netcdf HRMIP_mp120a_prod04.cam.h0.2014-12 { dimensions: ncol = 40962 ; time = UNLIMITED ; // (1 currently) nbnd = 2 ; chars = 8 ; lev = 32 ; ilev = 33 ; variables: double lat(ncol) ; lat:_FillValue = -900. ; lat:long_name = "latitude" ; lat:units = "degrees_north" ; double lon(ncol) ; lon:_FillValue = -900. ; lon:long_name = "longitude" ; lon:units = "degrees_east" ; double area(ncol) ; area:_FillValue = -900. ; area:long_name = "MPAS cell areas" ; double lev(lev) ; lev:long_name = "zeta level index at vertical midpoints" ; lev:units = "-" ; double ilev(ilev) ; ilev:long_name = "zeta level index at vertical interfaces" ; ilev:units = "-" ; double time(time) ; time:long_name = "time" ; time:units = "days since 1950-01-01 00:00:00" ; time:calendar = "noleap" ; time:bounds = "time_bnds" ; int date(time) ; date:long_name = "current date (YYYYMMDD)" ; int datesec(time) ; datesec:long_name = "current seconds of current date" ; double time_bnds(time, nbnd) ; time_bnds:long_name = "time interval endpoints" ; char date_written(time, chars) ; char time_written(time, chars) ; int ndbase ; ndbase:long_name = "base day" ; int nsbase ; nsbase:long_name = "seconds of base day" ; int nbdate ; nbdate:long_name = "base date (YYYYMMDD)" ; int nbsec ; nbsec:long_name = "seconds of base date" ; int mdt ; mdt:long_name = "timestep" ; mdt:units = "s" ; int ndcur(time) ; ndcur:long_name = "current day (from base day)" ; int nscur(time) ; nscur:long_name = "current seconds of current day" ; double co2vmr(time) ; co2vmr:long_name = "co2 volume mixing ratio" ; double ch4vmr(time) ; ch4vmr:long_name = "ch4 volume mixing ratio" ; double n2ovmr(time) ; n2ovmr:long_name = "n2o volume mixing ratio" ; double f11vmr(time) ; f11vmr:long_name = "f11 volume mixing ratio" ; double f12vmr(time) ; f12vmr:long_name = "f12 volume mixing ratio" ; double sol_tsi(time) ; sol_tsi:long_name = "total solar irradiance" ; sol_tsi:units = "W/m2" ; int nsteph(time) ; nsteph:long_name = "current timestep" ; float ABSORB(time, lev, ncol) ; ABSORB:mdims = 1 ; ABSORB:_FillValue = 1.e+36f ; ABSORB:missing_value = 1.e+36f ; ABSORB:units = "/m" ; ABSORB:long_name = "Aerosol absorption, day only" ; ABSORB:cell_methods = "time: mean" ; float ABSORB_d1(time, lev, ncol) ; ABSORB_d1:mdims = 1 ; ABSORB_d1:_FillValue = 1.e+36f ; ABSORB_d1:missing_value = 1.e+36f ; ABSORB_d1:units = "/m" ; ABSORB_d1:long_name = "Aerosol absorption" ; ABSORB_d1:cell_methods = "time: mean" ; float ABSORBdn(time, lev, ncol) ; ABSORBdn:mdims = 1 ; ABSORBdn:_FillValue = 1.e+36f ; ABSORBdn:missing_value = 1.e+36f ; ABSORBdn:units = "/m" ; ABSORBdn:long_name = "Aerosol absorption, day night" ; ABSORBdn:cell_methods = "time: mean" ; float ADRAIN(time, lev, ncol) ; ADRAIN:mdims = 1 ; ADRAIN:units = "Micron" ; ADRAIN:long_name = "Average rain effective Diameter" ; ADRAIN:cell_methods = "time: mean" ; float ADSNOW(time, lev, ncol) ; ADSNOW:mdims = 1 ; ADSNOW:units = "Micron" ; ADSNOW:long_name = "Average snow effective Diameter" ; ADSNOW:cell_methods = "time: mean" ; float AEROD_v(time, ncol) ; AEROD_v:_FillValue = 1.e+36f ; AEROD_v:missing_value = 1.e+36f ; AEROD_v:units = "1" ; AEROD_v:long_name = "Total Aerosol Optical Depth in visible band" ; AEROD_v:cell_methods = "time: mean" ; float ANRAIN(time, lev, ncol) ; ANRAIN:mdims = 1 ; ANRAIN:units = "m-3" ; ANRAIN:long_name = "Average rain number conc" ; ANRAIN:cell_methods = "time: mean" ; float ANSNOW(time, lev, ncol) ; ANSNOW:mdims = 1 ; ANSNOW:units = "m-3" ; ANSNOW:long_name = "Average snow number conc" ; ANSNOW:cell_methods = "time: mean" ; float AODABS(time, ncol) ; AODABS:_FillValue = 1.e+36f ; AODABS:missing_value = 1.e+36f ; AODABS:long_name = "Aerosol absorption optical depth 550 nm, day only" ; AODABS:cell_methods = "time: mean" ; float AODABSBC(time, ncol) ; AODABSBC:_FillValue = 1.e+36f ; AODABSBC:missing_value = 1.e+36f ; AODABSBC:long_name = "Aerosol absorption optical depth 550 nm from BC, day only" ; AODABSBC:cell_methods = "time: mean" ; float AODABSBCdn(time, ncol) ; AODABSBCdn:_FillValue = 1.e+36f ; AODABSBCdn:missing_value = 1.e+36f ; AODABSBCdn:long_name = "Aerosol absorption optical depth 550 nm from BC, day night" ; AODABSBCdn:cell_methods = "time: mean" ; float AODABS_d1(time, ncol) ; AODABS_d1:_FillValue = 1.e+36f ; AODABS_d1:missing_value = 1.e+36f ; AODABS_d1:long_name = "Aerosol absorption optical depth 550 nm" ; AODABS_d1:cell_methods = "time: mean" ; float AODABSdn(time, ncol) ; AODABSdn:_FillValue = 1.e+36f ; AODABSdn:missing_value = 1.e+36f ; AODABSdn:long_name = "Aerosol absorption optical depth 550 nm, day night" ; AODABSdn:cell_methods = "time: mean" ; float AODBC(time, ncol) ; AODBC:_FillValue = 1.e+36f ; AODBC:missing_value = 1.e+36f ; AODBC:long_name = "Aerosol optical depth 550 nm from BC, day only" ; AODBC:cell_methods = "time: mean" ; float AODBCdn(time, ncol) ; AODBCdn:_FillValue = 1.e+36f ; AODBCdn:missing_value = 1.e+36f ; AODBCdn:long_name = "Aerosol optical depth 550 nm from BC, day night" ; AODBCdn:cell_methods = "time: mean" ; float AODDUST(time, ncol) ; AODDUST:_FillValue = 1.e+36f ; AODDUST:missing_value = 1.e+36f ; AODDUST:long_name = "Aerosol optical depth 550 nm from dust, day only" ; AODDUST:cell_methods = "time: mean" ; float AODDUSTdn(time, ncol) ; AODDUSTdn:_FillValue = 1.e+36f ; AODDUSTdn:missing_value = 1.e+36f ; AODDUSTdn:long_name = "Aerosol optical depth 550 nm from dust, day night" ; AODDUSTdn:cell_methods = "time: mean" ; float AODMODE1(time, ncol) ; AODMODE1:_FillValue = 1.e+36f ; AODMODE1:missing_value = 1.e+36f ; AODMODE1:long_name = "Aerosol optical depth, day only, 550 nm mode 1" ; AODMODE1:cell_methods = "time: mean" ; float AODMODE2(time, ncol) ; AODMODE2:_FillValue = 1.e+36f ; AODMODE2:missing_value = 1.e+36f ; AODMODE2:long_name = "Aerosol optical depth, day only, 550 nm mode 2" ; AODMODE2:cell_methods = "time: mean" ; float AODMODE3(time, ncol) ; AODMODE3:_FillValue = 1.e+36f ; AODMODE3:missing_value = 1.e+36f ; AODMODE3:long_name = "Aerosol optical depth, day only, 550 nm mode 3" ; AODMODE3:cell_methods = "time: mean" ; float AODNIR(time, ncol) ; AODNIR:_FillValue = 1.e+36f ; AODNIR:missing_value = 1.e+36f ; AODNIR:long_name = "Aerosol optical depth 1020 nm, day only" ; AODNIR:cell_methods = "time: mean" ; float AODNIRdn(time, ncol) ; AODNIRdn:_FillValue = 1.e+36f ; AODNIRdn:missing_value = 1.e+36f ; AODNIRdn:long_name = "Aerosol optical depth 1020 nm, day night" ; AODNIRdn:cell_methods = "time: mean" ; float AODPOM(time, ncol) ; AODPOM:_FillValue = 1.e+36f ; AODPOM:missing_value = 1.e+36f ; AODPOM:long_name = "Aerosol optical depth 550 nm from POM, day only" ; AODPOM:cell_methods = "time: mean" ; float AODPOMdn(time, ncol) ; AODPOMdn:_FillValue = 1.e+36f ; AODPOMdn:missing_value = 1.e+36f ; AODPOMdn:long_name = "Aerosol optical depth 550 nm from POM, day night" ; AODPOMdn:cell_methods = "time: mean" ; float AODSO4(time, ncol) ; AODSO4:_FillValue = 1.e+36f ; AODSO4:missing_value = 1.e+36f ; AODSO4:long_name = "Aerosol optical depth 550 nm from SO4, day only" ; AODSO4:cell_methods = "time: mean" ; float AODSO4dn(time, ncol) ; AODSO4dn:_FillValue = 1.e+36f ; AODSO4dn:missing_value = 1.e+36f ; AODSO4dn:long_name = "Aerosol optical depth 550 nm from SO4, day night" ; AODSO4dn:cell_methods = "time: mean" ; float AODSOA(time, ncol) ; AODSOA:_FillValue = 1.e+36f ; AODSOA:missing_value = 1.e+36f ; AODSOA:long_name = "Aerosol optical depth 550 nm from SOA, day only" ; AODSOA:cell_methods = "time: mean" ; float AODSOAdn(time, ncol) ; AODSOAdn:_FillValue = 1.e+36f ; AODSOAdn:missing_value = 1.e+36f ; AODSOAdn:long_name = "Aerosol optical depth 550 nm from SOA, day night" ; AODSOAdn:cell_methods = "time: mean" ; float AODSS(time, ncol) ; AODSS:_FillValue = 1.e+36f ; AODSS:missing_value = 1.e+36f ; AODSS:long_name = "Aerosol optical depth 550 nm from seasalt, day only" ; AODSS:cell_methods = "time: mean" ; float AODSSdn(time, ncol) ; AODSSdn:_FillValue = 1.e+36f ; AODSSdn:missing_value = 1.e+36f ; AODSSdn:long_name = "Aerosol optical depth 550 nm from seasalt, day night" ; AODSSdn:cell_methods = "time: mean" ; float AODUV(time, ncol) ; AODUV:_FillValue = 1.e+36f ; AODUV:missing_value = 1.e+36f ; AODUV:long_name = "Aerosol optical depth 350 nm, day only" ; AODUV:cell_methods = "time: mean" ; float AODUVdn(time, ncol) ; AODUVdn:_FillValue = 1.e+36f ; AODUVdn:missing_value = 1.e+36f ; AODUVdn:long_name = "Aerosol optical depth 350 nm, day night" ; AODUVdn:cell_methods = "time: mean" ; float AODVIS(time, ncol) ; AODVIS:_FillValue = 1.e+36f ; AODVIS:missing_value = 1.e+36f ; AODVIS:long_name = "Aerosol optical depth 550 nm, day only" ; AODVIS:cell_methods = "time: mean" ; float AODVIS_d1(time, ncol) ; AODVIS_d1:_FillValue = 1.e+36f ; AODVIS_d1:missing_value = 1.e+36f ; AODVIS_d1:long_name = "Aerosol optical depth 550 nm" ; AODVIS_d1:cell_methods = "time: mean" ; float AODVISdn(time, ncol) ; AODVISdn:_FillValue = 1.e+36f ; AODVISdn:missing_value = 1.e+36f ; AODVISdn:long_name = "Aerosol optical depth 550 nm, day night" ; AODVISdn:cell_methods = "time: mean" ; float AODVISst_d1(time, ncol) ; AODVISst_d1:_FillValue = 1.e+36f ; AODVISst_d1:missing_value = 1.e+36f ; AODVISst_d1:long_name = "Stratospheric aerosol optical depth 550 nm" ; AODVISst_d1:cell_methods = "time: mean" ; float AODdnDUST1(time, ncol) ; AODdnDUST1:_FillValue = 1.e+36f ; AODdnDUST1:missing_value = 1.e+36f ; AODdnDUST1:long_name = "Aerosol optical depth 550 nm, day night, mode 1 from dust" ; AODdnDUST1:cell_methods = "time: mean" ; float AODdnDUST3(time, ncol) ; AODdnDUST3:_FillValue = 1.e+36f ; AODdnDUST3:missing_value = 1.e+36f ; AODdnDUST3:long_name = "Aerosol optical depth 550 nm, day night, mode 3 from dust" ; AODdnDUST3:cell_methods = "time: mean" ; float AODdnMODE1(time, ncol) ; AODdnMODE1:_FillValue = 1.e+36f ; AODdnMODE1:missing_value = 1.e+36f ; AODdnMODE1:long_name = "Aerosol optical depth 550 nm, day night, mode 1" ; AODdnMODE1:cell_methods = "time: mean" ; float AODdnMODE2(time, ncol) ; AODdnMODE2:_FillValue = 1.e+36f ; AODdnMODE2:missing_value = 1.e+36f ; AODdnMODE2:long_name = "Aerosol optical depth 550 nm, day night, mode 2" ; AODdnMODE2:cell_methods = "time: mean" ; float AODdnMODE3(time, ncol) ; AODdnMODE3:_FillValue = 1.e+36f ; AODdnMODE3:missing_value = 1.e+36f ; AODdnMODE3:long_name = "Aerosol optical depth 550 nm, day night, mode 3" ; AODdnMODE3:cell_methods = "time: mean" ; float AODxASYM(time, ncol) ; AODxASYM:_FillValue = 1.e+36f ; AODxASYM:missing_value = 1.e+36f ; AODxASYM:long_name = "Aerosol optical depth 550 * asymmetry factor, day only" ; AODxASYM:cell_methods = "time: mean" ; float AODxASYMdn(time, ncol) ; AODxASYMdn:_FillValue = 1.e+36f ; AODxASYMdn:missing_value = 1.e+36f ; AODxASYMdn:long_name = "Aerosol optical depth 550 * asymmetry factor, day night" ; AODxASYMdn:cell_methods = "time: mean" ; float AQRAIN(time, lev, ncol) ; AQRAIN:mdims = 1 ; AQRAIN:units = "kg/kg" ; AQRAIN:long_name = "Average rain mixing ratio" ; AQRAIN:cell_methods = "time: mean" ; float AQSNOW(time, lev, ncol) ; AQSNOW:mdims = 1 ; AQSNOW:units = "kg/kg" ; AQSNOW:long_name = "Average snow mixing ratio" ; AQSNOW:cell_methods = "time: mean" ; float AREI(time, lev, ncol) ; AREI:mdims = 1 ; AREI:units = "Micron" ; AREI:long_name = "Average ice effective radius" ; AREI:cell_methods = "time: mean" ; float AREL(time, lev, ncol) ; AREL:mdims = 1 ; AREL:units = "Micron" ; AREL:long_name = "Average droplet effective radius" ; AREL:cell_methods = "time: mean" ; float ATENDKE(time, ncol) ; ATENDKE:units = "W/m2" ; ATENDKE:long_name = "Adjustment Tendency of Total (vertically integrated) kinetic energy" ; ATENDKE:cell_methods = "time: mean" ; float ATENDSE(time, ncol) ; ATENDSE:units = "W/m2" ; ATENDSE:long_name = "Adjustment Tendency of Total (vertically integrated) static energy" ; ATENDSE:cell_methods = "time: mean" ; float AWNC(time, lev, ncol) ; AWNC:mdims = 1 ; AWNC:units = "m-3" ; AWNC:long_name = "Average cloud water number conc" ; AWNC:cell_methods = "time: mean" ; float AWNI(time, lev, ncol) ; AWNI:mdims = 1 ; AWNI:units = "m-3" ; AWNI:long_name = "Average cloud ice number conc" ; AWNI:cell_methods = "time: mean" ; float BURDENBCdn(time, ncol) ; BURDENBCdn:_FillValue = 1.e+36f ; BURDENBCdn:missing_value = 1.e+36f ; BURDENBCdn:units = "kg/m2" ; BURDENBCdn:long_name = "Black carbon aerosol burden, day night" ; BURDENBCdn:cell_methods = "time: mean" ; float BURDENDUSTdn(time, ncol) ; BURDENDUSTdn:_FillValue = 1.e+36f ; BURDENDUSTdn:missing_value = 1.e+36f ; BURDENDUSTdn:units = "kg/m2" ; BURDENDUSTdn:long_name = "Dust aerosol burden, day night" ; BURDENDUSTdn:cell_methods = "time: mean" ; float BURDENPOMdn(time, ncol) ; BURDENPOMdn:_FillValue = 1.e+36f ; BURDENPOMdn:missing_value = 1.e+36f ; BURDENPOMdn:units = "kg/m2" ; BURDENPOMdn:long_name = "POM aerosol burden, day night" ; BURDENPOMdn:cell_methods = "time: mean" ; float BURDENSEASALTdn(time, ncol) ; BURDENSEASALTdn:_FillValue = 1.e+36f ; BURDENSEASALTdn:missing_value = 1.e+36f ; BURDENSEASALTdn:units = "kg/m2" ; BURDENSEASALTdn:long_name = "Seasalt aerosol burden, day night" ; BURDENSEASALTdn:cell_methods = "time: mean" ; float BURDENSO4dn(time, ncol) ; BURDENSO4dn:_FillValue = 1.e+36f ; BURDENSO4dn:missing_value = 1.e+36f ; BURDENSO4dn:units = "kg/m2" ; BURDENSO4dn:long_name = "Sulfate aerosol burden, day night" ; BURDENSO4dn:cell_methods = "time: mean" ; float BURDENSOAdn(time, ncol) ; BURDENSOAdn:_FillValue = 1.e+36f ; BURDENSOAdn:missing_value = 1.e+36f ; BURDENSOAdn:units = "kg/m2" ; BURDENSOAdn:long_name = "SOA aerosol burden, day night" ; BURDENSOAdn:cell_methods = "time: mean" ; float BURDENdn1(time, ncol) ; BURDENdn1:_FillValue = 1.e+36f ; BURDENdn1:missing_value = 1.e+36f ; BURDENdn1:units = "kg/m2" ; BURDENdn1:long_name = "Aerosol burden, day night, mode 1" ; BURDENdn1:cell_methods = "time: mean" ; float BURDENdn2(time, ncol) ; BURDENdn2:_FillValue = 1.e+36f ; BURDENdn2:missing_value = 1.e+36f ; BURDENdn2:units = "kg/m2" ; BURDENdn2:long_name = "Aerosol burden, day night, mode 2" ; BURDENdn2:cell_methods = "time: mean" ; float BURDENdn3(time, ncol) ; BURDENdn3:_FillValue = 1.e+36f ; BURDENdn3:missing_value = 1.e+36f ; BURDENdn3:units = "kg/m2" ; BURDENdn3:long_name = "Aerosol burden, day night, mode 3" ; BURDENdn3:cell_methods = "time: mean" ; float CDNUMC(time, ncol) ; CDNUMC:units = "1/m2" ; CDNUMC:long_name = "Vertically-integrated droplet concentration" ; CDNUMC:cell_methods = "time: mean" ; float CLDBOT(time, ncol) ; CLDBOT:units = "1" ; CLDBOT:long_name = "Vertical index of cloud base" ; CLDBOT:cell_methods = "time: mean" ; float CLDHGH(time, ncol) ; CLDHGH:units = "fraction" ; CLDHGH:long_name = "Vertically-integrated high cloud" ; CLDHGH:cell_methods = "time: mean" ; float CLDICE(time, lev, ncol) ; CLDICE:mdims = 1 ; CLDICE:units = "kg/kg" ; CLDICE:long_name = "Grid box averaged cloud ice amount" ; CLDICE:cell_methods = "time: mean" ; float CLDLIQ(time, lev, ncol) ; CLDLIQ:mdims = 1 ; CLDLIQ:units = "kg/kg" ; CLDLIQ:long_name = "Grid box averaged cloud liquid amount" ; CLDLIQ:cell_methods = "time: mean" ; float CLDLOW(time, ncol) ; CLDLOW:units = "fraction" ; CLDLOW:long_name = "Vertically-integrated low cloud" ; CLDLOW:cell_methods = "time: mean" ; float CLDMED(time, ncol) ; CLDMED:units = "fraction" ; CLDMED:long_name = "Vertically-integrated mid-level cloud" ; CLDMED:cell_methods = "time: mean" ; float CLDTOP(time, ncol) ; CLDTOP:units = "1" ; CLDTOP:long_name = "Vertical index of cloud top" ; CLDTOP:cell_methods = "time: mean" ; float CLDTOT(time, ncol) ; CLDTOT:units = "fraction" ; CLDTOT:long_name = "Vertically-integrated total cloud" ; CLDTOT:cell_methods = "time: mean" ; float CLOUD(time, lev, ncol) ; CLOUD:mdims = 1 ; CLOUD:units = "fraction" ; CLOUD:long_name = "Cloud fraction" ; CLOUD:cell_methods = "time: mean" ; float CMFMC(time, ilev, ncol) ; CMFMC:mdims = 2 ; CMFMC:units = "kg/m2/s" ; CMFMC:long_name = "Moist convection (deep+shallow) mass flux" ; CMFMC:cell_methods = "time: mean" ; float CMFMCDZM(time, ilev, ncol) ; CMFMCDZM:mdims = 2 ; CMFMCDZM:units = "kg/m2/s" ; CMFMCDZM:long_name = "Convection mass flux from ZM deep" ; CMFMCDZM:cell_methods = "time: mean" ; float DTCOND(time, lev, ncol) ; DTCOND:mdims = 1 ; DTCOND:units = "K/s" ; DTCOND:long_name = "T tendency - moist processes" ; DTCOND:cell_methods = "time: mean" ; float DTENDKE(time, ncol) ; DTENDKE:units = "W/m2" ; DTENDKE:long_name = "Dynamic Tendency of Total (vertically integrated) kinetic energy" ; DTENDKE:cell_methods = "time: mean" ; float DTENDSE(time, ncol) ; DTENDSE:units = "W/m2" ; DTENDSE:long_name = "Dynamic Tendency of Total (vertically integrated) static energy" ; DTENDSE:cell_methods = "time: mean" ; float DTENDWI(time, ncol) ; DTENDWI:units = "kg/m2/s" ; DTENDWI:long_name = "Dynamic Tendency of Total (vertically integrated) water ice" ; DTENDWI:cell_methods = "time: mean" ; float DTENDWL(time, ncol) ; DTENDWL:units = "kg/m2/s" ; DTENDWL:long_name = "Dynamic Tendency of Total (vertically integrated) water liquid" ; DTENDWL:cell_methods = "time: mean" ; float DTENDWV(time, ncol) ; DTENDWV:units = "kg/m2/s" ; DTENDWV:long_name = "Dynamic Tendency of Total (vertically integrated) water vapor" ; DTENDWV:cell_methods = "time: mean" ; float DTV(time, lev, ncol) ; DTV:mdims = 1 ; DTV:units = "K/s" ; DTV:long_name = "T vertical diffusion" ; DTV:cell_methods = "time: mean" ; float EFIX(time, ncol) ; EFIX:units = "W/m2" ; EFIX:long_name = "Effective sensible heat flux due to energy fixer" ; EFIX:cell_methods = "time: mean" ; float EXTINCT(time, lev, ncol) ; EXTINCT:mdims = 1 ; EXTINCT:_FillValue = 1.e+36f ; EXTINCT:missing_value = 1.e+36f ; EXTINCT:units = "/m" ; EXTINCT:long_name = "Aerosol extinction 550 nm, day only" ; EXTINCT:cell_methods = "time: mean" ; float EXTINCT_d1(time, lev, ncol) ; EXTINCT_d1:mdims = 1 ; EXTINCT_d1:_FillValue = 1.e+36f ; EXTINCT_d1:missing_value = 1.e+36f ; EXTINCT_d1:units = "/m" ; EXTINCT_d1:long_name = "Aerosol extinction" ; EXTINCT_d1:cell_methods = "time: mean" ; float EXTINCTdn(time, lev, ncol) ; EXTINCTdn:mdims = 1 ; EXTINCTdn:_FillValue = 1.e+36f ; EXTINCTdn:missing_value = 1.e+36f ; EXTINCTdn:units = "/m" ; EXTINCTdn:long_name = "Aerosol extinction 550 nm, day night" ; EXTINCTdn:cell_methods = "time: mean" ; float EXTxASYM(time, lev, ncol) ; EXTxASYM:mdims = 1 ; EXTxASYM:_FillValue = 1.e+36f ; EXTxASYM:missing_value = 1.e+36f ; EXTxASYM:long_name = "extinction 550 nm * asymmetry factor, day only" ; EXTxASYM:cell_methods = "time: mean" ; float EXTxASYMdn(time, lev, ncol) ; EXTxASYMdn:mdims = 1 ; EXTxASYMdn:_FillValue = 1.e+36f ; EXTxASYMdn:missing_value = 1.e+36f ; EXTxASYMdn:long_name = "extinction 550 * asymmetry factor, day night" ; EXTxASYMdn:cell_methods = "time: mean" ; float FICE(time, lev, ncol) ; FICE:mdims = 1 ; FICE:units = "fraction" ; FICE:long_name = "Fractional ice content within cloud" ; FICE:cell_methods = "time: mean" ; float FLDS(time, ncol) ; FLDS:Sampling_Sequence = "rad_lwsw" ; FLDS:units = "W/m2" ; FLDS:long_name = "Downwelling longwave flux at surface" ; FLDS:cell_methods = "time: mean" ; float FLDSC(time, ncol) ; FLDSC:Sampling_Sequence = "rad_lwsw" ; FLDSC:units = "W/m2" ; FLDSC:long_name = "Clearsky Downwelling longwave flux at surface" ; FLDSC:cell_methods = "time: mean" ; float FLDS_d1(time, ncol) ; FLDS_d1:Sampling_Sequence = "rad_lwsw" ; FLDS_d1:units = "W/m2" ; FLDS_d1:long_name = "Downwelling longwave flux at surface" ; FLDS_d1:cell_methods = "time: mean" ; float FLNS(time, ncol) ; FLNS:Sampling_Sequence = "rad_lwsw" ; FLNS:units = "W/m2" ; FLNS:long_name = "Net longwave flux at surface" ; FLNS:cell_methods = "time: mean" ; float FLNSC(time, ncol) ; FLNSC:Sampling_Sequence = "rad_lwsw" ; FLNSC:units = "W/m2" ; FLNSC:long_name = "Clearsky net longwave flux at surface" ; FLNSC:cell_methods = "time: mean" ; float FLNSC_d1(time, ncol) ; FLNSC_d1:Sampling_Sequence = "rad_lwsw" ; FLNSC_d1:units = "W/m2" ; FLNSC_d1:long_name = "Clearsky net longwave flux at surface" ; FLNSC_d1:cell_methods = "time: mean" ; float FLNS_d1(time, ncol) ; FLNS_d1:Sampling_Sequence = "rad_lwsw" ; FLNS_d1:units = "W/m2" ; FLNS_d1:long_name = "Net longwave flux at surface" ; FLNS_d1:cell_methods = "time: mean" ; float FLNT(time, ncol) ; FLNT:Sampling_Sequence = "rad_lwsw" ; FLNT:units = "W/m2" ; FLNT:long_name = "Net longwave flux at top of model" ; FLNT:cell_methods = "time: mean" ; float FLNTC(time, ncol) ; FLNTC:Sampling_Sequence = "rad_lwsw" ; FLNTC:units = "W/m2" ; FLNTC:long_name = "Clearsky net longwave flux at top of model" ; FLNTC:cell_methods = "time: mean" ; float FLNTCLR(time, ncol) ; FLNTCLR:Sampling_Sequence = "rad_lwsw" ; FLNTCLR:units = "W/m2" ; FLNTCLR:long_name = "Clearsky ONLY points net longwave flux at top of model" ; FLNTCLR:cell_methods = "time: mean" ; float FLNTCLR_d1(time, ncol) ; FLNTCLR_d1:Sampling_Sequence = "rad_lwsw" ; FLNTCLR_d1:units = "W/m2" ; FLNTCLR_d1:long_name = "Clearsky ONLY points net longwave flux at top of model" ; FLNTCLR_d1:cell_methods = "time: mean" ; float FLNTC_d1(time, ncol) ; FLNTC_d1:Sampling_Sequence = "rad_lwsw" ; FLNTC_d1:units = "W/m2" ; FLNTC_d1:long_name = "Clearsky net longwave flux at top of model" ; FLNTC_d1:cell_methods = "time: mean" ; float FLNT_d1(time, ncol) ; FLNT_d1:Sampling_Sequence = "rad_lwsw" ; FLNT_d1:units = "W/m2" ; FLNT_d1:long_name = "Net longwave flux at top of model" ; FLNT_d1:cell_methods = "time: mean" ; float FLUT(time, ncol) ; FLUT:Sampling_Sequence = "rad_lwsw" ; FLUT:units = "W/m2" ; FLUT:long_name = "Upwelling longwave flux at top of model" ; FLUT:cell_methods = "time: mean" ; float FLUTC(time, ncol) ; FLUTC:Sampling_Sequence = "rad_lwsw" ; FLUTC:units = "W/m2" ; FLUTC:long_name = "Clearsky upwelling longwave flux at top of model" ; FLUTC:cell_methods = "time: mean" ; float FLUTC_d1(time, ncol) ; FLUTC_d1:Sampling_Sequence = "rad_lwsw" ; FLUTC_d1:units = "W/m2" ; FLUTC_d1:long_name = "Clearsky upwelling longwave flux at top of model" ; FLUTC_d1:cell_methods = "time: mean" ; float FLUT_d1(time, ncol) ; FLUT_d1:Sampling_Sequence = "rad_lwsw" ; FLUT_d1:units = "W/m2" ; FLUT_d1:long_name = "Upwelling longwave flux at top of model" ; FLUT_d1:cell_methods = "time: mean" ; float FREQCLR(time, ncol) ; FREQCLR:Sampling_Sequence = "rad_lwsw" ; FREQCLR:units = "Frac" ; FREQCLR:long_name = "Frequency of Occurrence of Clearsky" ; FREQCLR:cell_methods = "time: mean" ; float FREQCLR_d1(time, ncol) ; FREQCLR_d1:Sampling_Sequence = "rad_lwsw" ; FREQCLR_d1:units = "Frac" ; FREQCLR_d1:long_name = "Frequency of Occurrence of Clearsky" ; FREQCLR_d1:cell_methods = "time: mean" ; float FREQI(time, lev, ncol) ; FREQI:mdims = 1 ; FREQI:units = "fraction" ; FREQI:long_name = "Fractional occurrence of ice" ; FREQI:cell_methods = "time: mean" ; float FREQL(time, lev, ncol) ; FREQL:mdims = 1 ; FREQL:units = "fraction" ; FREQL:long_name = "Fractional occurrence of liquid" ; FREQL:cell_methods = "time: mean" ; float FREQR(time, lev, ncol) ; FREQR:mdims = 1 ; FREQR:units = "fraction" ; FREQR:long_name = "Fractional occurrence of rain" ; FREQR:cell_methods = "time: mean" ; float FREQS(time, lev, ncol) ; FREQS:mdims = 1 ; FREQS:units = "fraction" ; FREQS:long_name = "Fractional occurrence of snow" ; FREQS:cell_methods = "time: mean" ; float FREQSH(time, ncol) ; FREQSH:units = "fraction" ; FREQSH:long_name = "Fractional occurance of shallow convection" ; FREQSH:cell_methods = "time: mean" ; float FREQZM(time, ncol) ; FREQZM:units = "fraction" ; FREQZM:long_name = "Fractional occurance of ZM convection" ; FREQZM:cell_methods = "time: mean" ; float FSDS(time, ncol) ; FSDS:Sampling_Sequence = "rad_lwsw" ; FSDS:units = "W/m2" ; FSDS:long_name = "Downwelling solar flux at surface" ; FSDS:cell_methods = "time: mean" ; float FSDSC(time, ncol) ; FSDSC:Sampling_Sequence = "rad_lwsw" ; FSDSC:units = "W/m2" ; FSDSC:long_name = "Clearsky downwelling solar flux at surface" ; FSDSC:cell_methods = "time: mean" ; float FSDSC_d1(time, ncol) ; FSDSC_d1:Sampling_Sequence = "rad_lwsw" ; FSDSC_d1:units = "W/m2" ; FSDSC_d1:long_name = "Clearsky downwelling solar flux at surface" ; FSDSC_d1:cell_methods = "time: mean" ; float FSDS_d1(time, ncol) ; FSDS_d1:Sampling_Sequence = "rad_lwsw" ; FSDS_d1:units = "W/m2" ; FSDS_d1:long_name = "Downwelling solar flux at surface" ; FSDS_d1:cell_methods = "time: mean" ; float FSNS(time, ncol) ; FSNS:Sampling_Sequence = "rad_lwsw" ; FSNS:units = "W/m2" ; FSNS:long_name = "Net solar flux at surface" ; FSNS:cell_methods = "time: mean" ; float FSNSC(time, ncol) ; FSNSC:Sampling_Sequence = "rad_lwsw" ; FSNSC:units = "W/m2" ; FSNSC:long_name = "Clearsky net solar flux at surface" ; FSNSC:cell_methods = "time: mean" ; float FSNSC_d1(time, ncol) ; FSNSC_d1:Sampling_Sequence = "rad_lwsw" ; FSNSC_d1:units = "W/m2" ; FSNSC_d1:long_name = "Clearsky net solar flux at surface" ; FSNSC_d1:cell_methods = "time: mean" ; float FSNS_d1(time, ncol) ; FSNS_d1:Sampling_Sequence = "rad_lwsw" ; FSNS_d1:units = "W/m2" ; FSNS_d1:long_name = "Net solar flux at surface" ; FSNS_d1:cell_methods = "time: mean" ; float FSNT(time, ncol) ; FSNT:Sampling_Sequence = "rad_lwsw" ; FSNT:units = "W/m2" ; FSNT:long_name = "Net solar flux at top of model" ; FSNT:cell_methods = "time: mean" ; float FSNTC(time, ncol) ; FSNTC:Sampling_Sequence = "rad_lwsw" ; FSNTC:units = "W/m2" ; FSNTC:long_name = "Clearsky net solar flux at top of model" ; FSNTC:cell_methods = "time: mean" ; float FSNTC_d1(time, ncol) ; FSNTC_d1:Sampling_Sequence = "rad_lwsw" ; FSNTC_d1:units = "W/m2" ; FSNTC_d1:long_name = "Clearsky net solar flux at top of model" ; FSNTC_d1:cell_methods = "time: mean" ; float FSNTOA(time, ncol) ; FSNTOA:Sampling_Sequence = "rad_lwsw" ; FSNTOA:units = "W/m2" ; FSNTOA:long_name = "Net solar flux at top of atmosphere" ; FSNTOA:cell_methods = "time: mean" ; float FSNTOAC(time, ncol) ; FSNTOAC:Sampling_Sequence = "rad_lwsw" ; FSNTOAC:units = "W/m2" ; FSNTOAC:long_name = "Clearsky net solar flux at top of atmosphere" ; FSNTOAC:cell_methods = "time: mean" ; float FSNTOAC_d1(time, ncol) ; FSNTOAC_d1:Sampling_Sequence = "rad_lwsw" ; FSNTOAC_d1:units = "W/m2" ; FSNTOAC_d1:long_name = "Clearsky net solar flux at top of atmosphere" ; FSNTOAC_d1:cell_methods = "time: mean" ; float FSNTOA_d1(time, ncol) ; FSNTOA_d1:Sampling_Sequence = "rad_lwsw" ; FSNTOA_d1:units = "W/m2" ; FSNTOA_d1:long_name = "Net solar flux at top of atmosphere" ; FSNTOA_d1:cell_methods = "time: mean" ; float FSNT_d1(time, ncol) ; FSNT_d1:Sampling_Sequence = "rad_lwsw" ; FSNT_d1:units = "W/m2" ; FSNT_d1:long_name = "Net solar flux at top of model" ; FSNT_d1:cell_methods = "time: mean" ; float FSUTOA(time, ncol) ; FSUTOA:Sampling_Sequence = "rad_lwsw" ; FSUTOA:units = "W/m2" ; FSUTOA:long_name = "Upwelling solar flux at top of atmosphere" ; FSUTOA:cell_methods = "time: mean" ; float FSUTOA_d1(time, ncol) ; FSUTOA_d1:Sampling_Sequence = "rad_lwsw" ; FSUTOA_d1:units = "W/m2" ; FSUTOA_d1:long_name = "Upwelling solar flux at top of atmosphere" ; FSUTOA_d1:cell_methods = "time: mean" ; float ICEFRAC(time, ncol) ; ICEFRAC:units = "fraction" ; ICEFRAC:long_name = "Fraction of sfc area covered by sea-ice" ; ICEFRAC:cell_methods = "time: mean" ; float ICIMR(time, lev, ncol) ; ICIMR:mdims = 1 ; ICIMR:units = "kg/kg" ; ICIMR:long_name = "Prognostic in-cloud ice mixing ratio" ; ICIMR:cell_methods = "time: mean" ; float ICWMR(time, lev, ncol) ; ICWMR:mdims = 1 ; ICWMR:units = "kg/kg" ; ICWMR:long_name = "Prognostic in-cloud water mixing ratio" ; ICWMR:cell_methods = "time: mean" ; float IWC(time, lev, ncol) ; IWC:mdims = 1 ; IWC:units = "kg/m3" ; IWC:long_name = "Grid box average ice water content" ; IWC:cell_methods = "time: mean" ; float KPBL(time, ncol) ; KPBL:units = "index" ; KPBL:long_name = "PBL top layer" ; KPBL:cell_methods = "time: mean" ; float LANDFRAC(time, ncol) ; LANDFRAC:units = "fraction" ; LANDFRAC:long_name = "Fraction of sfc area covered by land" ; LANDFRAC:cell_methods = "time: mean" ; float LHFLX(time, ncol) ; LHFLX:units = "W/m2" ; LHFLX:long_name = "Surface latent heat flux" ; LHFLX:cell_methods = "time: mean" ; float LWCF(time, ncol) ; LWCF:Sampling_Sequence = "rad_lwsw" ; LWCF:units = "W/m2" ; LWCF:long_name = "Longwave cloud forcing" ; LWCF:cell_methods = "time: mean" ; float LWCF_d1(time, ncol) ; LWCF_d1:Sampling_Sequence = "rad_lwsw" ; LWCF_d1:units = "W/m2" ; LWCF_d1:long_name = "Longwave cloud forcing" ; LWCF_d1:cell_methods = "time: mean" ; float OCNFRAC(time, ncol) ; OCNFRAC:units = "fraction" ; OCNFRAC:long_name = "Fraction of sfc area covered by ocean" ; OCNFRAC:cell_methods = "time: mean" ; float ODV_VOLC_MMR(time, ncol) ; ODV_VOLC_MMR:_FillValue = 1.e+36f ; ODV_VOLC_MMR:missing_value = 1.e+36f ; ODV_VOLC_MMR:units = "1" ; ODV_VOLC_MMR:long_name = "VOLC_MMR optical depth in visible band" ; ODV_VOLC_MMR:cell_methods = "time: mean" ; float OMEGA(time, lev, ncol) ; OMEGA:mdims = 1 ; OMEGA:units = "Pa/s" ; OMEGA:long_name = "Vertical velocity (pressure)" ; OMEGA:cell_methods = "time: mean" ; float OMEGAT(time, lev, ncol) ; OMEGAT:mdims = 1 ; OMEGAT:units = "K Pa/s" ; OMEGAT:long_name = "Vertical heat flux" ; OMEGAT:cell_methods = "time: mean" ; float PBLH(time, ncol) ; PBLH:units = "m" ; PBLH:long_name = "PBL height" ; PBLH:cell_methods = "time: mean" ; float PCONVB(time, ncol) ; PCONVB:units = "Pa" ; PCONVB:long_name = "convection base pressure" ; PCONVB:cell_methods = "time: mean" ; float PCONVT(time, ncol) ; PCONVT:units = "Pa" ; PCONVT:long_name = "convection top pressure" ; PCONVT:cell_methods = "time: mean" ; float PHIS(time, ncol) ; PHIS:units = "m2/s2" ; PHIS:long_name = "Surface geopotential" ; PHIS:cell_methods = "time: mean" ; float PRECC(time, ncol) ; PRECC:units = "m/s" ; PRECC:long_name = "Convective precipitation rate (liq + ice)" ; PRECC:cell_methods = "time: mean" ; float PRECL(time, ncol) ; PRECL:units = "m/s" ; PRECL:long_name = "Large-scale (stable) precipitation rate (liq + ice)" ; PRECL:cell_methods = "time: mean" ; float PRECSC(time, ncol) ; PRECSC:units = "m/s" ; PRECSC:long_name = "Convective snow rate (water equivalent)" ; PRECSC:cell_methods = "time: mean" ; float PRECSL(time, ncol) ; PRECSL:units = "m/s" ; PRECSL:long_name = "Large-scale (stable) snow rate (water equivalent)" ; PRECSL:cell_methods = "time: mean" ; float PRECT(time, ncol) ; PRECT:units = "m/s" ; PRECT:long_name = "Total (convective and large-scale) precipitation rate (liq + ice)" ; PRECT:cell_methods = "time: mean" ; float PRESSURE(time, lev, ncol) ; PRESSURE:mdims = 1 ; PRESSURE:units = "Pa" ; PRESSURE:long_name = "Pressure" ; PRESSURE:cell_methods = "time: mean" ; float PRESSUREi(time, ilev, ncol) ; PRESSUREi:mdims = 2 ; PRESSUREi:units = "Pa" ; PRESSUREi:long_name = "Pressure" ; PRESSUREi:cell_methods = "time: mean" ; float PS(time, ncol) ; PS:units = "Pa" ; PS:long_name = "Surface pressure" ; PS:cell_methods = "time: mean" ; float PSL(time, ncol) ; PSL:units = "Pa" ; PSL:long_name = "Sea level pressure" ; PSL:cell_methods = "time: mean" ; float Q(time, lev, ncol) ; Q:mdims = 1 ; Q:units = "kg/kg" ; Q:long_name = "Specific humidity" ; Q:cell_methods = "time: mean" ; float QFLX(time, ncol) ; QFLX:units = "kg/m2/s" ; QFLX:long_name = "Surface water flux" ; QFLX:cell_methods = "time: mean" ; float QREFHT(time, ncol) ; QREFHT:units = "kg/kg" ; QREFHT:long_name = "Reference height humidity" ; QREFHT:cell_methods = "time: mean" ; float QRL(time, lev, ncol) ; QRL:mdims = 1 ; QRL:Sampling_Sequence = "rad_lwsw" ; QRL:units = "K/s" ; QRL:long_name = "Longwave heating rate" ; QRL:cell_methods = "time: mean" ; float QRL_d1(time, lev, ncol) ; QRL_d1:mdims = 1 ; QRL_d1:Sampling_Sequence = "rad_lwsw" ; QRL_d1:units = "K/s" ; QRL_d1:long_name = "Longwave heating rate" ; QRL_d1:cell_methods = "time: mean" ; float QRS(time, lev, ncol) ; QRS:mdims = 1 ; QRS:Sampling_Sequence = "rad_lwsw" ; QRS:units = "K/s" ; QRS:long_name = "Solar heating rate" ; QRS:cell_methods = "time: mean" ; float QRS_d1(time, lev, ncol) ; QRS_d1:mdims = 1 ; QRS_d1:Sampling_Sequence = "rad_lwsw" ; QRS_d1:units = "K/s" ; QRS_d1:long_name = "Solar heating rate" ; QRS_d1:cell_methods = "time: mean" ; float RAINQM(time, lev, ncol) ; RAINQM:mdims = 1 ; RAINQM:units = "kg/kg" ; RAINQM:long_name = "Grid box averaged rain amount" ; RAINQM:cell_methods = "time: mean" ; float RELHUM(time, lev, ncol) ; RELHUM:mdims = 1 ; RELHUM:units = "percent" ; RELHUM:long_name = "Relative humidity" ; RELHUM:cell_methods = "time: mean" ; float RHREFHT(time, ncol) ; RHREFHT:units = "fraction" ; RHREFHT:long_name = "Reference height relative humidity" ; RHREFHT:cell_methods = "time: mean" ; float SHFLX(time, ncol) ; SHFLX:units = "W/m2" ; SHFLX:long_name = "Surface sensible heat flux" ; SHFLX:cell_methods = "time: mean" ; float SNOWHICE(time, ncol) ; SNOWHICE:units = "m" ; SNOWHICE:long_name = "Snow depth over ice" ; SNOWHICE:cell_methods = "time: mean" ; float SNOWHLND(time, ncol) ; SNOWHLND:units = "m" ; SNOWHLND:long_name = "Water equivalent snow depth" ; SNOWHLND:cell_methods = "time: mean" ; float SNOWQM(time, lev, ncol) ; SNOWQM:mdims = 1 ; SNOWQM:units = "kg/kg" ; SNOWQM:long_name = "Grid box averaged snow amount" ; SNOWQM:cell_methods = "time: mean" ; float SOLIN(time, ncol) ; SOLIN:Sampling_Sequence = "rad_lwsw" ; SOLIN:units = "W/m2" ; SOLIN:long_name = "Solar insolation" ; SOLIN:cell_methods = "time: mean" ; float SOLIN_d1(time, ncol) ; SOLIN_d1:Sampling_Sequence = "rad_lwsw" ; SOLIN_d1:units = "W/m2" ; SOLIN_d1:long_name = "Solar insolation" ; SOLIN_d1:cell_methods = "time: mean" ; float SSAVIS(time, ncol) ; SSAVIS:_FillValue = 1.e+36f ; SSAVIS:missing_value = 1.e+36f ; SSAVIS:long_name = "Aerosol single-scatter albedo, day only" ; SSAVIS:cell_methods = "time: mean" ; float SSAVISdn(time, ncol) ; SSAVISdn:_FillValue = 1.e+36f ; SSAVISdn:missing_value = 1.e+36f ; SSAVISdn:long_name = "Aerosol single-scatter albedo, day night" ; SSAVISdn:cell_methods = "time: mean" ; float SWCF(time, ncol) ; SWCF:Sampling_Sequence = "rad_lwsw" ; SWCF:units = "W/m2" ; SWCF:long_name = "Shortwave cloud forcing" ; SWCF:cell_methods = "time: mean" ; float SWCF_d1(time, ncol) ; SWCF_d1:Sampling_Sequence = "rad_lwsw" ; SWCF_d1:units = "W/m2" ; SWCF_d1:long_name = "Shortwave cloud forcing" ; SWCF_d1:cell_methods = "time: mean" ; float T(time, lev, ncol) ; T:mdims = 1 ; T:units = "K" ; T:long_name = "Temperature" ; T:cell_methods = "time: mean" ; float TAUGWX(time, ncol) ; TAUGWX:units = "N/m2" ; TAUGWX:long_name = "Zonal gravity wave surface stress" ; TAUGWX:cell_methods = "time: mean" ; float TAUGWY(time, ncol) ; TAUGWY:units = "N/m2" ; TAUGWY:long_name = "Meridional gravity wave surface stress" ; TAUGWY:cell_methods = "time: mean" ; float TAUTMSX(time, ncol) ; TAUTMSX:units = "N/m2" ; TAUTMSX:long_name = "Zonal turbulent mountain surface stress" ; TAUTMSX:cell_methods = "time: mean" ; float TAUTMSY(time, ncol) ; TAUTMSY:units = "N/m2" ; TAUTMSY:long_name = "Meridional turbulent mountain surface stress" ; TAUTMSY:cell_methods = "time: mean" ; float TAUX(time, ncol) ; TAUX:units = "N/m2" ; TAUX:long_name = "Zonal surface stress" ; TAUX:cell_methods = "time: mean" ; float TAUY(time, ncol) ; TAUY:units = "N/m2" ; TAUY:long_name = "Meridional surface stress" ; TAUY:cell_methods = "time: mean" ; float TGCLDCWP(time, ncol) ; TGCLDCWP:units = "kg/m2" ; TGCLDCWP:long_name = "Total grid-box cloud water path (liquid and ice)" ; TGCLDCWP:cell_methods = "time: mean" ; float TGCLDIWP(time, ncol) ; TGCLDIWP:units = "kg/m2" ; TGCLDIWP:long_name = "Total grid-box cloud ice water path" ; TGCLDIWP:cell_methods = "time: mean" ; float TGCLDLWP(time, ncol) ; TGCLDLWP:units = "kg/m2" ; TGCLDLWP:long_name = "Total grid-box cloud liquid water path" ; TGCLDLWP:cell_methods = "time: mean" ; float TMKE(time, ncol) ; TMKE:units = "J/m2" ; TMKE:long_name = "Total (vertically integrated) kinetic energy" ; float TMQ(time, ncol) ; TMQ:units = "kg/m2" ; TMQ:long_name = "Total (vertically integrated) precipitable water" ; TMQ:cell_methods = "time: mean" ; float TMSE(time, ncol) ; TMSE:units = "J/m2" ; TMSE:long_name = "Total (vertically integrated) static energy" ; float TMWI(time, ncol) ; TMWI:units = "kg/m2" ; TMWI:long_name = "Total (vertically integrated) water ice" ; float TMWL(time, ncol) ; TMWL:units = "kg/m2" ; TMWL:long_name = "Total (vertically integrated) water liquid" ; float TMWV(time, ncol) ; TMWV:units = "kg/m2" ; TMWV:long_name = "Total (vertically integrated) water vapor" ; float TREFHT(time, ncol) ; TREFHT:units = "K" ; TREFHT:long_name = "Reference height temperature" ; TREFHT:cell_methods = "time: mean" ; float TS(time, ncol) ; TS:units = "K" ; TS:long_name = "Surface temperature (radiative)" ; TS:cell_methods = "time: mean" ; float TSMN(time, ncol) ; TSMN:units = "K" ; TSMN:long_name = "Minimum surface temperature over output period" ; TSMN:cell_methods = "time: mean" ; float TSMX(time, ncol) ; TSMX:units = "K" ; TSMX:long_name = "Maximum surface temperature over output period" ; TSMX:cell_methods = "time: mean" ; float TUH(time, ncol) ; TUH:units = "W/m" ; TUH:long_name = "Total (vertically integrated) zonal moist static energy flux" ; TUH:cell_methods = "time: mean" ; float TUQ(time, ncol) ; TUQ:units = "kg/m2" ; TUQ:long_name = "Total (vertically integrated) zonal water vapor flux" ; TUQ:cell_methods = "time: mean" ; float TVH(time, ncol) ; TVH:units = "W/m" ; TVH:long_name = "Total (vertically integrated) meridional moist static energy flux" ; TVH:cell_methods = "time: mean" ; float TVQ(time, ncol) ; TVQ:units = "kg/m/s" ; TVQ:long_name = "Total (vertically integrated) meridional water vapor flux" ; TVQ:cell_methods = "time: mean" ; float U(time, lev, ncol) ; U:mdims = 1 ; U:units = "m/s" ; U:long_name = "Zonal wind" ; U:cell_methods = "time: mean" ; float U10(time, ncol) ; U10:units = "m/s" ; U10:long_name = "10m wind speed" ; U10:cell_methods = "time: mean" ; float UBOT(time, ncol) ; UBOT:units = "m/s" ; UBOT:long_name = "Lowest model level zonal wind" ; UBOT:cell_methods = "time: mean" ; float UU(time, lev, ncol) ; UU:mdims = 1 ; UU:units = "m2/s2" ; UU:long_name = "Zonal velocity squared" ; UU:cell_methods = "time: mean" ; float V(time, lev, ncol) ; V:mdims = 1 ; V:units = "m/s" ; V:long_name = "Meridional wind" ; V:cell_methods = "time: mean" ; float VBOT(time, ncol) ; VBOT:units = "m/s" ; VBOT:long_name = "Lowest model level meridional wind" ; VBOT:cell_methods = "time: mean" ; float VD01(time, lev, ncol) ; VD01:mdims = 1 ; VD01:units = "kg/kg/s" ; VD01:long_name = "Vertical diffusion of Q" ; VD01:cell_methods = "time: mean" ; float VQ(time, lev, ncol) ; VQ:mdims = 1 ; VQ:units = "m/skg/kg" ; VQ:long_name = "Meridional water transport" ; VQ:cell_methods = "time: mean" ; float VT(time, lev, ncol) ; VT:mdims = 1 ; VT:units = "K m/s" ; VT:long_name = "Meridional heat transport" ; VT:cell_methods = "time: mean" ; float VU(time, lev, ncol) ; VU:mdims = 1 ; VU:units = "m2/s2" ; VU:long_name = "Meridional flux of zonal momentum" ; VU:cell_methods = "time: mean" ; float VV(time, lev, ncol) ; VV:mdims = 1 ; VV:units = "m2/s2" ; VV:long_name = "Meridional velocity squared" ; VV:cell_methods = "time: mean" ; float WGUSTD(time, ncol) ; WGUSTD:units = "m/s" ; WGUSTD:long_name = "wind gusts from turbulence" ; WGUSTD:cell_methods = "time: mean" ; float WSUB(time, lev, ncol) ; WSUB:mdims = 1 ; WSUB:units = "m/s" ; WSUB:long_name = "Diagnostic sub-grid vertical velocity" ; WSUB:cell_methods = "time: mean" ; float XPH_LWC(time, lev, ncol) ; XPH_LWC:mdims = 1 ; XPH_LWC:units = "kg/kg" ; XPH_LWC:long_name = "pH value multiplied by lwc" ; XPH_LWC:cell_methods = "time: mean" ; float Z3(time, lev, ncol) ; Z3:mdims = 1 ; Z3:units = "m" ; Z3:long_name = "Geopotential Height (above sea level)" ; Z3:cell_methods = "time: mean" ; float dgnd_a01(time, lev, ncol) ; dgnd_a01:mdims = 1 ; dgnd_a01:units = "m" ; dgnd_a01:long_name = "dry dgnum, interstitial, mode 01" ; dgnd_a01:cell_methods = "time: mean" ; float dgnd_a02(time, lev, ncol) ; dgnd_a02:mdims = 1 ; dgnd_a02:units = "m" ; dgnd_a02:long_name = "dry dgnum, interstitial, mode 02" ; dgnd_a02:cell_methods = "time: mean" ; float dgnd_a03(time, lev, ncol) ; dgnd_a03:mdims = 1 ; dgnd_a03:units = "m" ; dgnd_a03:long_name = "dry dgnum, interstitial, mode 03" ; dgnd_a03:cell_methods = "time: mean" ; float dgnw_a01(time, lev, ncol) ; dgnw_a01:mdims = 1 ; dgnw_a01:units = "m" ; dgnw_a01:long_name = "wet dgnum, interstitial, mode 01" ; dgnw_a01:cell_methods = "time: mean" ; float dgnw_a02(time, lev, ncol) ; dgnw_a02:mdims = 1 ; dgnw_a02:units = "m" ; dgnw_a02:long_name = "wet dgnum, interstitial, mode 02" ; dgnw_a02:cell_methods = "time: mean" ; float dgnw_a03(time, lev, ncol) ; dgnw_a03:mdims = 1 ; dgnw_a03:units = "m" ; dgnw_a03:long_name = "wet dgnum, interstitial, mode 03" ; dgnw_a03:cell_methods = "time: mean" ; float wat_a1(time, lev, ncol) ; wat_a1:mdims = 1 ; wat_a1:units = "m" ; wat_a1:long_name = "aerosol water, interstitial, mode 01" ; wat_a1:cell_methods = "time: mean" ; float wat_a2(time, lev, ncol) ; wat_a2:mdims = 1 ; wat_a2:units = "m" ; wat_a2:long_name = "aerosol water, interstitial, mode 02" ; wat_a2:cell_methods = "time: mean" ; float wat_a3(time, lev, ncol) ; wat_a3:mdims = 1 ; wat_a3:units = "m" ; wat_a3:long_name = "aerosol water, interstitial, mode 03" ; wat_a3:cell_methods = "time: mean" ; // global attributes: :nCells = 40962 ; :Conventions = "CF-1.0" ; :source = "CAM" ; :case = "HRMIP_mp120a_prod04" ; :logname = "beharrop" ; :host = "login33" ; :initial_file = "/global/cfs/cdirs/m1867/MPASinput/HighResMIP/init/mp120a/mp120a_HRM-GFMACv2spin01_FC54.cam.r.2001-01-01-00000.nc" ; :topography_file = "/global/cfs/cdirs/m1867/MPASinput/mp120a/mp40962a_topo.nc" ; :model_doi_url = "https://doi.org/10.5065/D67H1H0V" ; :time_period_freq = "month_1" ; }