netcdf CESMA/QAqu_deepK/clim/QAqu_deepK.cam.h0.clim.nc { dimensions: lev = 26; ilev = 27; time = UNLIMITED; // (1 currently) lat = 96; lon = 144; slat = 95; slon = 144; nbnd = 2; chars = 8; variables: double lev(lev=26); :long_name = "hybrid level at midpoints (1000*(A+B))"; :units = "level"; :positive = "down"; :standard_name = "atmosphere_hybrid_sigma_pressure_coordinate"; :formula_terms = "a: hyam b: hybm p0: P0 ps: PS"; double hyam(lev=26); :long_name = "hybrid A coefficient at layer midpoints"; double hybm(lev=26); :long_name = "hybrid B coefficient at layer midpoints"; double ilev(ilev=27); :long_name = "hybrid level at interfaces (1000*(A+B))"; :units = "level"; :positive = "down"; :standard_name = "atmosphere_hybrid_sigma_pressure_coordinate"; :formula_terms = "a: hyai b: hybi p0: P0 ps: PS"; double hyai(ilev=27); :long_name = "hybrid A coefficient at layer interfaces"; double hybi(ilev=27); :long_name = "hybrid B coefficient at layer interfaces"; double P0; :long_name = "reference pressure"; :units = "Pa"; double time(time=1); :long_name = "time"; :units = "days since 0001-01-01 00:00:00"; :calendar = "noleap"; :bounds = "time_bnds"; :cell_methods = "time: mean"; int date(time=1); :long_name = "current date (YYYYMMDD)"; :cell_methods = "time: mean"; int datesec(time=1); :long_name = "current seconds of current date"; :cell_methods = "time: mean"; double lat(lat=96); :long_name = "latitude"; :units = "degrees_north"; double lon(lon=144); :long_name = "longitude"; :units = "degrees_east"; double slat(slat=95); :long_name = "staggered latitude"; :units = "degrees_north"; double slon(slon=144); :long_name = "staggered longitude"; :units = "degrees_east"; double w_stag(slat=95); :long_name = "staggered latitude weights"; double time_bnds(time=1, nbnd=2); :long_name = "time interval endpoints"; :cell_methods = "time: mean"; char date_written(time=1, chars=8); :cell_methods = "time: mean"; char time_written(time=1, chars=8); :cell_methods = "time: mean"; int ntrm; :long_name = "spectral truncation parameter M"; int ntrn; :long_name = "spectral truncation parameter N"; int ntrk; :long_name = "spectral truncation parameter K"; int ndbase; :long_name = "base day"; int nsbase; :long_name = "seconds of base day"; int nbdate; :long_name = "base date (YYYYMMDD)"; int nbsec; :long_name = "seconds of base date"; int mdt; :long_name = "timestep"; :units = "s"; int nlon(lat=96); :long_name = "number of longitudes"; int wnummax(lat=96); :long_name = "cutoff Fourier wavenumber"; double gw(lat=96); :long_name = "gauss weights"; int ndcur(time=1); :long_name = "current day (from base day)"; :cell_methods = "time: mean"; int nscur(time=1); :long_name = "current seconds of current day"; :cell_methods = "time: mean"; double co2vmr(time=1); :long_name = "co2 volume mixing ratio"; :cell_methods = "time: mean"; double ch4vmr(time=1); :long_name = "ch4 volume mixing ratio"; :cell_methods = "time: mean"; double n2ovmr(time=1); :long_name = "n2o volume mixing ratio"; :cell_methods = "time: mean"; double f11vmr(time=1); :long_name = "f11 volume mixing ratio"; :cell_methods = "time: mean"; double f12vmr(time=1); :long_name = "f12 volume mixing ratio"; :cell_methods = "time: mean"; double sol_tsi(time=1); :long_name = "total solar irradiance"; :units = "W/m2"; :cell_methods = "time: mean"; int nsteph(time=1); :long_name = "current timestep"; :cell_methods = "time: mean"; float AEROD_v(time=1, lat=96, lon=144); :_FillValue = 1.0E36f; // float :missing_value = 1.0E36f; // float :units = "1"; :long_name = "Total Aerosol Optical Depth in visible band"; :cell_methods = "time: mean time: mean"; float CLDHGH(time=1, lat=96, lon=144); :Sampling_Sequence = "rad_lwsw"; :units = "fraction"; :long_name = "Vertically-integrated high cloud"; :cell_methods = "time: mean time: mean"; float CLDICE(time=1, lev=26, lat=96, lon=144); :mdims = 1; // int :units = "kg/kg"; :long_name = "Grid box averaged cloud ice amount"; :cell_methods = "time: mean time: mean"; float CLDLIQ(time=1, lev=26, lat=96, lon=144); :mdims = 1; // int :units = "kg/kg"; :long_name = "Grid box averaged cloud liquid amount"; :cell_methods = "time: mean time: mean"; float CLDLOW(time=1, lat=96, lon=144); :Sampling_Sequence = "rad_lwsw"; :units = "fraction"; :long_name = "Vertically-integrated low cloud"; :cell_methods = "time: mean time: mean"; float CLDMED(time=1, lat=96, lon=144); :Sampling_Sequence = "rad_lwsw"; :units = "fraction"; :long_name = "Vertically-integrated mid-level cloud"; :cell_methods = "time: mean time: mean"; float CLDTOT(time=1, lat=96, lon=144); :Sampling_Sequence = "rad_lwsw"; :units = "fraction"; :long_name = "Vertically-integrated total cloud"; :cell_methods = "time: mean time: mean"; float CLOUD(time=1, lev=26, lat=96, lon=144); :mdims = 1; // int :Sampling_Sequence = "rad_lwsw"; :units = "fraction"; :long_name = "Cloud fraction"; :cell_methods = "time: mean time: mean"; float CONCLD(time=1, lev=26, lat=96, lon=144); :mdims = 1; // int :units = "fraction"; :long_name = "Convective cloud cover"; :cell_methods = "time: mean time: mean"; float DCQ(time=1, lev=26, lat=96, lon=144); :mdims = 1; // int :units = "kg/kg/s"; :long_name = "Q tendency due to moist processes"; :cell_methods = "time: mean time: mean"; float DTCOND(time=1, lev=26, lat=96, lon=144); :mdims = 1; // int :units = "K/s"; :long_name = "T tendency - moist processes"; :cell_methods = "time: mean time: mean"; float DTV(time=1, lev=26, lat=96, lon=144); :mdims = 1; // int :units = "K/s"; :long_name = "T vertical diffusion"; :cell_methods = "time: mean time: mean"; float EMIS(time=1, lev=26, lat=96, lon=144); :mdims = 1; // int :Sampling_Sequence = "rad_lwsw"; :units = "1"; :long_name = "cloud emissivity"; :cell_methods = "time: mean time: mean"; float FICE(time=1, lev=26, lat=96, lon=144); :mdims = 1; // int :units = "fraction"; :long_name = "Fractional ice content within cloud"; :cell_methods = "time: mean time: mean"; float FLDS(time=1, lat=96, lon=144); :Sampling_Sequence = "rad_lwsw"; :units = "W/m2"; :long_name = "Downwelling longwave flux at surface"; :cell_methods = "time: mean time: mean"; float FLDSC(time=1, lat=96, lon=144); :Sampling_Sequence = "rad_lwsw"; :units = "W/m2"; :long_name = "Clearsky downwelling longwave flux at surface"; :cell_methods = "time: mean time: mean"; float FLNS(time=1, lat=96, lon=144); :Sampling_Sequence = "rad_lwsw"; :units = "W/m2"; :long_name = "Net longwave flux at surface"; :cell_methods = "time: mean time: mean"; float FLNSC(time=1, lat=96, lon=144); :Sampling_Sequence = "rad_lwsw"; :units = "W/m2"; :long_name = "Clearsky net longwave flux at surface"; :cell_methods = "time: mean time: mean"; float FLNT(time=1, lat=96, lon=144); :Sampling_Sequence = "rad_lwsw"; :units = "W/m2"; :long_name = "Net longwave flux at top of model"; :cell_methods = "time: mean time: mean"; float FLNTC(time=1, lat=96, lon=144); :Sampling_Sequence = "rad_lwsw"; :units = "W/m2"; :long_name = "Clearsky net longwave flux at top of model"; :cell_methods = "time: mean time: mean"; float FLUT(time=1, lat=96, lon=144); :Sampling_Sequence = "rad_lwsw"; :units = "W/m2"; :long_name = "Upwelling longwave flux at top of model"; :cell_methods = "time: mean time: mean"; float FLUTC(time=1, lat=96, lon=144); :Sampling_Sequence = "rad_lwsw"; :units = "W/m2"; :long_name = "Clearsky upwelling longwave flux at top of model"; :cell_methods = "time: mean time: mean"; float FSDS(time=1, lat=96, lon=144); :Sampling_Sequence = "rad_lwsw"; :units = "W/m2"; :long_name = "Downwelling solar flux at surface"; :cell_methods = "time: mean time: mean"; float FSDSC(time=1, lat=96, lon=144); :Sampling_Sequence = "rad_lwsw"; :units = "W/m2"; :long_name = "Clearsky downwelling solar flux at surface"; :cell_methods = "time: mean time: mean"; float FSDTOA(time=1, lat=96, lon=144); :Sampling_Sequence = "rad_lwsw"; :units = "W/m2"; :long_name = "Downwelling solar flux at top of atmosphere"; :cell_methods = "time: mean time: mean"; float FSNS(time=1, lat=96, lon=144); :Sampling_Sequence = "rad_lwsw"; :units = "W/m2"; :long_name = "Net solar flux at surface"; :cell_methods = "time: mean time: mean"; float FSNSC(time=1, lat=96, lon=144); :Sampling_Sequence = "rad_lwsw"; :units = "W/m2"; :long_name = "Clearsky net solar flux at surface"; :cell_methods = "time: mean time: mean"; float FSNT(time=1, lat=96, lon=144); :Sampling_Sequence = "rad_lwsw"; :units = "W/m2"; :long_name = "Net solar flux at top of model"; :cell_methods = "time: mean time: mean"; float FSNTC(time=1, lat=96, lon=144); :Sampling_Sequence = "rad_lwsw"; :units = "W/m2"; :long_name = "Clearsky net solar flux at top of model"; :cell_methods = "time: mean time: mean"; float FSNTOA(time=1, lat=96, lon=144); :Sampling_Sequence = "rad_lwsw"; :units = "W/m2"; :long_name = "Net solar flux at top of atmosphere"; :cell_methods = "time: mean time: mean"; float FSNTOAC(time=1, lat=96, lon=144); :Sampling_Sequence = "rad_lwsw"; :units = "W/m2"; :long_name = "Clearsky net solar flux at top of atmosphere"; :cell_methods = "time: mean time: mean"; float FSUTOA(time=1, lat=96, lon=144); :Sampling_Sequence = "rad_lwsw"; :units = "W/m2"; :long_name = "Upwelling solar flux at top of atmosphere"; :cell_methods = "time: mean time: mean"; float ICEFRAC(time=1, lat=96, lon=144); :units = "fraction"; :long_name = "Fraction of sfc area covered by sea-ice"; :cell_methods = "time: mean time: mean"; float ICIMR(time=1, lev=26, lat=96, lon=144); :mdims = 1; // int :units = "kg/kg"; :long_name = "Prognostic in-cloud ice mixing ratio"; :cell_methods = "time: mean time: mean"; float ICWMR(time=1, lev=26, lat=96, lon=144); :mdims = 1; // int :units = "kg/kg"; :long_name = "Prognostic in-cloud water mixing ratio"; :cell_methods = "time: mean time: mean"; float LANDFRAC(time=1, lat=96, lon=144); :units = "fraction"; :long_name = "Fraction of sfc area covered by land"; :cell_methods = "time: mean time: mean"; float LHFLX(time=1, lat=96, lon=144); :units = "W/m2"; :long_name = "Surface latent heat flux"; :cell_methods = "time: mean time: mean"; float LWCF(time=1, lat=96, lon=144); :Sampling_Sequence = "rad_lwsw"; :units = "W/m2"; :long_name = "Longwave cloud forcing"; :cell_methods = "time: mean time: mean"; float OCNFRAC(time=1, lat=96, lon=144); :units = "fraction"; :long_name = "Fraction of sfc area covered by ocean"; :cell_methods = "time: mean time: mean"; float OMEGA(time=1, lev=26, lat=96, lon=144); :mdims = 1; // int :units = "Pa/s"; :long_name = "Vertical velocity (pressure)"; :cell_methods = "time: mean time: mean"; float OMEGAT(time=1, lev=26, lat=96, lon=144); :mdims = 1; // int :units = "K Pa/s"; :long_name = "Vertical heat flux"; :cell_methods = "time: mean time: mean"; float PBLH(time=1, lat=96, lon=144); :units = "m"; :long_name = "PBL height"; :cell_methods = "time: mean time: mean"; float PHIS(time=1, lat=96, lon=144); :units = "m2/s2"; :long_name = "Surface geopotential"; :cell_methods = "time: mean"; float PRECC(time=1, lat=96, lon=144); :units = "m/s"; :long_name = "Convective precipitation rate (liq + ice)"; :cell_methods = "time: mean time: mean"; float PRECL(time=1, lat=96, lon=144); :units = "m/s"; :long_name = "Large-scale (stable) precipitation rate (liq + ice)"; :cell_methods = "time: mean time: mean"; float PRECSC(time=1, lat=96, lon=144); :units = "m/s"; :long_name = "Convective snow rate (water equivalent)"; :cell_methods = "time: mean time: mean"; float PRECSL(time=1, lat=96, lon=144); :units = "m/s"; :long_name = "Large-scale (stable) snow rate (water equivalent)"; :cell_methods = "time: mean time: mean"; float PS(time=1, lat=96, lon=144); :units = "Pa"; :long_name = "Surface pressure"; :cell_methods = "time: mean time: mean"; float PSL(time=1, lat=96, lon=144); :units = "Pa"; :long_name = "Sea level pressure"; :cell_methods = "time: mean time: mean"; float Q(time=1, lev=26, lat=96, lon=144); :mdims = 1; // int :units = "kg/kg"; :long_name = "Specific humidity"; :cell_methods = "time: mean time: mean"; float QFLX(time=1, lat=96, lon=144); :units = "kg/m2/s"; :long_name = "Surface water flux"; :cell_methods = "time: mean time: mean"; float QREFHT(time=1, lat=96, lon=144); :units = "kg/kg"; :long_name = "Reference height humidity"; :cell_methods = "time: mean time: mean"; float QRL(time=1, lev=26, lat=96, lon=144); :mdims = 1; // int :Sampling_Sequence = "rad_lwsw"; :units = "K/s"; :long_name = "Longwave heating rate"; :cell_methods = "time: mean time: mean"; float QRS(time=1, lev=26, lat=96, lon=144); :mdims = 1; // int :Sampling_Sequence = "rad_lwsw"; :units = "K/s"; :long_name = "Solar heating rate"; :cell_methods = "time: mean time: mean"; float RELHUM(time=1, lev=26, lat=96, lon=144); :mdims = 1; // int :units = "percent"; :long_name = "Relative humidity"; :cell_methods = "time: mean time: mean"; float SFCLDICE(time=1, lat=96, lon=144); :units = "kg/m2/s"; :long_name = "CLDICE surface flux"; :cell_methods = "time: mean time: mean"; float SFCLDLIQ(time=1, lat=96, lon=144); :units = "kg/m2/s"; :long_name = "CLDLIQ surface flux"; :cell_methods = "time: mean time: mean"; float SHFLX(time=1, lat=96, lon=144); :units = "W/m2"; :long_name = "Surface sensible heat flux"; :cell_methods = "time: mean time: mean"; float SNOWHICE(time=1, lat=96, lon=144); :units = "m"; :long_name = "Snow depth over ice"; :cell_methods = "time: mean time: mean"; float SNOWHLND(time=1, lat=96, lon=144); :units = "m"; :long_name = "Water equivalent snow depth"; :cell_methods = "time: mean time: mean"; float SOLIN(time=1, lat=96, lon=144); :Sampling_Sequence = "rad_lwsw"; :units = "W/m2"; :long_name = "Solar insolation"; :cell_methods = "time: mean time: mean"; float SWCF(time=1, lat=96, lon=144); :Sampling_Sequence = "rad_lwsw"; :units = "W/m2"; :long_name = "Shortwave cloud forcing"; :cell_methods = "time: mean time: mean"; float T(time=1, lev=26, lat=96, lon=144); :mdims = 1; // int :units = "K"; :long_name = "Temperature"; :cell_methods = "time: mean time: mean"; float TAUX(time=1, lat=96, lon=144); :units = "N/m2"; :long_name = "Zonal surface stress"; :cell_methods = "time: mean time: mean"; float TAUY(time=1, lat=96, lon=144); :units = "N/m2"; :long_name = "Meridional surface stress"; :cell_methods = "time: mean time: mean"; float TGCLDCWP(time=1, lat=96, lon=144); :Sampling_Sequence = "rad_lwsw"; :units = "gram/m2"; :long_name = "Total grid-box cloud water path (liquid and ice)"; :cell_methods = "time: mean time: mean"; float TGCLDIWP(time=1, lat=96, lon=144); :Sampling_Sequence = "rad_lwsw"; :units = "gram/m2"; :long_name = "Total grid-box cloud ice water path"; :cell_methods = "time: mean time: mean"; float TGCLDLWP(time=1, lat=96, lon=144); :Sampling_Sequence = "rad_lwsw"; :units = "gram/m2"; :long_name = "Total grid-box cloud liquid water path"; :cell_methods = "time: mean time: mean"; float TMQ(time=1, lat=96, lon=144); :units = "kg/m2"; :long_name = "Total (vertically integrated) precipitable water"; :cell_methods = "time: mean time: mean"; float TREFHT(time=1, lat=96, lon=144); :units = "K"; :long_name = "Reference height temperature"; :cell_methods = "time: mean time: mean"; float TS(time=1, lat=96, lon=144); :units = "K"; :long_name = "Surface temperature (radiative)"; :cell_methods = "time: mean time: mean"; float TSMN(time=1, lat=96, lon=144); :units = "K"; :long_name = "Minimum surface temperature over output period"; :cell_methods = "time: minimum time: mean"; float TSMX(time=1, lat=96, lon=144); :units = "K"; :long_name = "Maximum surface temperature over output period"; :cell_methods = "time: maximum time: mean"; float U(time=1, lev=26, lat=96, lon=144); :mdims = 1; // int :units = "m/s"; :long_name = "Zonal wind"; :cell_methods = "time: mean time: mean"; float U10(time=1, lat=96, lon=144); :units = "m/s"; :long_name = "10m wind speed"; :cell_methods = "time: mean time: mean"; float UU(time=1, lev=26, lat=96, lon=144); :mdims = 1; // int :units = "m2/s2"; :long_name = "Zonal velocity squared"; :cell_methods = "time: mean time: mean"; float V(time=1, lev=26, lat=96, lon=144); :mdims = 1; // int :units = "m/s"; :long_name = "Meridional wind"; :cell_methods = "time: mean time: mean"; float VD01(time=1, lev=26, lat=96, lon=144); :mdims = 1; // int :units = "kg/kg/s"; :long_name = "Vertical diffusion of Q"; :cell_methods = "time: mean time: mean"; float VQ(time=1, lev=26, lat=96, lon=144); :mdims = 1; // int :units = "m/skg/kg"; :long_name = "Meridional water transport"; :cell_methods = "time: mean time: mean"; float VT(time=1, lev=26, lat=96, lon=144); :mdims = 1; // int :units = "K m/s"; :long_name = "Meridional heat transport"; :cell_methods = "time: mean time: mean"; float VU(time=1, lev=26, lat=96, lon=144); :mdims = 1; // int :units = "m2/s2"; :long_name = "Meridional flux of zonal momentum"; :cell_methods = "time: mean time: mean"; float VV(time=1, lev=26, lat=96, lon=144); :mdims = 1; // int :units = "m2/s2"; :long_name = "Meridional velocity squared"; :cell_methods = "time: mean time: mean"; float Z3(time=1, lev=26, lat=96, lon=144); :mdims = 1; // int :units = "m"; :long_name = "Geopotential Height (above sea level)"; :cell_methods = "time: mean time: mean"; // global attributes: :Conventions = "CF-1.0"; :source = "CAM"; :case = "QAqu_deepK"; :title = "UNSET"; :logname = "br546577"; :host = "snow-09.rit.alba"; :Version = "$Name$"; :revision_Id = "$Id$"; :initial_file = "/data/rose_scr/cesm_inputdata/atm/cam/inic/fv/ncdata_aqua_1.9x2.5.nc"; :topography_file = "/data/rose_scr/cesm_inputdata/atm/cam/topo/USGS_aqua_topo_1.9x2.5.nc"; :history = "Sat Jun 14 12:51:07 2014: ncra /data/rose_scr/cesmruns/archive/QAqu_deepK/atm/hist/QAqu_deepK.cam.h0.0041-01.nc /data/rose_scr/cesmruns/archive/QAqu_deepK/atm/hist/QAqu_deepK.cam.h0.0041-02.nc /data/rose_scr/cesmruns/archive/QAqu_deepK/atm/hist/QAqu_deepK.cam.h0.0041-03.nc /data/rose_scr/cesmruns/archive/QAqu_deepK/atm/hist/QAqu_deepK.cam.h0.0041-04.nc 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/data/rose_scr/cesmruns/archive/QAqu_deepK/atm/hist/QAqu_deepK.cam.h0.0049-05.nc /data/rose_scr/cesmruns/archive/QAqu_deepK/atm/hist/QAqu_deepK.cam.h0.0049-06.nc /data/rose_scr/cesmruns/archive/QAqu_deepK/atm/hist/QAqu_deepK.cam.h0.0049-07.nc /data/rose_scr/cesmruns/archive/QAqu_deepK/atm/hist/QAqu_deepK.cam.h0.0049-08.nc /data/rose_scr/cesmruns/archive/QAqu_deepK/atm/hist/QAqu_deepK.cam.h0.0049-09.nc /data/rose_scr/cesmruns/archive/QAqu_deepK/atm/hist/QAqu_deepK.cam.h0.0049-10.nc /data/rose_scr/cesmruns/archive/QAqu_deepK/atm/hist/QAqu_deepK.cam.h0.0049-11.nc /data/rose_scr/cesmruns/archive/QAqu_deepK/atm/hist/QAqu_deepK.cam.h0.0049-12.nc /data/rose_scr/cesmruns/archive/QAqu_deepK/atm/hist/QAqu_deepK.cam.h0.0050-01.nc /data/rose_scr/cesmruns/archive/QAqu_deepK/atm/hist/QAqu_deepK.cam.h0.0050-02.nc /data/rose_scr/cesmruns/archive/QAqu_deepK/atm/hist/QAqu_deepK.cam.h0.0050-03.nc /data/rose_scr/cesmruns/archive/QAqu_deepK/atm/hist/QAqu_deepK.cam.h0.0050-04.nc /data/rose_scr/cesmruns/archive/QAqu_deepK/atm/hist/QAqu_deepK.cam.h0.0050-05.nc /data/rose_scr/cesmruns/archive/QAqu_deepK/atm/hist/QAqu_deepK.cam.h0.0050-06.nc /data/rose_scr/cesmruns/archive/QAqu_deepK/atm/hist/QAqu_deepK.cam.h0.0050-07.nc /data/rose_scr/cesmruns/archive/QAqu_deepK/atm/hist/QAqu_deepK.cam.h0.0050-08.nc /data/rose_scr/cesmruns/archive/QAqu_deepK/atm/hist/QAqu_deepK.cam.h0.0050-09.nc /data/rose_scr/cesmruns/archive/QAqu_deepK/atm/hist/QAqu_deepK.cam.h0.0050-10.nc /data/rose_scr/cesmruns/archive/QAqu_deepK/atm/hist/QAqu_deepK.cam.h0.0050-11.nc /data/rose_scr/cesmruns/archive/QAqu_deepK/atm/hist/QAqu_deepK.cam.h0.0050-12.nc /network/rit/lab/roselab_rit/cesm/cesm1_2_1/aquaplanet_som/clim/QAqu_deepK.cam.h0.clim.nc"; :nco_openmp_thread_number = 1; // int }