondary OM mass mixing ratio (aitken mode cloud-borne)
|-
| SOA_GAS || MAMchem || molmol || xyz || SOA(gas) mass mixing ratio
|-
| SS_A_ACC || MAMchem || kgkg || xyz || sea-salt mass mixing ratio (accumulation mode interstitial)
|-
| SS_A_AIT || MAMchem || kgkg || xyz || sea-salt mass mixing ratio (aitken mode interstitial)
|-
| SS_A_CSS || MAMchem || kgkg || xyz || sea-salt mass mixing ratio (coarse seasalt mode interstitial)
|-
| SS_A_FSS || MAMchem || kgkg || xyz || sea-salt mass mixing ratio (fine seasalt mode interstitial)
|-
| SS_C_ACC || MAMchem || kgkg || xyz || sea-salt mass mixing ratio (accumulation mode cloud-borne)
|-
| SS_C_AIT || MAMchem || kgkg || xyz || sea-salt mass mixing ratio (aitken mode cloud-borne)
|-
| SS_C_CSS || MAMchem || kgkg || xyz || sea-salt mass mixing ratio (coarse seasalt mode cloud-borne)
|-
| SS_C_FSS || MAMchem || kgkg || xyz || sea-salt mass mixing ratio (fine seasalt mode cloud-borne)
|-
| SU_A_ACC || MAMchem || kgkg || xyz || sulfate mass mixing ratio (accumulation mode interstitial)
|-
| SU_A_AIT || MAMchem || kgkg || xyz || sulfate mass mixing ratio (aitken mode  interstitial)
|-
| SU_A_CDU || MAMchem || kgkg || xyz || sulfate mass mixing ratio (coarse dust mode interstitial)
|-
| SU_A_CSS || MAMchem || kgkg || xyz || sulfate mass mixing ratio (coarse seasalt mode interstitial)
|-
| SU_A_FDU || MAMchem || kgkg || xyz || sulfate mass mixing ratio (fine dust mode interstitial)
|-
| SU_A_FSS || MAMchem || kgkg || xyz || sulfate mass mixing ratio (fine seasalt mode interstitial)
|-
| SU_C_ACC || MAMchem || kgkg || xyz || sulfate mass mixing ratio (accumulation mode cloud-borne)
|-
| SU_C_AIT || MAMchem || kgkg || xyz || sulfate mass mixing ratio (aitken mode cloud-borne)
|-
| SU_C_CDU || MAMchem || kgkg || xyz || sulfate mass mixing ratio (coarse dust mode cloud-borne)
|-
| SU_C_CSS || MAMchem || kgkg || xyz || sulfate mass mixing ratio (coarse seasalt mode cloud-borne)
|-
| SU_C_FDU || MAMchem || kgkg || xyz || sulfate mass mixing ratio (fine dust mode cloud-borne)
|-
| SU_C_FSS || MAMchem || kgkg || xyz || sulfate mass mixing ratio (fine seasalt mode cloud-borne)
|-
| CLCN || Moist || 1 || xyz || convective cloud area fraction
|-
| CLLS || Moist || 1 || xyz || large scale cloud area fraction
|-
| Q || Moist || kg kg-1 || xyz || specific humidity
|-
| QICN || Moist || kg kg-1 || xyz || mass fraction of convective cloud ice water
|-
| QILS || Moist || kg kg-1 || xyz || mass fraction of large scale cloud ice water
|-
| QLCN || Moist || kg kg-1 || xyz || mass fraction of convective cloud liquid water
|-
| QLLS || Moist || kg kg-1 || xyz || mass fraction of large scale cloud liquid water
|-
| KPAR_NEXT || Orad || m-1 || xy || KPAR next
|-
| KPAR_PREV || Orad || m-1 || xy || KPAR previous
|-
| AERO || PChem || kg kg-1 || xyz || aerosol mass mixing ratios
|-
| AEROTEND || PChem || kg kg-1 s-1 || xyz || aerosol mass mixing ratio tendencies
|-
| AOA || PChem || days || xyz || age of air
|-
| CFC11 || PChem || mol mol-1 || xyz || CFC11 (CCl3F) volume mixing ratio
|-
| CFC12 || PChem || mol mol-1 || xyz || CFC12 (CCl2F2) volume mixing ratio
|-
| CH4 || PChem || mol mol-1 || xyz || methane volume mixing ratio
|-
| HCFC22 || PChem || mol mol-1 || xyz || HCFC22 (CHClF2) volume mixing ratio
|-
| N2O || PChem || mol mol-1 || xyz || nitrous oxide volume mixing ratio
|-
| OX || PChem || mol mol-1 || xyz || odd oxygen volume mixing ratio
|-
| CH || Saltwater || kg m-2 s-1 || tile2 || surface heat exchange coefficient
|-
| CM || Saltwater || kg m-2 s-1 || tile2 || surface momentum exchange coefficient
|-
| CQ || Saltwater || kg m-2 s-1 || tile2 || surface moisture exchange coefficient
|-
| HSKINI || Saltwater || kg m-2 || tile || ice skin layer mass
|-
| HSKINW || Saltwater || kg m-2 || tile || water skin layer mass
|-
| QS || Saltwater || kg kg-1 || tile2 || surface specific humidity
|-
| SSKINI || Saltwater || psu || tile || ice skin salinity
|-
| SSKINW || Saltwater || psu || tile || water skin salinity
|-
| TSKINI || Saltwater || K || tile || ice skin temperature
|-
| TSKINW || Saltwater || K || tile || water skin temperature
|-
| WW || Saltwater || m+2 s-2 || tile2 || vertical velocity scale squared
|-
| Z0 || Saltwater || m || tile2 || aerodynamic roughness
|-
| DFNIRN || Solar || 1 || xy || normalized surface downwelling nearinfrared diffuse flux
|-
| DFPARN || Solar || 1 || xy || normalized surface downwelling par diffuse flux
|-
| DFUVRN || Solar || 1 || xy || normalized surface downwelling ultraviolet diffuse flux
|-
| DRNIRN || Solar || 1 || xy || normalized surface downwelling nearinfrared beam flux
|-
| DRPARN || Solar || 1 || xy || normalized surface downwelling par beam flux
|-
| DRUVRN || Solar || 1 || xy || normalized surface downwelling ultraviolet beam flux
|-
| FSCN || Solar || 1 || xyz || normalized net downward shortwave flux in air assuming clear sky
|-
| FSCNAN || Solar || 1 || xyz || normalized net downward shortwave flux in air assuming clear sky and no aerosol
|-
| FSCUN || Solar || 1 || xyz || normalized upward shortwave flux in air assuming clear sky
|-
| FSCUNAN || Solar || 1 || xyz || normalized upward shortwave flux in air assuming clear sky and no aerosol
|-
| FSWBANDN || Solar || 1 || xy || normalized net surface downward shortwave flux per band in air
|-
| FSWBANDNAN || Solar || 1 || xy || normalized net surface downward shortwave flux per band in air assuming no aerosol
|-
| FSWN || Solar || 1 || xyz || normalized net downward shortwave flux in air
|-
| FSWNAN || Solar || 1 || xyz || normalized net downward shortwave flux in air assuming no aerosol
|-
| FSWUN || Solar || 1 || xyz || normalized upward shortwave flux in air
|-
| FSWUNAN || Solar || 1 || xyz || normalized upward shortwave flux in air assuming no aerosol
|-
| AOADAYS || StratChem || days || xyz || age-of-air
|-
| BR || StratChem || mol mol-1 || xyz || atomic bromine
|-
| BRCL || StratChem || mol mol-1 || xyz || bromine chloride
|-
| BRO || StratChem || mol mol-1 || xyz || bromine monoxide
|-
| BRONO2 || StratChem || mol mol-1 || xyz || bromine nitrate
|-
| BRX || StratChem || mol mol-1 || xyz || odd bromine
|-
| CCL4 || StratChem || mol mol-1 || xyz || carbon tetrachloride
|-
| CFC11 || StratChem || mol mol-1 || xyz || CFC-11 (CFCl3)
|-
| CFC113 || StratChem || mol mol-1 || xyz || CFC-113 (C2Cl3F3)
|-
| CFC12 || StratChem || mol mol-1 || xyz || CFC-12 (CF2Cl2)
|-
| CH2O || StratChem || mol mol-1 || xyz || formaldehyde
|-
| CH3BR || StratChem || mol mol-1 || xyz || methyl bromide
|-
| CH3CCL3 || StratChem || mol mol-1 || xyz || methyl chloroform
|-
| CH3CL || StratChem || mol mol-1 || xyz || methyl chloride
|-
| CH3O2 || StratChem || mol mol-1 || xyz || methyl peroxide
|-
| CH3OOH || StratChem || mol mol-1 || xyz || methyl hydroperoxide
|-
| CH4 || StratChem || mol mol-1 || xyz || methane
|-
| CL || StratChem || mol mol-1 || xyz || atomic chlorine
|-
| CL2 || StratChem || mol mol-1 || xyz || molecular chlorine
|-
| CL2O2 || StratChem || mol mol-1 || xyz || dichlorine peroxide
|-
| CLO || StratChem || mol mol-1 || xyz || chlorine monoxide
|-
| CLONO2 || StratChem || mol mol-1 || xyz || chlorine nitrate
|-
| CLX || StratChem || mol mol-1 || xyz || odd chlorine
|-
| CO || StratChem || mol mol-1 || xyz || carbon monoxyde
|-
| H12_24 || StratChem || mol mol-1 || xyz || halon 12 24
|-
| H1301 || StratChem || mol mol-1 || xyz || halon 1301 (CBrF3)
|-
| H2O2 || StratChem || mol mol-1 || xyz || hydrogen peroxide
|-
| HATOMIC || StratChem || mol mol-1 || xyz || atomic hydrogen
|-
| HBR || StratChem || mol mol-1 || xyz || hydrogen bromide
|-
| HCFC || StratChem || mol mol-1 || xyz || HCFC
|-
| HCFC22 || StratChem || mol mol-1 || xyz || HCFC-22 (CHClF2)
|-
| HCL || StratChem || mol mol-1 || xyz || hydrochloric acid
|-
| HNO3 || StratChem || mol mol-1 || xyz || nitric acid
|-
| HNO3COND || StratChem || mol mol-1 || xyz || condensed nitric acid
|-
| HO2 || StratChem || mol mol-1 || xyz || hydroperoxyl radical
|-
| HO2NO2 || StratChem || mol mol-1 || xyz || peroxynitric acid
|-
| HOBR || StratChem || mol mol-1 || xyz || hypobromous acid
|-
| HOCL || StratChem || mol mol-1 || xyz || hypochlorous acid
|-
| N || StratChem || mol mol-1 || xyz || ground state atomic nitrogen
|-
| N2O || StratChem || mol mol-1 || xyz || nitrous oxide
|-
| N2O5 || StratChem || mol mol-1 || xyz || dinitrogen pentoxide
|-
| NO || StratChem || mol mol-1 || xyz || nitric oxide
|-
| NO2 || StratChem || mol mol-1 || xyz || nitrogen dioxide
|-
| NO3 || StratChem || mol mol-1 || xyz || nitrogen trioxide
|-
| NOX || StratChem || mol mol-1 || xyz || odd nitrogen
|-
| O1D || StratChem || mol mol-1 || xyz || atomic oxygen in the first excited state
|-
| O3CHEM || StratChem || mol mol-1 || xyz || ozone from chemistry
|-
| O3P || StratChem || mol mol-1 || xyz || atomic oxygen in the ground state
|-
| OCLO || StratChem || mol mol-1 || xyz || chlorine dioxide
|-
| OH || StratChem || mol mol-1 || xyz || hydroxyl radical
|-
| OX || StratChem || mol mol-1 || xyz || odd oxygen
|-
| RO3OX || StratChem || mol mol-1 || xyz || ozone odd oxygen ratio
|-
| UNKNOWN || StratChem || UNKNOWN || xyz || UNKNOWN
|-
| UNKNOWN || StratChem || UNKNOWN || xyz || UNKNOWN
|-
| CM || Surface || kg m-2 s-1 || xy || surface exchange coefficient for momentum
|-
| CN || Surface || 1 || xy || surface neutral drag coefficient
|-
| CQ || Surface || kg m-2 s-1 || xy || surface exchange coefficient for moisture
|-
| CT || Surface || kg m-2 s-1 || xy || surface exchange coefficient for heat
|-
| D0 || Surface || m || xy || zero plane displacement height
|-
| QHAT || Surface || kg kg-1 || xy || effective surface specific humidity
|-
| QS || Surface || kg kg-1 || xy || surface specific humidity
|-
| RHOS || Surface || kg m-3 || xy || air density at surface
|-
| THAT || Surface || K || xy || effective surface skin temperature
|-
| TS || Surface || K || xy || surface skin temperature
|-
| UHAT || Surface || m s-1 || xy || effective surface eastward velocity
|-
| VHAT || Surface || m s-1 || xy || effective surface northward velocity
|-
| AKQ || Turbulence || 1 || xyz || matrix diagonal ahat for moisture
|-
| AKS || Turbulence || 1 || xyz || matrix diagonal ahat for scalars
|-
| AKV || Turbulence || 1 || xyz || matrix diagonal ahat for winds
|-
| BKQ || Turbulence || 1 || xyz || matrix diagonal bhat for moisture
|-
| BKS || Turbulence || 1 || xyz || matrix diagonal bhat for scalars
|-
| BKV || Turbulence || 1 || xyz || matrix diagonal bhat for winds
|-
| CKQ || Turbulence || 1 || xyz || matrix diagonal c for moisture
|-
| CKS || Turbulence || 1 || xyz || matrix diagonal c for scalars
|-
| CKV || Turbulence || 1 || xyz || matrix diagonal c for winds
|-
| DKQ || Turbulence || s-1 || xyz || sensitivity of tendency to surface value for moisture
|-
| DKS || Turbulence || s-1 || xyz || sensitivity of tendency to surface value for scalars
|-
| DKV || Turbulence || s-1 || xyz || sensitivity of tendency to surface value for winds
|-
| EKV || Turbulence || Pa s-1 || xyz || momentum mixing factor
|-
| FKV || Turbulence || Pa s-1 || xyz || topographic roughness factor
|-
| SINC || Turbulence || m+2 s-3 || xyz || turbulence tendency for dry static energy
|-
| ZLE || Turbulence || m || xyz || geopotential height above surface
|-
| ZPBL || Turbulence || m || xy || planetary boundary layer height
|-
| ITY || Vegdyn || 1 || tile || vegetation type
|}
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