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concentration ;\tCLDFOC:Frequency of Warm Cloud Occurence ;\tCLDFREE:Cloud free fraction wrt CAODVIS and CABSVIS ;\tCLDHGH:Vertically-integrated high cloud ;\tCLDICE:Grid box averaged cloud ice amount ;\tCLDLIQ:Grid box averaged cloud liquid amount ;\tCLDLIX:Aerosol calc averaged liquid condensate amount ;\tCLDLOW:Vertically-integrated low cloud ;\tCLDMED:Vertically-integrated mid-level cloud ;\tCLDTOT:Vertically-integrated total cloud ;\tCLOUD:Cloud fraction ;\tCMFDQ:QV tendency - shallow convection ;\tCMFDQR:Q tendency - shallow convection rainout ;\tCMFDT:T tendency - shallow convection ;\tCMFMC:Moist shallow convection mass flux ;\tCMFMCDZM:Convection mass flux from ZM deep ;\tCONCLD:Convective cloud cover ;\tC_BC:Column burden ;\tC_DMS:Column burden ;\tC_DUST:Column burden ;\tC_POM:Column burden ;\tC_SO2:Column burden ;\tC_SO4:Column burden ;\tC_SS:Column burden ;\tDAYFOC:Daylight fraction ;\tDCQ:Q tendency due to moist processes ;\tDMS:DMS ;\tDRY_BC:Dry deposition ;\tDRY_DUST:Dry deposition ;\tDRY_POM:Dry deposition ;\tDRY_SO2:Dry deposition ;\tDRY_SO4:Dry deposition ;\tDRY_SS:Dry deposition ;\tDTCOND:T tendency - moist processes ;\tDTV:T vertical diffusion ;\tDUST:Concentration ;\tEMI_BC:Emissions ;\tEMI_DMS:Emissions ;\tEMI_DUST:Emissions ;\tEMI_POM:Emissions ;\tEMI_SO2:Emissions ;\tEMI_SO4:Emissions ;\tEMI_SS:Emissions ;\tEVAPX:Evaporation of cloud droplets ;\tFICE:Fractional ice content within cloud ;\tFLDS:Downwelling longwave flux at surface ;\tFLDSC:Clearsky downwelling longwave flux at surface ;\tFLNS:Net longwave flux at surface ;\tFLNSC:Clearsky net longwave flux at surface ;\tFLNT:Net longwave flux at top of model ;\tFLNTC:Clearsky net longwave flux at top of model ;\tFLUT:Upwelling longwave flux at top of model ;\tFLUTC:Clearsky upwelling longwave flux at top of model ;\tFOCHANA:Frequency of Occurrence of Clouds with REHANA /= 0 ;\tFREQSH:Fractional occurance of shallow convection ;\tFREQZM:Fractional occurance of ZM convection ;\tFSDS:Downwelling solar flux at surface ;\tFSDSC:Clearsky downwelling solar flux at surface ;\tFSNS:Net solar flux at surface ;\tFSNSC:Clearsky net solar flux at surface ;\tFSNT:Net solar flux at top of model ;\tFSNTC:Clearsky net solar flux at top of model ;\tFSNTOA:Net solar flux at top of atmosphere ;\tFSNTOAC:Clearsky net solar flux at top of atmosphere ;\tFSUTOA:Upwelling solar flux at top of atmosphere ;\tGCLDLWP:Grid-box cloud water path ;\tICEFRAC:Fraction of sfc area covered by sea-ice ;\tICLDIWP:In-cloud ice water path ;\tICLDTWP:In-cloud cloud total water path (liquid and ice) ;\tLANDFRAC:Fraction of sfc area covered by land ;\tLHFLX:Surface latent heat flux ;\tLWCF:Longwave cloud forcing ;\tMSAGA:MSA gas-phase prod ;\tMSKtem:TEM mask ;\tNRAINX:Loss of cloud droplets due to precip ;\tNUCRAT:Nucleation of cloud droplets ;\tN_AER:Aerosol number concentration ;\tOCNFRAC:Fraction of sfc area covered by ocean ;\tOMEGA:Vertical velocity (pressure) ;\tOMEGA010:Vertical velocity at 10 mbar pressure surface ;\tOMEGA020:Vertical velocity at 20 mbar pressure surface ;\tOMEGA030:Vertical velocity at 30 mbar pressure surface ;\tOMEGA050:Vertical velocity at 50 mbar pressure surface ;\tOMEGA070:Vertical velocity at 70 mbar pressure surface ;\tOMEGA100:Vertical velocity at 100 mbar pressure surface ;\tOMEGA1000:Vertical velocity at 1000 mbar pressure surface ;\tOMEGA150:Vertical velocity at 150 mbar pressure surface ;\tOMEGA200:Vertical velocity at 200 mbar pressure surface ;\tOMEGA250:Vertical velocity at 250 mbar pressure surface ;\tOMEGA300:Vertical velocity at 300 mbar pressure surface ;\tOMEGA400:Vertical velocity at 400 mbar pressure surface ;\tOMEGA500:Vertical velocity at 500 mbar pressure surface ;\tOMEGA600:Vertical velocity at 600 mbar pressure surface ;\tOMEGA700:Vertical velocity at 700 mbar pressure surface ;\tOMEGA850:Vertical velocity at 850 mbar pressure surface ;\tOMEGA925:Vertical velocity at 925 mbar pressure surface ;\tOMEGAT:Vertical heat flux ;\tPBLH:PBL height ;\tPCONVB:convection base pressure ;\tPCONVT:convection top  pressure ;\tPHIS:Surface geopotential ;\tPOM:Concentration ;\tPRECC:Convective precipitation rate (liq + ice) ;\tPRECCDZM:Convective precipitation rate from ZM deep ;\tPRECL:Large-scale (stable) precipitation rate (liq + ice) ;\tPRECSC:Convective snow rate (water equivalent) ;\tPRECSH:Shallow Convection precipitation rate ;\tPRECSL:Large-scale (stable) snow rate (water equivalent) ;\tPRECT:Total (convective and large-scale) precipitation rate (liq + ice) ;\tPS:Surface pressure ;\tPSL:Sea level pressure ;\tQ:Specific humidity ;\tQ010:Specific Humidity at 10 mbar pressure surface ;\tQ020:Specific Humidity at 20 mbar pressure surface ;\tQ030:Specific Humidity at 30 mbar pressure surface ;\tQ050:Specific Humidity at 50 mbar pressure surface ;\tQ070:Specific Humidity at 70 mbar pressure surface ;\tQ100:Specific Humidity at 100 mbar pressure surface ;\tQ1000:Specific Humidity at 1000 mbar pressure surface ;\tQ150:Specific Humidity at 150 mbar pressure surface ;\tQ200:Specific Humidity at 200 mbar pressure surface ;\tQ250:Specific Humidity at 250 mbar pressure surface ;\tQ300:Specific Humidity at 300 mbar pressure surface ;\tQ400:Specific Humidity at 400 mbar pressure surface ;\tQ500:Specific Humidity at 500 mbar pressure surface ;\tQ600:Specific Humidity at 600 mbar pressure surface ;\tQ700:Specific Humidity at 700 mbar pressure surface ;\tQ850:Specific Humidity at 850 mbar pressure surface ;\tQ925:Specific Humidity at 925 mbar pressure surface ;\tQC:Q tendency - shallow convection LW export ;\tQFLX:Surface water flux ;\tQREFHT:Reference height humidity ;\tQRL:Longwave heating rate ;\tQRS:Solar heating rate ;\tR010:Relative Humidity at 10 mbar pressure surface ;\tR020:Relative Humidity at 20 mbar pressure surface ;\tR030:Relative Humidity at 30 mbar pressure surface ;\tR050:Relative Humidity at 50 mbar pressure surface ;\tR070:Relative Humidity at 70 mbar pressure surface ;\tR100:Relative Humidity at 100 mbar pressure surface ;\tR1000:Relative Humidity at 1000 mbar pressure surface ;\tR150:Relative Humidity at 150 mbar pressure surface ;\tR200:Relative Humidity at 200 mbar pressure surface ;\tR250:Relative Humidity at 250 mbar pressure surface ;\tR300:Relative Humidity at 300 mbar pressure surface ;\tR400:Relative Humidity at 400 mbar pressure surface ;\tR500:Relative Humidity at 500 mbar pressure surface ;\tR600:Relative Humidity at 600 mbar pressure surface ;\tR700:Relative Humidity at 700 mbar pressure surface ;\tR850:Relative Humidity at 850 mbar pressure surface ;\tR925:Relative Humidity at 925 mbar pressure surface ;\tREFFL:Effective Radius of Cloud Droplets ;\tREHANA:Effective radius as seen from satellite ;\tRELH:Fictive relative humidity ;\tRELHUM:Relative humidity ;\tRHREFHT:Reference height relative humidity ;\tRHREFHTMN:Minimum reference height relative humidity ;\tS2GA:SO2 gas-phase prod ;\tS4AQ:Sulphate aq.phase prod ;\tS4GA:Sulphate gas-phase prod ;\tSELFX:Selfcollection of cloud droplets ;\tSHFLX:Surface sensible heat flux ;\tSNOWHICE:Water equivalent snow depth ;\tSNOWHLND:Water equivalent snow depth ;\tSO2:SO2 ;\tSO4:Concentration ;\tSOLIN:Solar insolation ;\tSOLLD:Solar downward near infrared diffuse to surface ;\tSOLSD:Solar downward visible diffuse to surface ;\tSRFRAD:Net radiative flux at surface ;\tSS:Concentration ;\tSST:sea surface temperature ;\tSUPERSAT:Supersaturation from AGR schem ;\tSWCF:Shortwave cloud forcing ;\tT:Temperature ;\tT010:Temperature at 10 mbar pressure surface ;\tT020:Temperature at 20 mbar pressure surface ;\tT030:Temperature at 30 mbar pressure surface ;\tT050:Temperature at 50 mbar pressure surface ;\tT070:Temperature at 70 mbar pressure surface ;\tT100:Temperature at 100 mbar pressure surface ;\tT1000:Temperature at 1000 mbar pressure surface ;\tT150:Temperature at 150 mbar pressure surface ;\tT200:Temperature at 200 mbar pressure surface ;\tT250:Temperature at 250 mbar pressure surface ;\tT300:Temperature at 300 mbar pressure surface ;\tT400:Temperature at 400 mbar pressure surface ;\tT500:Temperature at 500 mbar pressure surface ;\tT600:Temperature at 600 mbar pressure surface ;\tT700:Temperature at 700 mbar pressure surface ;\tT850:Temperature at 850 mbar pressure surface ;\tT925:Temperature at 925 mbar pressure surface ;\tTAUX:Zonal surface stress ;\tTAUY:Meridional surface stress ;\tTGCLDIWP:Total grid-box cloud ice water path ;\tTGCLDLWP:Total grid-box cloud liquid water path ;\tTGCLDLWX:Offline grid-box cloud liquid water path ;\tTH2d:Zonal-Mean potential temp ;\tTMQ:Total (vertically integrated) precipitatable water ;\tTREFHT:Reference height temperature ;\tTREFMNAV:Average of TREFHT daily minimum ;\tTREFMXAV:Average of TREFHT daily maximum ;\tTROP_P:Tropopause Pressure ;\tTROP_T:Tropopause Temperature ;\tTROP_Z:Tropopause Height ;\tTS:Surface temperature (radiative) ;\tTSMN:Minimum surface temperature over output period ;\tTSMX:Maximum surface temperature over output period ;\tU:Zonal wind ;\tU010:Zonal wind at 10 mbar pressure surface ;\tU020:Zonal wind at 20 mbar pressure surface ;\tU030:Zonal wind at 30 mbar pressure surface ;\tU050:Zonal wind at 50 mbar pressure surface ;\tU070:Zonal wind at 70 mbar pressure surface ;\tU10:10m wind speed ;\tU100:Zonal wind at 100 mbar pressure surface ;\tU1000:Zonal wind at 1000 mbar pressure surface ;\tU150:Zonal wind at 150 mbar pressure surface ;\tU200:Zonal wind at 200 mbar pressure surface ;\tU250:Zonal wind at 250 mbar pressure surface ;\tU2d:Zonal-Mean zonal wind ;\tU300:Zonal wind at 300 mbar pressure surface ;\tU400:Zonal wind at 400 mbar pressure surface ;\tU500:Zonal wind at 500 mbar pressure surface ;\tU600:Zonal wind at 600 mbar pressure surface ;\tU700:Zonal wind at 700 mbar pressure surface ;\tU850:Zonal wind at 850 mbar pressure surface ;\tU925:Zonal wind at 925 mbar pressure surface ;\tUAS:Eastward 10m wind ;\tUS:Zonal wind, staggered ;\tUTGWORO:U tendency - orographic gravity wave drag ;\tUU:Zonal velocity squared ;\tUV2d:Meridional Flux of Zonal Momentum: 2D prj of zon. mean ;\tUV3d:Meridional Flux of Zonal Momentum: 3D zon. mean ;\tUW2d:Vertical Flux of Zonal Momentum; 2D prj of zon. mean ;\tUW3d:Vertical Flux of Zonal Momentum: 3D zon. mean ;\tV:Meridional wind ;\tV010:Meridional wind at 10 mbar pressure surface ;\tV020:Meridional wind at 20 mbar pressure surface ;\tV030:Meridional wind at 30 mbar pressure surface ;\tV050:Meridional wind at 50 mbar pressure surface ;\tV070:Meridional wind at 70 mbar pressure surface ;\tV100:Meridional wind at 100 mbar pressure surface ;\tV1000:Meridional wind at 1000 mbar pressure surface ;\tV150:Meridional wind at 150 mbar pressure surface ;\tV200:Meridional wind at 200 mbar pressure surface ;\tV250:Meridional wind at 250 mbar pressure surface ;\tV2d:Zonal-Mean meridional wind ;\tV300:Meridional wind at 300 mbar pressure surface ;\tV400:Meridional wind at 400 mbar pressure surface ;\tV500:Meridional wind at 500 mbar pressure surface ;\tV600:Meridional wind at 600 mbar pressure surface ;\tV700:Meridional wind at 700 mbar pressure surface ;\tV850:Meridional wind at 850 mbar pressure surface ;\tV925:Meridional wind at 925 mbar pressure surface ;\tVAS:Northward 10m wind ;\tVD01:Vertical diffusion of Q ;\tVQ:Meridional water transport ;\tVS:Meridional wind, staggered ;\tVT:Meridional heat transport ;\tVTH2d:Meridional Heat Flux: 2D prj of zon. mean ;\tVTH3d:Meridional Heat Flux: 3D zon. mean ;\tVU:Meridional flux of zonal momentum ;\tVV:Meridional velocity squared ;\tW2d:Zonal-Mean vertical wind ;\tWET_BC:Wet deposition ;\tWET_DUST:Wet deposition ;\tWET_POM:Wet deposition ;\tWET_SO2:Wet deposition ;\tWET_SO4:Wet deposition ;\tWET_SS:Wet deposition ;\tWTH3d:Vertical Heat Flux: 3D zon. mean ;\tZ010:Geopotential Z at 10 mbar pressure surface ;\tZ020:Geopotential Z at 20 mbar pressure surface ;\tZ030:Geopotential Z at 30 mbar pressure surface ;\tZ050:Geopotential Z at 50 mbar pressure surface ;\tZ070:Geopotential Z at 70 mbar pressure surface ;\tZ100:Geopotential Z at 100 mbar pressure surface ;\tZ1000:Geopotential Z at 1000 mbar pressure surface ;\tZ150:Geopotential Z at 150 mbar pressure surface ;\tZ200:Geopotential Z at 200 mbar pressure surface ;\tZ250:Geopotential Z at 250 mbar pressure surface ;\tZ3:Geopotential Height (above sea level) ;\tZ300:Geopotential Z at 300 mbar pressure surface ;\tZ400:Geopotential Z at 400 mbar pressure surface ;\tZ500:Geopotential Z at 500 mbar pressure surface ;\tZ600:Geopotential Z at 600 mbar pressure surface ;\tZ700:Geopotential Z at 700 mbar pressure surface ;\tZ850:Geopotential Z at 850 mbar pressure surface ;\tZ925:Geopotential Z at 925 mbar pressure surface ;\tSource = CLM ; Variables =\t\tlevgrnd:coordinate soil levels ;\tlevlak:coordinate lake levels ;\tedgen:northern edge of surface grid ;\tedgee:eastern edge of surface grid ;\tedges:southern edge of surface grid ;\tedgew:western edge of surface grid ;\ttime:time ;\tmcdate:current date (YYYYMMDD) ;\tmcsec:current seconds of current date ;\tmdcur:current day (from base day) ;\tmscur:current seconds of current day ;\tnstep:time step ;\ttime_bounds:history time interval endpoints ;\tlon:coordinate longitude ;\tlat:coordinate latitude ;\tlonatm:atm coordinate longitude ;\tlatatm:atm coordinate latitude ;\tlonrof:runoff coordinate longitude ;\tlatrof:runoff coordinate latitude ;\tlongxy:longitude ;\tlatixy:latitude ;\tarea:grid cell areas ;\tareaupsc:normalized grid cell areas related to upscaling ;\ttopo:grid cell topography ;\ttopodnsc:normalized grid cell topography related to downscaling ;\tlandfrac:land fraction ;\tlandmask:land/ocean mask (0.=ocean and 1.=land) ;\tpftmask:pft real/fake mask (0.=fake and 1.=real) ;\tindxupsc:upscaling atm global grid index ;\tlongxyatm:atm longitude ;\tlatixyatm:atm latitude ;\tareaatm:atm grid cell areas ;\tZSOI:soil depth ;\tDZSOI:soil thickness ;\tWATSAT:saturated soil water content (porosity) ;\tSUCSAT:saturated soil matric potential ;\tBSW:slope of soil water retention curve ;\tHKSAT:saturated hydraulic conductivity ;\tACTUAL_IMMOB:actual N immobilization ;\tAGNPP:aboveground NPP ;\tANN_FAREA_BURNED:annual total fractional area burned ;\tAR:autotrophic respiration (MR + GR) ;\tBCDEP:total BC deposition (dry+wet) from atmosphere ;\tBGNPP:belowground NPP ;\tBIOGENCO:biogenic CO flux ;\tBTRAN:transpiration beta factor ;\tBUILDHEAT:heat flux from urban building interior to walls and roof ;\tCOL_CTRUNC:column-level sink for C truncation ;\tCOL_FIRE_CLOSS:total column-level fire C loss ;\tCOL_FIRE_NLOSS:total column-level fire N loss ;\tCOL_NTRUNC:column-level sink for N truncation ;\tCPOOL:temporary photosynthate C pool ;\tCWDC:coarse woody debris C ;\tCWDC_HR:coarse woody debris C heterotrophic respiration ;\tCWDC_LOSS:coarse woody debris C loss ;\tCWDN:coarse woody debris N ;\tDEADCROOTC:dead coarse root C ;\tDEADCROOTN:dead coarse root N ;\tDEADSTEMC:dead stem C ;\tDEADSTEMN:dead stem N ;\tDENIT:total rate of denitrification ;\tDISPVEGC:displayed veg carbon, excluding storage and cpool ;\tDISPVEGN:displayed vegetation nitrogen ;\tDSTDEP:total dust deposition (dry+wet) from atmosphere ;\tDSTFLXT:total surface dust emission ;\tDWT_CLOSS:total carbon loss from land cover conversion ;\tDWT_CONV_CFLUX:conversion C flux (immediate loss to atm) ;\tDWT_CONV_NFLUX:conversion N flux (immediate loss to atm) ;\tDWT_NLOSS:total nitrogen loss from landcover conversion ;\tDWT_PROD100C_GAIN:landcover change-driven addition to 100-yr wood product pool ;\tDWT_PROD100N_GAIN:addition to 100-yr wood product pool ;\tDWT_PROD10C_GAIN:landcover change-driven addition to 10-yr wood product pool ;\tDWT_PROD10N_GAIN:addition to 10-yr wood product pool ;\tDWT_SEEDC_TO_DEADSTEM:seed source to PFT-level deadstem ;\tDWT_SEEDC_TO_LEAF:seed source to PFT-level leaf ;\tDWT_SEEDN_TO_DEADSTEM:seed source to PFT-level deadstem ;\tDWT_SEEDN_TO_LEAF:seed source to PFT-level leaf ;\tEFLX_DYNBAL:dynamic land cover change conversion energy flux ;\tEFLX_LH_TOT_R:Rural total evaporation ;\tEFLX_LH_TOT_U:Urban total evaporation ;\tELAI:exposed one-sided leaf area index ;\tER:total ecosystem respiration, autotrophic + heterotrophic ;\tERRH2O:total water conservation error ;\tERRSEB:surface energy conservation error ;\tERRSOI:soil/lake energy conservation error ;\tERRSOL:solar radiation conservation error ;\tESAI:exposed one-sided stem area index ;\tFCEV:canopy evaporation ;\tFCOV:fractional impermeable area ;\tFCTR:canopy transpiration ;\tFGEV:ground evaporation ;\tFGR:heat flux into soil/snow including snow melt ;\tFGR12:heat flux between soil layers 1 and 2 ;\tFGR_R:Rural heat flux into soil/snow including snow melt ;\tFGR_U:Urban heat flux into soil/snow including snow melt ;\tFIRA:net infrared (longwave) radiation ;\tFIRA_R:Rural net infrared (longwave) radiation ;\tFIRA_U:Urban net infrared (longwave) radiation ;\tFIRE:emitted infrared (longwave) radiation ;\tFIRESEASONL:annual fire season length ;\tFLDS:atmospheric longwave radiation ;\tFLUXFM2A:heat flux for rain to snow conversion ;\tFLUXFMLND:heat flux from rain to snow conversion ;\tFPG:fraction of potential gpp ;\tFPI:fraction of potential immobilization ;\tFPSN:photosynthesis ;\tFROOTC:fine root C ;\tFROOTC_ALLOC:fine root C allocation ;\tFROOTC_LOSS:fine root C loss ;\tFROOTN:fine root N ;\tFSA:absorbed solar radiation ;\tFSAT:fractional area with water table at surface ;\tFSA_R:Rural absorbed solar radiation ;\tFSA_U:Urban absorbed solar radiation ;\tFSDS:atmospheric incident solar radiation ;\tFSDSND:direct nir incident solar radiation ;\tFSDSNDLN:direct nir incident solar radiation at local noon ;\tFSDSNI:diffuse nir incident solar radiation ;\tFSDSVD:direct vis incident solar radiation ;\tFSDSVDLN:direct vis incident solar radiation at local noon ;\tFSDSVI:diffuse vis incident solar radiation ;\tFSH:sensible heat ;\tFSH_G:sensible heat from ground ;\tFSH_NODYNLNDUSE:sensible heat ;\tFSH_R:Rural sensible heat ;\tFSH_U:Urban sensible heat ;\tFSH_V:sensible heat from veg ;\tFSM:snow melt heat flux ;\tFSM_R:Rural snow melt heat flux ;\tFSM_U:Urban snow melt heat flux ;\tFSNO:fraction of ground covered by snow ;\tFSR:reflected solar radiation ;\tFSRND:direct nir reflected solar radiation ;\tFSRNDLN:direct nir reflected solar radiation at local noon ;\tFSRNI:diffuse nir reflected solar radiation ;\tFSRVD:direct vis reflected solar radiation ;\tFSRVDLN:direct vis reflected solar radiation at local noon ;\tFSRVI:diffuse vis reflected solar radiation ;\tGC_HEAT1:initial gridcell total heat content ;\tGC_ICE1:initial gridcell total ice content ;\tGC_LIQ1:initial gridcell total liq content ;\tGPP:gross primary production ;\tGR:total growth respiration ;\tGROSS_NMIN:gross rate of N mineralization ;\tH2OCAN:intercepted water ;\tH2OSNO:snow depth (liquid water) ;\tH2OSNO_TOP:mass of snow in top snow layer ;\tH2OSOI:volumetric soil water ;\tHC:heat content of soil/snow/lake ;\tHCSOI:soil heat content ;\tHEAT_FROM_AC:sensible heat flux put into canyon due to heat removed from air conditioning ;\tHR:total heterotrophic respiration ;\tHTOP:canopy top ;\tISOPRENE:isoprene flux ;\tLAISHA:shaded projected leaf area index ;\tLAISUN:sunlit projected leaf area index ;\tLAND_UPTAKE:NEE minus LAND_USE_FLUX, negative for update ;\tLAND_USE_FLUX:total C emitted from land cover conversion and wood product pools ;\tLEAFC:leaf C ;\tLEAFC_ALLOC:leaf C allocation ;\tLEAFC_LOSS:leaf C loss ;\tLEAFN:leaf N ;\tLITFALL:litterfall (leaves and fine roots) ;\tLITHR:litter heterotrophic respiration ;\tLITR1C:litter labile C ;\tLITR1C_TO_SOIL1C:decomp. of litter 1 C to SOM 1 C ;\tLITR1N:litter labile N ;\tLITR2C:litter cellulose C ;\tLITR2C_TO_SOIL2C:decomp. of litter 2 C to SOM 2 C ;\tLITR2N:litter cellulose N ;\tLITR3C:litter lignin C ;\tLITR3C_TO_SOIL3C:decomp. of litter 3 C to SOM 3 C ;\tLITR3N:litter lignin N ;\tLITTERC:litter C ;\tLITTERC_HR:litter C heterotrophic respiration ;\tLITTERC_LOSS:litter C loss ;\tLIVECROOTC:live coarse root C ;\tLIVECROOTN:live coarse root N ;\tLIVESTEMC:live stem C ;\tLIVESTEMN:live stem N ;\tMEAN_FIRE_PROB:e-folding mean of daily fire probability ;\tMONOTERP:monoterpene flux ;\tMR:maintenance respiration ;\tNBP:net biome production, includes fire, landuse, and harvest flux, positive for sink ;\tNDEPLOY:total N deployed in new growth ;\tNDEP_TO_SMINN:atmospheric N deposition to soil mineral N ;\tNEE:net ecosystem exchange of carbon, includes fire, landuse, harvest, and hrv_xsmrpool flux, positive for source ;\tNEP:net ecosystem production, excludes fire, landuse, and harvest flux, positive for sink ;\tNET_NMIN:net rate of N mineralization ;\tNFIX_TO_SMINN:symbiotic/asymbiotic N fixation to soil mineral N ;\tNPP:net primary production ;\tOCDEP:total OC deposition (dry+wet) from atmosphere ;\tORVOC:other reactive VOC flux ;\tOVOC:other VOC flux ;\tPBOT:atmospheric pressure ;\tPCO2:atmospheric partial pressure of CO2 ;\tPFT_CTRUNC:pft-level sink for C truncation ;\tPFT_FIRE_CLOSS:total pft-level fire C loss ;\tPFT_FIRE_NLOSS:total pft-level fire N loss ;\tPFT_NTRUNC:pft-level sink for N truncation ;\tPLANT_NDEMAND:N flux required to support initial GPP ;\tPOTENTIAL_IMMOB:potential N immobilization ;\tPROD100C:100-yr wood product C ;\tPROD100C_LOSS:loss from 100-yr wood product pool ;\tPROD100N:100-yr wood product N ;\tPROD100N_LOSS:loss from 100-yr wood product pool ;\tPROD10C:10-yr wood product C ;\tPROD10C_LOSS:loss from 10-yr wood product pool ;\tPROD10N:10-yr wood product N ;\tPROD10N_LOSS:loss from 10-yr wood product pool ;\tPRODUCT_CLOSS:total carbon loss from wood product pools ;\tPRODUCT_NLOSS:total N loss from wood product pools ;\tPSNSHA:shaded leaf photosynthesis ;\tPSNSHADE_TO_CPOOL:C fixation from shaded canopy ;\tPSNSUN:sunlit leaf photosynthesis ;\tPSNSUN_TO_CPOOL:C fixation from sunlit canopy ;\tQ2M:2m specific humidity ;\tQBOT:atmospheric specific humidity ;\tQCHANR:RTM river flow: LIQ ;\tQCHANR_ICE:RTM river flow: ICE ;\tQCHARGE:aquifer recharge rate ;\tQCHOCNR:RTM river discharge into ocean: LIQ ;\tQCHOCNR_ICE:RTM river discharge into ocean: ICE ;\tQDRAI:sub-surface drainage ;\tQDRIP:throughfall ;\tQFLX_ICE_DYNBAL:ice dynamic land cover change conversion runoff flux ;\tQFLX_LIQ_DYNBAL:liq dynamic land cover change conversion runoff flux ;\tQINFL:infiltration ;\tQINTR:interception ;\tQMELT:snow melt ;\tQOVER:surface runoff ;\tQRGWL:surface runoff at glaciers (liquid only), wetlands, lakes ;\tQRUNOFF:total liquid runoff (does not include QSNWCPICE) ;\tQRUNOFF_NODYNLNDUSE:total liquid runoff (does not include QSNWCPICE) ;\tQRUNOFF_R:Rural total runoff ;\tQRUNOFF_U:Urban total runoff ;\tQSNWCPICE:excess snowfall due to snow capping ;\tQSNWCPICE_NODYNLNDUSE:excess snowfall due to snow capping ;\tQSOIL:ground evaporation ;\tQVEGE:canopy evaporation ;\tQVEGT:canopy transpiration ;\tRAIN:atmospheric rain ;\tRAINATM:atmospheric rain forcing ;\tRAINFM2A:land rain on atm grid ;\tRETRANSN:plant pool of retranslocated N ;\tRETRANSN_TO_NPOOL:deployment of retranslocated N ;\tRH2M:2m relative humidity ;\tRH2M_R:Rural 2m specific humidity ;\tRH2M_U:Urban 2m relative humidity ;\tRR:root respiration (fine root MR + total root GR) ;\tSABG:solar rad absorbed by ground ;\tSABV:solar rad absorbed by veg ;\tSEEDC:pool for seeding new PFTs ;\tSEEDN:pool for seeding new PFTs ;\tSMINN:soil mineral N ;\tSMINN_LEACHED:soil mineral N pool loss to leaching ;\tSMINN_TO_NPOOL:deployment of soil mineral N uptake ;\tSMINN_TO_PLANT:plant uptake of soil mineral N ;\tSNOAERFRC2L:surface forcing of all aerosols in snow, averaged only when snow is present (land) ;\tSNOAERFRCL:surface forcing of all aerosols in snow (land) ;\tSNOBCFRC2L:surface forcing of BC in snow, averaged only when snow is present (land) ;\tSNOBCFRCL:surface forcing of BC in snow (land) ;\tSNOBCMCL:mass of BC in snow column ;\tSNOBCMSL:mass of BC in top snow layer ;\tSNODSTFRC2L:surface forcing of dust in snow, averaged only when snow is present (land) 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      "@value" : "Dataset contains raw output from historical All-Hist simulations produced with NorESM1-HAPPI (Iversen et al. 2017) for the half a degree additional warming, prognosis and projected impacts (HAPPI) project (Mitchell et al. 2017, <a href=\"http://www.happimip.org\" class=\"linkified\" target=\"_blank\">LINK</a>).\n\nMembers 001-125 cover the “present decade” period 2006-2016. From mid-2016, SST boundary conditions are repeated from year 2015. \n\nReferences: \n\nMitchell, D., AchutaRao, K., Allen, M., Bethke, I., Beyerle, U., Ciavarella, A., Forster, P. M., Fuglestvedt, J., Gillett, N., Haustein, K., Ingram, W., Iversen, T., Kharin, V., Klingaman, N., Massey, N., Fischer, E., Schleussner, C.-F., Scinocca, J., Seland, Ø., Shiogama, H., Shuckburgh, E., Sparrow, S., Stone, D., Uhe, P., Wallom, D., Wehner, M., and Zaaboul, R.: Half a degree additional warming, prognosis and projected impacts (HAPPI): background and experimental design, Geosci. Model Dev., 10, 571-583, <a href=\"http://doi.org/10.5194/gmd-10-571-2017\" class=\"linkified\" target=\"_blank\">LINK</a>, 2017.\n\nIversen, T., Bethke, I., Debernard, J. B., Graff, L. S., Seland, Ø., Bentsen, M., Kirkevåg, A., Li, C., and Olivié, D. J. L.: The NorESM1-Happi used for evaluating differences between a global warming of 1.5°C and 2°C, and the role of Arctic Amplification, Earth Syst. Dynam. Discuss., <a href=\"http://doi.org/10.5194/esd-2017-115\" class=\"linkified\" target=\"_blank\">LINK</a>, in review, 2017.\n Data description: case =NorESM_Happi_PresentDecade; Members 001-125 ; Source = CAM ; Variables =\t\tP0:reference pressure ;\tlat:latitude ;\tlon:longitude ;\tslat:staggered latitude ;\tslon:staggered longitude ;\tw_stag:staggered latitude weights ;\tlev:hybrid level at midpoints (1000*(A+B)) ;\tilev:hybrid level at interfaces (1000*(A+B)) ;\tisccp_prs:Mean ISCCP pressure ;\tisccp_tau:Mean ISCCP optical depth ;\tisccp_prstau:Mean pressure (mb).mean optical depth (unitless)/1000 ;\ttime:time ;\ttime_bnds:time interval endpoints ;\tntrm:spectral truncation parameter M ;\tntrn:spectral truncation parameter N ;\tntrk:spectral truncation parameter K ;\tndbase:base day ;\tnsbase:seconds of base day ;\tnbdate:base date (YYYYMMDD) ;\tnbsec:seconds of base date ;\tmdt:timestep ;\tnlon:number of longitudes ;\twnummax:cutoff Fourier wavenumber ;\thyai:hybrid A coefficient at 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;\tQ1000:Specific Humidity at 1000 mbar pressure surface ;\tQ150:Specific Humidity at 150 mbar pressure surface ;\tQ200:Specific Humidity at 200 mbar pressure surface ;\tQ250:Specific Humidity at 250 mbar pressure surface ;\tQ300:Specific Humidity at 300 mbar pressure surface ;\tQ400:Specific Humidity at 400 mbar pressure surface ;\tQ500:Specific Humidity at 500 mbar pressure surface ;\tQ600:Specific Humidity at 600 mbar pressure surface ;\tQ700:Specific Humidity at 700 mbar pressure surface ;\tQ850:Specific Humidity at 850 mbar pressure surface ;\tQ925:Specific Humidity at 925 mbar pressure surface ;\tQC:Q tendency - shallow convection LW export ;\tQFLX:Surface water flux ;\tQREFHT:Reference height humidity ;\tQRL:Longwave heating rate ;\tQRS:Solar heating rate ;\tR010:Relative Humidity at 10 mbar pressure surface ;\tR020:Relative Humidity at 20 mbar pressure surface ;\tR030:Relative Humidity at 30 mbar pressure surface ;\tR050:Relative Humidity at 50 mbar pressure surface ;\tR070:Relative Humidity at 70 mbar pressure surface ;\tR100:Relative Humidity at 100 mbar pressure surface ;\tR1000:Relative Humidity at 1000 mbar pressure surface ;\tR150:Relative Humidity at 150 mbar pressure surface ;\tR200:Relative Humidity at 200 mbar pressure surface ;\tR250:Relative Humidity at 250 mbar pressure surface ;\tR300:Relative Humidity at 300 mbar pressure surface ;\tR400:Relative Humidity at 400 mbar pressure surface ;\tR500:Relative Humidity at 500 mbar pressure surface ;\tR600:Relative Humidity at 600 mbar pressure surface ;\tR700:Relative Humidity at 700 mbar pressure surface ;\tR850:Relative Humidity at 850 mbar pressure surface ;\tR925:Relative Humidity at 925 mbar pressure surface ;\tREFFL:Effective Radius of Cloud Droplets ;\tREHANA:Effective radius as seen from satellite ;\tRELH:Fictive relative humidity ;\tRELHUM:Relative humidity ;\tRHREFHT:Reference height relative humidity ;\tRHREFHTMN:Minimum reference height relative humidity ;\tS2GA:SO2 gas-phase prod ;\tS4AQ:Sulphate aq.phase prod ;\tS4GA:Sulphate gas-phase prod ;\tSELFX:Selfcollection of cloud droplets ;\tSHFLX:Surface sensible heat flux ;\tSNOWHICE:Water equivalent snow depth ;\tSNOWHLND:Water equivalent snow depth ;\tSO2:SO2 ;\tSO4:Concentration ;\tSOLIN:Solar insolation ;\tSOLLD:Solar downward near infrared diffuse to surface ;\tSOLSD:Solar downward visible diffuse to surface ;\tSRFRAD:Net radiative flux at surface ;\tSS:Concentration ;\tSST:sea surface temperature ;\tSUPERSAT:Supersaturation from AGR schem ;\tSWCF:Shortwave cloud forcing ;\tT:Temperature ;\tT010:Temperature at 10 mbar pressure surface ;\tT020:Temperature at 20 mbar pressure surface ;\tT030:Temperature at 30 mbar pressure surface ;\tT050:Temperature at 50 mbar pressure surface ;\tT070:Temperature at 70 mbar pressure surface ;\tT100:Temperature at 100 mbar pressure surface ;\tT1000:Temperature at 1000 mbar pressure surface ;\tT150:Temperature at 150 mbar pressure surface ;\tT200:Temperature at 200 mbar pressure surface ;\tT250:Temperature at 250 mbar pressure surface ;\tT300:Temperature at 300 mbar pressure surface ;\tT400:Temperature at 400 mbar pressure surface ;\tT500:Temperature at 500 mbar pressure surface ;\tT600:Temperature at 600 mbar pressure surface ;\tT700:Temperature at 700 mbar pressure surface ;\tT850:Temperature at 850 mbar pressure surface ;\tT925:Temperature at 925 mbar pressure surface ;\tTAUX:Zonal surface stress ;\tTAUY:Meridional surface stress ;\tTGCLDIWP:Total grid-box cloud ice water path ;\tTGCLDLWP:Total grid-box cloud liquid water path ;\tTGCLDLWX:Offline grid-box cloud liquid water path ;\tTH2d:Zonal-Mean potential temp ;\tTMQ:Total (vertically integrated) precipitatable water ;\tTREFHT:Reference height temperature ;\tTREFMNAV:Average of TREFHT daily minimum ;\tTREFMXAV:Average of TREFHT daily maximum ;\tTROP_P:Tropopause Pressure ;\tTROP_T:Tropopause Temperature ;\tTROP_Z:Tropopause Height ;\tTS:Surface temperature (radiative) ;\tTSMN:Minimum surface temperature over output period ;\tTSMX:Maximum surface temperature over output period ;\tU:Zonal wind ;\tU010:Zonal wind at 10 mbar pressure surface ;\tU020:Zonal wind at 20 mbar pressure surface ;\tU030:Zonal wind at 30 mbar pressure surface ;\tU050:Zonal wind at 50 mbar pressure surface ;\tU070:Zonal wind at 70 mbar pressure surface ;\tU10:10m wind speed ;\tU100:Zonal wind at 100 mbar pressure surface ;\tU1000:Zonal wind at 1000 mbar pressure surface ;\tU150:Zonal wind at 150 mbar pressure surface ;\tU200:Zonal wind at 200 mbar pressure surface ;\tU250:Zonal wind at 250 mbar pressure surface ;\tU2d:Zonal-Mean zonal wind ;\tU300:Zonal wind at 300 mbar pressure surface ;\tU400:Zonal wind at 400 mbar pressure surface ;\tU500:Zonal wind at 500 mbar pressure surface ;\tU600:Zonal wind at 600 mbar pressure surface ;\tU700:Zonal wind at 700 mbar pressure surface ;\tU850:Zonal wind at 850 mbar pressure surface ;\tU925:Zonal wind at 925 mbar pressure surface ;\tUAS:Eastward 10m wind ;\tUS:Zonal wind, staggered ;\tUTGWORO:U tendency - orographic gravity wave drag ;\tUU:Zonal velocity squared ;\tUV2d:Meridional Flux of Zonal Momentum: 2D prj of zon. mean ;\tUV3d:Meridional Flux of Zonal Momentum: 3D zon. mean ;\tUW2d:Vertical Flux of Zonal Momentum; 2D prj of zon. mean ;\tUW3d:Vertical Flux of Zonal Momentum: 3D zon. mean ;\tV:Meridional wind ;\tV010:Meridional wind at 10 mbar pressure surface ;\tV020:Meridional wind at 20 mbar pressure surface ;\tV030:Meridional wind at 30 mbar pressure surface ;\tV050:Meridional wind at 50 mbar pressure surface ;\tV070:Meridional wind at 70 mbar pressure surface ;\tV100:Meridional wind at 100 mbar pressure surface ;\tV1000:Meridional wind at 1000 mbar pressure surface ;\tV150:Meridional wind at 150 mbar pressure surface ;\tV200:Meridional wind at 200 mbar pressure surface ;\tV250:Meridional wind at 250 mbar pressure surface ;\tV2d:Zonal-Mean meridional wind ;\tV300:Meridional wind at 300 mbar pressure surface ;\tV400:Meridional wind at 400 mbar pressure surface ;\tV500:Meridional wind at 500 mbar pressure surface ;\tV600:Meridional wind at 600 mbar pressure surface ;\tV700:Meridional wind at 700 mbar pressure surface ;\tV850:Meridional wind at 850 mbar pressure surface ;\tV925:Meridional wind at 925 mbar pressure surface ;\tVAS:Northward 10m wind ;\tVD01:Vertical diffusion of Q ;\tVQ:Meridional water transport ;\tVS:Meridional wind, staggered ;\tVT:Meridional heat transport ;\tVTH2d:Meridional Heat Flux: 2D prj of zon. mean ;\tVTH3d:Meridional Heat Flux: 3D zon. mean ;\tVU:Meridional flux of zonal momentum ;\tVV:Meridional velocity squared ;\tW2d:Zonal-Mean vertical wind ;\tWET_BC:Wet deposition ;\tWET_DUST:Wet deposition ;\tWET_POM:Wet deposition ;\tWET_SO2:Wet deposition ;\tWET_SO4:Wet deposition ;\tWET_SS:Wet deposition ;\tWTH3d:Vertical Heat Flux: 3D zon. mean ;\tZ010:Geopotential Z at 10 mbar pressure surface ;\tZ020:Geopotential Z at 20 mbar pressure surface ;\tZ030:Geopotential Z at 30 mbar pressure surface ;\tZ050:Geopotential Z at 50 mbar pressure surface ;\tZ070:Geopotential Z at 70 mbar pressure surface ;\tZ100:Geopotential Z at 100 mbar pressure surface ;\tZ1000:Geopotential Z at 1000 mbar pressure surface ;\tZ150:Geopotential Z at 150 mbar pressure surface ;\tZ200:Geopotential Z at 200 mbar pressure surface ;\tZ250:Geopotential Z at 250 mbar pressure surface ;\tZ3:Geopotential Height (above sea level) ;\tZ300:Geopotential Z at 300 mbar pressure surface ;\tZ400:Geopotential Z at 400 mbar pressure surface ;\tZ500:Geopotential Z at 500 mbar pressure surface ;\tZ600:Geopotential Z at 600 mbar pressure surface ;\tZ700:Geopotential Z at 700 mbar pressure surface ;\tZ850:Geopotential Z at 850 mbar pressure surface ;\tZ925:Geopotential Z at 925 mbar pressure surface ;\tSource = CLM ; Variables =\t\tlevgrnd:coordinate soil levels ;\tlevlak:coordinate lake levels ;\tedgen:northern edge of surface grid ;\tedgee:eastern edge of surface grid ;\tedges:southern edge of surface grid ;\tedgew:western edge of surface grid ;\ttime:time ;\tmcdate:current date (YYYYMMDD) ;\tmcsec:current seconds of current date ;\tmdcur:current day (from base day) ;\tmscur:current seconds of current day ;\tnstep:time step ;\ttime_bounds:history time interval endpoints ;\tlon:coordinate longitude ;\tlat:coordinate latitude ;\tlonatm:atm coordinate longitude ;\tlatatm:atm coordinate latitude ;\tlonrof:runoff coordinate longitude ;\tlatrof:runoff coordinate latitude ;\tlongxy:longitude ;\tlatixy:latitude ;\tarea:grid cell areas ;\tareaupsc:normalized grid cell areas related to upscaling ;\ttopo:grid cell topography ;\ttopodnsc:normalized grid cell topography related to downscaling ;\tlandfrac:land fraction ;\tlandmask:land/ocean mask (0.=ocean and 1.=land) ;\tpftmask:pft real/fake mask (0.=fake and 1.=real) ;\tindxupsc:upscaling atm global grid index ;\tlongxyatm:atm longitude ;\tlatixyatm:atm latitude ;\tareaatm:atm grid cell areas ;\tZSOI:soil depth ;\tDZSOI:soil thickness ;\tWATSAT:saturated soil water content (porosity) ;\tSUCSAT:saturated soil matric potential ;\tBSW:slope of soil water retention curve ;\tHKSAT:saturated hydraulic conductivity ;\tACTUAL_IMMOB:actual N immobilization ;\tAGNPP:aboveground NPP ;\tANN_FAREA_BURNED:annual total fractional area burned ;\tAR:autotrophic respiration (MR + GR) ;\tBCDEP:total BC deposition (dry+wet) from atmosphere ;\tBGNPP:belowground NPP ;\tBIOGENCO:biogenic CO flux ;\tBTRAN:transpiration beta factor ;\tBUILDHEAT:heat flux from urban building interior to walls and roof ;\tCOL_CTRUNC:column-level sink for C truncation ;\tCOL_FIRE_CLOSS:total column-level fire C loss ;\tCOL_FIRE_NLOSS:total column-level fire N loss ;\tCOL_NTRUNC:column-level sink for N truncation ;\tCPOOL:temporary photosynthate C pool ;\tCWDC:coarse woody debris C ;\tCWDC_HR:coarse woody debris C heterotrophic respiration ;\tCWDC_LOSS:coarse woody debris C loss ;\tCWDN:coarse woody debris N ;\tDEADCROOTC:dead coarse root C ;\tDEADCROOTN:dead coarse root N ;\tDEADSTEMC:dead stem C ;\tDEADSTEMN:dead stem N ;\tDENIT:total rate of denitrification ;\tDISPVEGC:displayed veg carbon, excluding storage and cpool ;\tDISPVEGN:displayed vegetation nitrogen ;\tDSTDEP:total dust deposition (dry+wet) from atmosphere ;\tDSTFLXT:total surface dust emission ;\tDWT_CLOSS:total carbon loss from land cover conversion ;\tDWT_CONV_CFLUX:conversion C flux (immediate loss to atm) ;\tDWT_CONV_NFLUX:conversion N flux (immediate loss to atm) ;\tDWT_NLOSS:total nitrogen loss from landcover conversion ;\tDWT_PROD100C_GAIN:landcover change-driven addition to 100-yr wood product pool ;\tDWT_PROD100N_GAIN:addition to 100-yr wood product pool ;\tDWT_PROD10C_GAIN:landcover change-driven addition to 10-yr wood product pool ;\tDWT_PROD10N_GAIN:addition to 10-yr wood product pool ;\tDWT_SEEDC_TO_DEADSTEM:seed source to PFT-level deadstem ;\tDWT_SEEDC_TO_LEAF:seed source to PFT-level leaf ;\tDWT_SEEDN_TO_DEADSTEM:seed source to PFT-level deadstem ;\tDWT_SEEDN_TO_LEAF:seed source to PFT-level leaf ;\tEFLX_DYNBAL:dynamic land cover change conversion energy flux ;\tEFLX_LH_TOT_R:Rural total evaporation ;\tEFLX_LH_TOT_U:Urban total evaporation ;\tELAI:exposed one-sided leaf area index ;\tER:total ecosystem respiration, autotrophic + heterotrophic ;\tERRH2O:total water conservation error ;\tERRSEB:surface energy conservation error ;\tERRSOI:soil/lake energy conservation error ;\tERRSOL:solar radiation conservation error ;\tESAI:exposed one-sided stem area index ;\tFCEV:canopy evaporation ;\tFCOV:fractional impermeable area ;\tFCTR:canopy transpiration ;\tFGEV:ground evaporation ;\tFGR:heat flux into soil/snow including snow melt ;\tFGR12:heat flux between soil layers 1 and 2 ;\tFGR_R:Rural heat flux into soil/snow including snow melt ;\tFGR_U:Urban heat flux into soil/snow including snow melt ;\tFIRA:net infrared (longwave) radiation ;\tFIRA_R:Rural net infrared (longwave) radiation ;\tFIRA_U:Urban net infrared (longwave) radiation ;\tFIRE:emitted infrared (longwave) radiation ;\tFIRESEASONL:annual fire season length ;\tFLDS:atmospheric longwave radiation ;\tFLUXFM2A:heat flux for rain to snow conversion ;\tFLUXFMLND:heat flux from rain to snow conversion ;\tFPG:fraction of potential gpp ;\tFPI:fraction of potential immobilization ;\tFPSN:photosynthesis ;\tFROOTC:fine root C ;\tFROOTC_ALLOC:fine root C allocation ;\tFROOTC_LOSS:fine root C loss ;\tFROOTN:fine root N ;\tFSA:absorbed solar radiation ;\tFSAT:fractional area with water table at surface ;\tFSA_R:Rural absorbed solar radiation ;\tFSA_U:Urban absorbed solar radiation ;\tFSDS:atmospheric incident solar radiation ;\tFSDSND:direct nir incident solar radiation ;\tFSDSNDLN:direct nir incident solar radiation at local noon ;\tFSDSNI:diffuse nir incident solar radiation ;\tFSDSVD:direct vis incident solar radiation ;\tFSDSVDLN:direct vis incident solar radiation at local noon ;\tFSDSVI:diffuse vis incident solar radiation ;\tFSH:sensible heat ;\tFSH_G:sensible heat from ground ;\tFSH_NODYNLNDUSE:sensible heat ;\tFSH_R:Rural sensible heat ;\tFSH_U:Urban sensible heat ;\tFSH_V:sensible heat from veg ;\tFSM:snow melt heat flux ;\tFSM_R:Rural snow melt heat flux ;\tFSM_U:Urban snow melt heat flux ;\tFSNO:fraction of ground covered by snow ;\tFSR:reflected solar radiation ;\tFSRND:direct nir reflected solar radiation ;\tFSRNDLN:direct nir reflected solar radiation at local noon ;\tFSRNI:diffuse nir reflected solar radiation ;\tFSRVD:direct vis reflected solar radiation ;\tFSRVDLN:direct vis reflected solar radiation at local noon ;\tFSRVI:diffuse vis reflected solar radiation ;\tGC_HEAT1:initial gridcell total heat content ;\tGC_ICE1:initial gridcell total ice content ;\tGC_LIQ1:initial gridcell total liq content ;\tGPP:gross primary production ;\tGR:total growth respiration ;\tGROSS_NMIN:gross rate of N mineralization ;\tH2OCAN:intercepted water ;\tH2OSNO:snow depth (liquid water) ;\tH2OSNO_TOP:mass of snow in top snow layer ;\tH2OSOI:volumetric soil water ;\tHC:heat content of soil/snow/lake ;\tHCSOI:soil heat content ;\tHEAT_FROM_AC:sensible heat flux put into canyon due to heat removed from air conditioning ;\tHR:total heterotrophic respiration ;\tHTOP:canopy top ;\tISOPRENE:isoprene flux ;\tLAISHA:shaded projected leaf area index ;\tLAISUN:sunlit projected leaf area index ;\tLAND_UPTAKE:NEE minus LAND_USE_FLUX, negative for update ;\tLAND_USE_FLUX:total C emitted from land cover conversion and wood product pools ;\tLEAFC:leaf C ;\tLEAFC_ALLOC:leaf C allocation ;\tLEAFC_LOSS:leaf C loss ;\tLEAFN:leaf N ;\tLITFALL:litterfall (leaves and fine roots) ;\tLITHR:litter heterotrophic respiration ;\tLITR1C:litter labile C ;\tLITR1C_TO_SOIL1C:decomp. of litter 1 C to SOM 1 C ;\tLITR1N:litter labile N ;\tLITR2C:litter cellulose C ;\tLITR2C_TO_SOIL2C:decomp. of litter 2 C to SOM 2 C ;\tLITR2N:litter cellulose N ;\tLITR3C:litter lignin C ;\tLITR3C_TO_SOIL3C:decomp. of litter 3 C to SOM 3 C ;\tLITR3N:litter lignin N ;\tLITTERC:litter C ;\tLITTERC_HR:litter C heterotrophic respiration ;\tLITTERC_LOSS:litter C loss ;\tLIVECROOTC:live coarse root C ;\tLIVECROOTN:live coarse root N ;\tLIVESTEMC:live stem C ;\tLIVESTEMN:live stem N ;\tMEAN_FIRE_PROB:e-folding mean of daily fire probability ;\tMONOTERP:monoterpene flux ;\tMR:maintenance respiration ;\tNBP:net biome production, includes fire, landuse, and harvest flux, positive for sink ;\tNDEPLOY:total N deployed in new growth ;\tNDEP_TO_SMINN:atmospheric N deposition to soil mineral N ;\tNEE:net ecosystem exchange of carbon, includes fire, landuse, harvest, and hrv_xsmrpool flux, positive for source ;\tNEP:net ecosystem production, excludes fire, landuse, and harvest flux, positive for sink ;\tNET_NMIN:net rate of N mineralization ;\tNFIX_TO_SMINN:symbiotic/asymbiotic N fixation to soil mineral N ;\tNPP:net primary production ;\tOCDEP:total OC deposition (dry+wet) from atmosphere ;\tORVOC:other reactive VOC flux ;\tOVOC:other VOC flux ;\tPBOT:atmospheric pressure ;\tPCO2:atmospheric partial pressure of CO2 ;\tPFT_CTRUNC:pft-level sink for C truncation ;\tPFT_FIRE_CLOSS:total pft-level fire C loss ;\tPFT_FIRE_NLOSS:total pft-level fire N loss ;\tPFT_NTRUNC:pft-level sink for N truncation ;\tPLANT_NDEMAND:N flux required to support initial GPP ;\tPOTENTIAL_IMMOB:potential N immobilization ;\tPROD100C:100-yr wood product C ;\tPROD100C_LOSS:loss from 100-yr wood product pool ;\tPROD100N:100-yr wood product N ;\tPROD100N_LOSS:loss from 100-yr wood product pool ;\tPROD10C:10-yr wood product C ;\tPROD10C_LOSS:loss from 10-yr wood product pool ;\tPROD10N:10-yr wood product N ;\tPROD10N_LOSS:loss from 10-yr wood product pool ;\tPRODUCT_CLOSS:total carbon loss from wood product pools ;\tPRODUCT_NLOSS:total N loss from wood product pools ;\tPSNSHA:shaded leaf photosynthesis ;\tPSNSHADE_TO_CPOOL:C fixation from shaded canopy ;\tPSNSUN:sunlit leaf photosynthesis ;\tPSNSUN_TO_CPOOL:C fixation from sunlit canopy ;\tQ2M:2m specific humidity ;\tQBOT:atmospheric specific humidity ;\tQCHANR:RTM river flow: LIQ ;\tQCHANR_ICE:RTM river flow: ICE ;\tQCHARGE:aquifer recharge rate ;\tQCHOCNR:RTM river discharge into ocean: LIQ ;\tQCHOCNR_ICE:RTM river discharge into ocean: ICE ;\tQDRAI:sub-surface drainage ;\tQDRIP:throughfall ;\tQFLX_ICE_DYNBAL:ice dynamic land cover change conversion runoff flux ;\tQFLX_LIQ_DYNBAL:liq dynamic land cover change conversion runoff flux ;\tQINFL:infiltration ;\tQINTR:interception ;\tQMELT:snow melt ;\tQOVER:surface runoff ;\tQRGWL:surface runoff at glaciers (liquid only), wetlands, lakes ;\tQRUNOFF:total liquid runoff (does not include QSNWCPICE) ;\tQRUNOFF_NODYNLNDUSE:total liquid runoff (does not include QSNWCPICE) ;\tQRUNOFF_R:Rural total runoff ;\tQRUNOFF_U:Urban total runoff ;\tQSNWCPICE:excess snowfall due to snow capping ;\tQSNWCPICE_NODYNLNDUSE:excess snowfall due to snow capping ;\tQSOIL:ground evaporation ;\tQVEGE:canopy evaporation ;\tQVEGT:canopy transpiration ;\tRAIN:atmospheric rain ;\tRAINATM:atmospheric rain forcing ;\tRAINFM2A:land rain on atm grid ;\tRETRANSN:plant pool of retranslocated N ;\tRETRANSN_TO_NPOOL:deployment of retranslocated N ;\tRH2M:2m relative humidity ;\tRH2M_R:Rural 2m specific humidity ;\tRH2M_U:Urban 2m relative humidity ;\tRR:root respiration (fine root MR + total root GR) ;\tSABG:solar rad absorbed by ground ;\tSABV:solar rad absorbed by veg ;\tSEEDC:pool for seeding new PFTs ;\tSEEDN:pool for seeding new PFTs ;\tSMINN:soil mineral N ;\tSMINN_LEACHED:soil mineral N pool loss to leaching ;\tSMINN_TO_NPOOL:deployment of soil mineral N uptake ;\tSMINN_TO_PLANT:plant uptake of soil mineral N ;\tSNOAERFRC2L:surface forcing of all aerosols in snow, averaged only when snow is present (land) ;\tSNOAERFRCL:surface forcing of all aerosols in snow (land) ;\tSNOBCFRC2L:surface forcing of BC in snow, averaged only when snow is present (land) ;\tSNOBCFRCL:surface forcing of BC in snow (land) ;\tSNOBCMCL:mass of BC in snow column ;\tSNOBCMSL:mass of BC in top snow layer ;\tSNODSTFRC2L:surface forcing of dust in snow, averaged only when snow is present (land) ;\tSNODSTFRCL:surface forcing of dust in snow (land) ;\tSNODSTMCL:mass of dust in snow column ;\tSNODSTMSL:mass of dust in top snow layer ;\tSNOOCFRC2L:surface forcing of OC in snow, averaged only when snow is present (land) ;\tSNOOCFRCL:surface forcing of OC in snow (land) ;\tSNOOCMCL:mass of OC in snow column ;\tSNOOCMSL:mass of OC in top snow layer ;\tSNOW:atmospheric snow ;\tSNOWATM:atmospheric snow forcing ;\tSNOWDP:snow height ;\tSNOWFM2A:land snow on atm grid ;\tSNOWICE:snow ice ;\tSNOWLIQ:snow liquid water ;\tSOIL1C:soil organic matter C (fast pool) ;\tSOIL1N:soil organic matter N (fast pool) ;\tSOIL2C:soil organic matter C (medium pool) ;\tSOIL2N:soil organic matter N (medium pool) ;\tSOIL3C:soil organic matter C (slow pool) ;\tSOIL3N:soil orgainc matter N (slow pool) ;\tSOIL4C:soil organic matter C (slowest pool) ;\tSOIL4N:soil orgainc matter N (slowest pool) ;\tSOILC:soil C ;\tSOILC_HR:soil C heterotrophic respiration ;\tSOILC_LOSS:soil C loss ;\tSOILICE:soil ice ;\tSOILLIQ:soil liquid water ;\tSOILPSI:soil water potential in each soil layer ;\tSOILWATER_10CM:soil liquid water + ice in top 10cm of soil ;\tSOMHR:soil organic matter heterotrophic respiration ;\tSR:total soil respiration (HR + root resp) ;\tSTORVEGC:stored vegetation carbon, excluding cpool ;\tSTORVEGN:stored vegetation nitrogen ;\tSUPPLEMENT_TO_SMINN:supplemental N supply ;\tSoilAlpha:factor limiting ground evap ;\tSoilAlpha_U:urban factor limiting ground evap ;\tTAUX:zonal surface stress ;\tTAUY:meridional surface stress ;\tTBOT:atmospheric air temperature ;\tTBUILD:internal urban building temperature ;\tTG:ground temperature ;\tTG_R:Rural ground temperature ;\tTG_U:Urban ground temperature ;\tTHBOT:atmospheric air potential temperature ;\tTLAI:total projected leaf area index ;\tTLAKE:lake temperature ;\tTOTCOLC:total column carbon, incl veg and cpool ;\tTOTCOLN:total column-level N ;\tTOTECOSYSC:total ecosystem carbon, incl veg but excl cpool ;\tTOTECOSYSN:total ecosystem N ;\tTOTLITC:total litter carbon ;\tTOTLITN:total litter N ;\tTOTPFTC:total pft-level carbon, including cpool ;\tTOTPFTN:total PFT-level nitrogen ;\tTOTPRODC:total wood product C ;\tTOTPRODN:total wood product N ;\tTOTSOMC:total soil organic matter carbon ;\tTOTSOMN:total soil organic matter N ;\tTOTVEGC:total vegetation carbon, excluding cpool ;\tTOTVEGN:total vegetation nitrogen ;\tTREFMNAV:daily minimum of average 2-m temperature ;\tTREFMNAV_R:Rural daily minimum of average 2-m temperature ;\tTREFMNAV_U:Urban daily minimum of average 2-m temperature ;\tTREFMXAV:daily maximum of average 2-m temperature ;\tTREFMXAV_R:Rural daily maximum of average 2-m temperature ;\tTREFMXAV_U:Urban daily maximum of average 2-m temperature ;\tTSA:2m air temperature ;\tTSAI:total projected stem area index ;\tTSA_R:Rural 2m air temperature ;\tTSA_U:Urban 2m air temperature ;\tTSOI:soil temperature ;\tTSOI_10CM:soil temperature in top 10cm of soil ;\tTV:vegetation temperature ;\tURBAN_AC:urban air conditioning flux ;\tURBAN_HEAT:urban heating flux ;\tVOCFLXT:total VOC flux into atmosphere ;\tWA:water in the unconfined aquifer ;\tWASTEHEAT:sensible heat flux from heating/cooling sources of urban waste heat ;\tWIND:atmospheric wind velocity magnitude ;\tWOODC:wood C ;\tWOODC_ALLOC:wood C allocation ;\tWOODC_LOSS:wood C loss ;\tWOOD_HARVESTC:wood harvest (to product pools) ;\tWOOD_HARVESTN:wood harvest (to product pools) ;\tWT:total water storage (unsaturated soil water + groundwater) ;\tXSMRPOOL:temporary photosynthate C pool ;\tXSMRPOOL_RECOVER:C flux assigned to recovery of negative xsmrpool ;\tZBOT:atmospheric reference height ;\tZWT:water table depth ;"
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