netcdf PRIMAVERA_hist_atm_m01_1_7441033969749845474 {
dimensions:
time = UNLIMITED ; // (12 currently)
lat = 192 ;
lon = 384 ;
variables:
double aclcov(time, lat, lon) ;
aclcov:CDI_grid_num_LPE = 96 ;
aclcov:CDI_grid_type = "gaussian" ;
aclcov:code = 164 ;
aclcov:long_name = "total cloud cover (mean)" ;
aclcov:standard_name = "cloud_area_fraction" ;
aclcov:table = 128 ;
aclcov:units = "1" ;
float abso4(time, lat, lon) ;
abso4:long_name = "antropogenic sulfur burden" ;
abso4:units = "kg m-2" ;
abso4:code = 235 ;
abso4:table = 128 ;
abso4:CDI_grid_type = "gaussian" ;
abso4:CDI_grid_num_LPE = 96 ;
float ahfcon(time, lat, lon) ;
ahfcon:long_name = "conductive heat flux through ice" ;
ahfcon:units = "W m-2" ;
ahfcon:code = 208 ;
ahfcon:table = 128 ;
ahfcon:CDI_grid_type = "gaussian" ;
ahfcon:CDI_grid_num_LPE = 96 ;
ahfcon:standard_name = "surface_downward_latent_heat_flux" ;
float ahfl(time, lat, lon) ;
ahfl:long_name = "latent heat flux" ;
ahfl:units = "W m-2" ;
ahfl:code = 147 ;
ahfl:table = 128 ;
ahfl:CDI_grid_type = "gaussian" ;
ahfl:CDI_grid_num_LPE = 96 ;
ahfl:standard_name = "surface_downward_latent_heat_flux" ;
float ahfliac(time, lat, lon) ;
ahfliac:long_name = "latent heat flux over ice" ;
ahfliac:units = "W m-2" ;
ahfliac:code = 110 ;
ahfliac:table = 128 ;
ahfliac:CDI_grid_type = "gaussian" ;
ahfliac:CDI_grid_num_LPE = 96 ;
ahfliac:standard_name = "surface_downward_latent_heat_flux" ;
float ahfllac(time, lat, lon) ;
ahfllac:long_name = "latent heat flux over land" ;
ahfllac:units = "W m-2" ;
ahfllac:code = 112 ;
ahfllac:table = 128 ;
ahfllac:CDI_grid_type = "gaussian" ;
ahfllac:CDI_grid_num_LPE = 96 ;
ahfllac:standard_name = "surface_downward_latent_heat_flux" ;
float ahflwac(time, lat, lon) ;
ahflwac:long_name = "latent heat flux over water" ;
ahflwac:units = "W m-2" ;
ahflwac:code = 111 ;
ahflwac:table = 128 ;
ahflwac:CDI_grid_type = "gaussian" ;
ahflwac:CDI_grid_num_LPE = 96 ;
ahflwac:standard_name = "surface_downward_latent_heat_flux" ;
float ahfres(time, lat, lon) ;
ahfres:long_name = "melting of ice" ;
ahfres:units = "W m-2" ;
ahfres:code = 209 ;
ahfres:table = 128 ;
ahfres:CDI_grid_type = "gaussian" ;
ahfres:CDI_grid_num_LPE = 96 ;
float ahfs(time, lat, lon) ;
ahfs:long_name = "sensible heat flux" ;
ahfs:units = "W m-2" ;
ahfs:code = 146 ;
ahfs:table = 128 ;
ahfs:CDI_grid_type = "gaussian" ;
ahfs:CDI_grid_num_LPE = 96 ;
ahfs:standard_name = "surface_downward_sensible_heat_flux" ;
float ahfsiac(time, lat, lon) ;
ahfsiac:long_name = "sensible heat flux over ice" ;
ahfsiac:units = "W m-2" ;
ahfsiac:code = 119 ;
ahfsiac:table = 128 ;
ahfsiac:CDI_grid_type = "gaussian" ;
ahfsiac:CDI_grid_num_LPE = 96 ;
ahfsiac:standard_name = "surface_downward_sensible_heat_flux" ;
float ahfslac(time, lat, lon) ;
ahfslac:long_name = "sensible heat flux over land" ;
ahfslac:units = "W m-2" ;
ahfslac:code = 121 ;
ahfslac:table = 128 ;
ahfslac:CDI_grid_type = "gaussian" ;
ahfslac:CDI_grid_num_LPE = 96 ;
ahfslac:standard_name = "surface_downward_sensible_heat_flux" ;
float ahfswac(time, lat, lon) ;
ahfswac:long_name = "sensible heat flux over water" ;
ahfswac:units = "W m-2" ;
ahfswac:code = 120 ;
ahfswac:table = 128 ;
ahfswac:CDI_grid_type = "gaussian" ;
ahfswac:CDI_grid_num_LPE = 96 ;
ahfswac:standard_name = "surface_downward_sensible_heat_flux" ;
float albedo(time, lat, lon) ;
albedo:long_name = "surface albedo" ;
albedo:code = 175 ;
albedo:table = 128 ;
albedo:CDI_grid_type = "gaussian" ;
albedo:CDI_grid_num_LPE = 96 ;
albedo:standard_name = "surface_albedo" ;
albedo:units = "1" ;
float alsoi(time, lat, lon) ;
alsoi:long_name = "albedo of ice" ;
alsoi:code = 122 ;
alsoi:table = 128 ;
alsoi:CDI_grid_type = "gaussian" ;
alsoi:CDI_grid_num_LPE = 96 ;
alsoi:standard_name = "sea_ice_albedo" ;
alsoi:units = "1" ;
float alsol(time, lat, lon) ;
alsol:long_name = "albedo of land" ;
alsol:code = 124 ;
alsol:table = 128 ;
alsol:CDI_grid_type = "gaussian" ;
alsol:CDI_grid_num_LPE = 96 ;
alsol:standard_name = "soil_albedo" ;
alsol:units = "1" ;
float alsow(time, lat, lon) ;
alsow:long_name = "albedo of water" ;
alsow:code = 123 ;
alsow:table = 128 ;
alsow:CDI_grid_type = "gaussian" ;
alsow:CDI_grid_num_LPE = 96 ;
alsow:standard_name = "surface_albedo" ;
alsow:units = "1" ;
float apmeb(time, lat, lon) ;
apmeb:long_name = "vert. integr. tendencies of water" ;
apmeb:units = "kg m-2 s-1" ;
apmeb:code = 137 ;
apmeb:table = 128 ;
apmeb:CDI_grid_type = "gaussian" ;
apmeb:CDI_grid_num_LPE = 96 ;
float apmegl(time, lat, lon) ;
apmegl:long_name = "P-E over land ice" ;
apmegl:units = "kg m-2 s-1" ;
apmegl:code = 221 ;
apmegl:table = 185 ;
apmegl:CDI_grid_type = "gaussian" ;
apmegl:CDI_grid_num_LPE = 96 ;
apmegl:standard_name = "surface_downward_water_flux" ;
float aprc(time, lat, lon) ;
aprc:long_name = "convective precipitation" ;
aprc:units = "kg m-2 s-1" ;
aprc:code = 143 ;
aprc:table = 128 ;
aprc:CDI_grid_type = "gaussian" ;
aprc:CDI_grid_num_LPE = 96 ;
aprc:standard_name = "convective_precipitation_flux" ;
float aprl(time, lat, lon) ;
aprl:long_name = "large scale precipitation" ;
aprl:units = "kg m-2 s-1" ;
aprl:code = 142 ;
aprl:table = 128 ;
aprl:CDI_grid_type = "gaussian" ;
aprl:CDI_grid_num_LPE = 96 ;
aprl:standard_name = "stratiform_precipitation_flux" ;
float aprs(time, lat, lon) ;
aprs:long_name = "snow fall" ;
aprs:units = "kg m-2 s-1" ;
aprs:code = 144 ;
aprs:table = 128 ;
aprs:CDI_grid_type = "gaussian" ;
aprs:CDI_grid_num_LPE = 96 ;
aprs:standard_name = "snowfall_flux" ;
float aps(time, lat, lon) ;
aps:long_name = "surface pressure" ;
aps:units = "Pa" ;
aps:code = 134 ;
aps:table = 128 ;
aps:CDI_grid_type = "gaussian" ;
aps:CDI_grid_num_LPE = 96 ;
aps:standard_name = "surface_air_pressure" ;
float az0i(time, lat, lon) ;
az0i:long_name = "roughness length over ice" ;
az0i:units = "m" ;
az0i:code = 116 ;
az0i:table = 128 ;
az0i:CDI_grid_type = "gaussian" ;
az0i:CDI_grid_num_LPE = 96 ;
az0i:standard_name = "surface_roughness_length" ;
float az0w(time, lat, lon) ;
az0w:long_name = "roughness length over water" ;
az0w:units = "m" ;
az0w:code = 117 ;
az0w:table = 128 ;
az0w:CDI_grid_type = "gaussian" ;
az0w:CDI_grid_num_LPE = 96 ;
az0w:standard_name = "surface_roughness_length" ;
float dew2(time, lat, lon) ;
dew2:long_name = "2m dew point temperature" ;
dew2:units = "K" ;
dew2:code = 168 ;
dew2:table = 128 ;
dew2:CDI_grid_type = "gaussian" ;
dew2:CDI_grid_num_LPE = 96 ;
dew2:standard_name = "dew_point_temperature" ;
float drain(time, lat, lon) ;
drain:long_name = "drainage" ;
drain:units = "kg m-2 s-1" ;
drain:code = 161 ;
drain:table = 185 ;
drain:CDI_grid_type = "gaussian" ;
drain:CDI_grid_num_LPE = 96 ;
float evap(time, lat, lon) ;
evap:long_name = "evaporation" ;
evap:units = "kg m-2 s-1" ;
evap:code = 182 ;
evap:table = 128 ;
evap:CDI_grid_type = "gaussian" ;
evap:CDI_grid_num_LPE = 96 ;
evap:standard_name = "water_evaporation_flux" ;
float evapiac(time, lat, lon) ;
evapiac:long_name = "evaporation over ice" ;
evapiac:units = "kg m-2 s-1" ;
evapiac:code = 113 ;
evapiac:table = 128 ;
evapiac:CDI_grid_type = "gaussian" ;
evapiac:CDI_grid_num_LPE = 96 ;
evapiac:standard_name = "water_evaporation_flux" ;
float evaplac(time, lat, lon) ;
evaplac:long_name = "evaporation over land" ;
evaplac:units = "kg m-2 s-1" ;
evaplac:code = 115 ;
evaplac:table = 128 ;
evaplac:CDI_grid_type = "gaussian" ;
evaplac:CDI_grid_num_LPE = 96 ;
evaplac:standard_name = "water_evaporation_flux" ;
float evapwac(time, lat, lon) ;
evapwac:long_name = "evaporation over water" ;
evapwac:units = "kg m-2 s-1" ;
evapwac:code = 114 ;
evapwac:table = 128 ;
evapwac:CDI_grid_type = "gaussian" ;
evapwac:CDI_grid_num_LPE = 96 ;
evapwac:standard_name = "water_evaporation_flux" ;
float friac(time, lat, lon) ;
friac:long_name = "ice cover (fraction of grid box)" ;
friac:code = 97 ;
friac:table = 128 ;
friac:CDI_grid_type = "gaussian" ;
friac:CDI_grid_num_LPE = 96 ;
friac:units = "1" ;
float gld(time, lat, lon) ;
gld:long_name = "glacier depth" ;
gld:units = "m" ;
gld:code = 213 ;
gld:table = 128 ;
gld:CDI_grid_type = "gaussian" ;
gld:CDI_grid_num_LPE = 96 ;
gld:standard_name = "land_ice_thickness" ;
float grndflux(time, lat, lon) ;
grndflux:long_name = "surface ground heat flux" ;
grndflux:code = 206 ;
grndflux:table = 185 ;
grndflux:CDI_grid_type = "gaussian" ;
grndflux:CDI_grid_num_LPE = 96 ;
grndflux:units = "Wm-2" ;
grndflux:standard_name = "upward_heat_flux_at_ground_level_in_soil" ;
double lat(lat) ;
lat:standard_name = "latitude" ;
lat:long_name = "latitude" ;
lat:units = "degrees_north" ;
lat:axis = "Y" ;
double lon(lon) ;
lon:standard_name = "longitude" ;
lon:long_name = "longitude" ;
lon:units = "degrees_east" ;
lon:axis = "X" ;
float ocu(time, lat, lon) ;
ocu:long_name = "ocean eastw. velocity (coupled mode)" ;
ocu:units = "m/s" ;
ocu:code = 83 ;
ocu:table = 128 ;
ocu:CDI_grid_type = "gaussian" ;
ocu:CDI_grid_num_LPE = 96 ;
ocu:standard_name = "eastward_sea_water_velocity" ;
float ocv(time, lat, lon) ;
ocv:long_name = "ocean northw. velocity (coupled mode)" ;
ocv:units = "m/s" ;
ocv:code = 84 ;
ocv:table = 128 ;
ocv:CDI_grid_type = "gaussian" ;
ocv:CDI_grid_num_LPE = 96 ;
ocv:standard_name = "northward_sea_water_velocity" ;
float precip(time, lat, lon) ;
precip:long_name = "total precipitation" ;
precip:units = "kg m-2 s-1" ;
precip:code = 4 ;
precip:table = 128 ;
precip:CDI_grid_type = "gaussian" ;
precip:CDI_grid_num_LPE = 96 ;
precip:standard_name = "precipitation_flux" ;
float qvi(time, lat, lon) ;
qvi:long_name = "vertically integrated water vapor" ;
qvi:units = "kg m-2" ;
qvi:code = 230 ;
qvi:table = 128 ;
qvi:CDI_grid_type = "gaussian" ;
qvi:CDI_grid_num_LPE = 96 ;
qvi:standard_name = "atmosphere_mass_content_of_water_vapor" ;
float rogl(time, lat, lon) ;
rogl:long_name = "glacier runoff" ;
rogl:units = "kg m-2 s-1" ;
rogl:code = 215 ;
rogl:table = 185 ;
rogl:CDI_grid_type = "gaussian" ;
rogl:CDI_grid_num_LPE = 96 ;
float runoff(time, lat, lon) ;
runoff:long_name = "surface runoff and drainage" ;
runoff:units = "kg m-2 s-1" ;
runoff:code = 160 ;
runoff:table = 185 ;
runoff:CDI_grid_type = "gaussian" ;
runoff:CDI_grid_num_LPE = 96 ;
runoff:standard_name = "runoff_flux" ;
float runtoc(time, lat, lon) ;
runtoc:long_name = "surface runoff into ocean" ;
runtoc:units = "kg m-2 s-1" ;
runtoc:code = 219 ;
runtoc:table = 180 ;
runtoc:CDI_grid_type = "gaussian" ;
runtoc:CDI_grid_num_LPE = 96 ;
runtoc:standard_name = "water_flux_into_sea_water_from_rivers" ;
float sclf0(time, lat, lon) ;
sclf0:long_name = "SW top cloud forcing (178-187)" ;
sclf0:units = "W m-2" ;
sclf0:code = 191 ;
sclf0:table = 128 ;
sclf0:CDI_grid_type = "gaussian" ;
sclf0:CDI_grid_num_LPE = 96 ;
float seaice(time, lat, lon) ;
seaice:long_name = "ice cover (fraction of 1-SLM)" ;
seaice:code = 210 ;
seaice:table = 128 ;
seaice:CDI_grid_type = "gaussian" ;
seaice:CDI_grid_num_LPE = 96 ;
seaice:units = "1" ;
float siced(time, lat, lon) ;
siced:long_name = "ice depth" ;
siced:units = "m" ;
siced:code = 211 ;
siced:table = 128 ;
siced:CDI_grid_type = "gaussian" ;
siced:CDI_grid_num_LPE = 96 ;
siced:standard_name = "floating_ice_thickness" ;
float slp(time, lat, lon) ;
slp:long_name = "mean sea level pressure" ;
slp:units = "Pa" ;
slp:code = 151 ;
slp:table = 128 ;
slp:CDI_grid_type = "gaussian" ;
slp:CDI_grid_num_LPE = 96 ;
slp:standard_name = "air_pressure_at_mean_sea_level" ;
float sn(time, lat, lon) ;
sn:long_name = "snow depth" ;
sn:units = "m" ;
sn:code = 141 ;
sn:table = 128 ;
sn:CDI_grid_type = "gaussian" ;
sn:CDI_grid_num_LPE = 96 ;
sn:standard_name = "lwe_thickness_of_surface_snow_amount" ;
float snacl(time, lat, lon) ;
snacl:long_name = "snow accumulation over land" ;
snacl:units = "kg m-2 s-1" ;
snacl:code = 222 ;
snacl:table = 185 ;
snacl:CDI_grid_type = "gaussian" ;
snacl:CDI_grid_num_LPE = 96 ;
snacl:standard_name = "tendency_of_surface_snow_amount" ;
float snc(time, lat, lon) ;
snc:long_name = "snow depth at the canopy" ;
snc:units = "m" ;
snc:code = 233 ;
snc:table = 128 ;
snc:CDI_grid_type = "gaussian" ;
snc:CDI_grid_num_LPE = 96 ;
snc:standard_name = "lwe_thickness_of_snowfall_amount" ;
float sni(time, lat, lon) ;
sni:long_name = "water equivalent of snow on ice" ;
sni:units = "m" ;
sni:code = 214 ;
sni:table = 128 ;
sni:CDI_grid_type = "gaussian" ;
sni:CDI_grid_num_LPE = 96 ;
sni:standard_name = "lwe_thickness_of_surface_snow_amount" ;
float snmel(time, lat, lon) ;
snmel:long_name = "snow melt" ;
snmel:units = "kg m-2 s-1" ;
snmel:code = 218 ;
snmel:table = 185 ;
snmel:CDI_grid_type = "gaussian" ;
snmel:CDI_grid_num_LPE = 96 ;
snmel:standard_name = "surface_snow_melt_flux" ;
float sodif(time, lat, lon) ;
sodif:long_name = "diffusivity of soil and land ice" ;
sodif:units = "m^2/s" ;
sodif:code = 228 ;
sodif:table = 185 ;
sodif:CDI_grid_type = "gaussian" ;
sodif:CDI_grid_num_LPE = 96 ;
float sofliac(time, lat, lon) ;
sofliac:long_name = "SW flux over ice" ;
sofliac:units = "W m-2" ;
sofliac:code = 94 ;
sofliac:table = 128 ;
sofliac:CDI_grid_type = "gaussian" ;
sofliac:CDI_grid_num_LPE = 96 ;
sofliac:standard_name = "surface_net_downward_shortwave_flux" ;
float sofllac(time, lat, lon) ;
sofllac:long_name = "SW flux over land" ;
sofllac:units = "W m-2" ;
sofllac:code = 96 ;
sofllac:table = 128 ;
sofllac:CDI_grid_type = "gaussian" ;
sofllac:CDI_grid_num_LPE = 96 ;
sofllac:standard_name = "surface_net_downward_shortwave_flux" ;
float soflwac(time, lat, lon) ;
soflwac:long_name = "SW flux over water" ;
soflwac:units = "W m-2" ;
soflwac:code = 95 ;
soflwac:table = 128 ;
soflwac:CDI_grid_type = "gaussian" ;
soflwac:CDI_grid_num_LPE = 96 ;
soflwac:standard_name = "surface_net_downward_shortwave_flux" ;
float srad0(time, lat, lon) ;
srad0:long_name = "net top solar radiation" ;
srad0:units = "W m-2" ;
srad0:code = 178 ;
srad0:table = 128 ;
srad0:CDI_grid_type = "gaussian" ;
srad0:CDI_grid_num_LPE = 96 ;
srad0:standard_name = "toa_net_downward_shortwave_flux" ;
float srad0d(time, lat, lon) ;
srad0d:long_name = "top incoming solar radiation" ;
srad0d:units = "W m-2" ;
srad0d:code = 184 ;
srad0d:table = 128 ;
srad0d:CDI_grid_type = "gaussian" ;
srad0d:CDI_grid_num_LPE = 96 ;
srad0d:standard_name = "toa_incoming_shortwave_flux" ;
float srad0u(time, lat, lon) ;
srad0u:long_name = "top solar radiation upward" ;
srad0u:units = "W m-2" ;
srad0u:code = 203 ;
srad0u:table = 128 ;
srad0u:CDI_grid_type = "gaussian" ;
srad0u:CDI_grid_num_LPE = 96 ;
srad0u:standard_name = "minus_one_times_toa_outgoing_shortwave_flux" ;
float sradl(time, lat, lon) ;
sradl:long_name = "solar radiation 200mb" ;
sradl:units = "W m-2" ;
sradl:code = 86 ;
sradl:table = 128 ;
sradl:CDI_grid_type = "gaussian" ;
sradl:CDI_grid_num_LPE = 96 ;
sradl:standard_name = "net_downward_shortwave_flux_in_air" ;
float srads(time, lat, lon) ;
srads:long_name = "net surface solar radiation" ;
srads:units = "W m-2" ;
srads:code = 176 ;
srads:table = 128 ;
srads:CDI_grid_type = "gaussian" ;
srads:CDI_grid_num_LPE = 96 ;
srads:standard_name = "surface_net_downward_shortwave_flux" ;
float sradsu(time, lat, lon) ;
sradsu:long_name = "surface solar radiation upward" ;
sradsu:units = "W m-2" ;
sradsu:code = 204 ;
sradsu:table = 128 ;
sradsu:CDI_grid_type = "gaussian" ;
sradsu:CDI_grid_num_LPE = 96 ;
sradsu:standard_name = "minus_one_times_surface_upwelling_shortwave_flux_in_air" ;
float sraf0(time, lat, lon) ;
sraf0:long_name = "net top solar radiation (clear sky)" ;
sraf0:units = "W m-2" ;
sraf0:code = 187 ;
sraf0:table = 128 ;
sraf0:CDI_grid_type = "gaussian" ;
sraf0:CDI_grid_num_LPE = 96 ;
sraf0:standard_name = "toa_net_downward_shortwave_flux_assuming_clear_sky" ;
float srafl(time, lat, lon) ;
srafl:long_name = "solar radiation 200mb (clear sky)" ;
srafl:units = "W m-2" ;
srafl:code = 88 ;
srafl:table = 128 ;
srafl:CDI_grid_type = "gaussian" ;
srafl:CDI_grid_num_LPE = 96 ;
srafl:standard_name = "net_downward_shortwave_flux_in_air_assuming_clear_sky" ;
float srafs(time, lat, lon) ;
srafs:long_name = "net surf. solar radiation (clear sky)" ;
srafs:units = "W m-2" ;
srafs:code = 185 ;
srafs:table = 128 ;
srafs:CDI_grid_type = "gaussian" ;
srafs:CDI_grid_num_LPE = 96 ;
srafs:standard_name = "surface_net_downward_shortwave_flux_assuming_clear_sky" ;
float tclf0(time, lat, lon) ;
tclf0:long_name = "LW top cloud forcing (179-188)" ;
tclf0:units = "W m-2" ;
tclf0:code = 192 ;
tclf0:table = 128 ;
tclf0:CDI_grid_type = "gaussian" ;
tclf0:CDI_grid_num_LPE = 96 ;
float temp2(time, lat, lon) ;
temp2:long_name = "2m temperature" ;
temp2:units = "K" ;
temp2:code = 167 ;
temp2:table = 128 ;
temp2:CDI_grid_type = "gaussian" ;
temp2:CDI_grid_num_LPE = 96 ;
temp2:standard_name = "air_temperature" ;
double time(time) ;
time:standard_name = "time" ;
time:calendar = "proleptic_gregorian" ;
time:axis = "T" ;
time:units = "day as %Y%m%d.%f" ;
float trad0(time, lat, lon) ;
trad0:long_name = "top thermal radiation (OLR)" ;
trad0:units = "W m-2" ;
trad0:code = 179 ;
trad0:table = 128 ;
trad0:CDI_grid_type = "gaussian" ;
trad0:CDI_grid_num_LPE = 96 ;
trad0:standard_name = "toa_net_downward_longwave_flux" ;
float tradl(time, lat, lon) ;
tradl:long_name = "thermal radiation 200mb" ;
tradl:units = "W m-2" ;
tradl:code = 85 ;
tradl:table = 128 ;
tradl:CDI_grid_type = "gaussian" ;
tradl:CDI_grid_num_LPE = 96 ;
tradl:standard_name = "net_downward_longwave_flux_in_air" ;
float trads(time, lat, lon) ;
trads:long_name = "net surface thermal radiation" ;
trads:units = "W m-2" ;
trads:code = 177 ;
trads:table = 128 ;
trads:CDI_grid_type = "gaussian" ;
trads:CDI_grid_num_LPE = 96 ;
trads:standard_name = "surface_net_downward_longwave_flux" ;
float tradsu(time, lat, lon) ;
tradsu:long_name = "surface thermal radiation upward" ;
tradsu:units = "W m-2" ;
tradsu:code = 205 ;
tradsu:table = 128 ;
tradsu:CDI_grid_type = "gaussian" ;
tradsu:CDI_grid_num_LPE = 96 ;
tradsu:standard_name = "minus_one_times_surface_upwelling_longwave_flux_in_air" ;
float traf0(time, lat, lon) ;
traf0:long_name = "net top thermal radiation (clear sky)" ;
traf0:units = "W m-2" ;
traf0:code = 188 ;
traf0:table = 128 ;
traf0:CDI_grid_type = "gaussian" ;
traf0:CDI_grid_num_LPE = 96 ;
traf0:standard_name = "toa_net_downward_longwave_flux_assuming_clear_sky" ;
float trafl(time, lat, lon) ;
trafl:long_name = "thermal radiation 200mb (clear sky)" ;
trafl:units = "W m-2" ;
trafl:code = 87 ;
trafl:table = 128 ;
trafl:CDI_grid_type = "gaussian" ;
trafl:CDI_grid_num_LPE = 96 ;
trafl:standard_name = "net_downward_longwave_flux_in_air_assuming_clear_sky" ;
float trafs(time, lat, lon) ;
trafs:long_name = "net surf. thermal radiation (clear sky)" ;
trafs:units = "W m-2" ;
trafs:code = 186 ;
trafs:table = 128 ;
trafs:CDI_grid_type = "gaussian" ;
trafs:CDI_grid_num_LPE = 96 ;
trafs:standard_name = "surface_net_downward_longwave_flux_assuming_clear_sky" ;
float trfliac(time, lat, lon) ;
trfliac:long_name = "LW flux over ice" ;
trfliac:units = "W m-2" ;
trfliac:code = 91 ;
trfliac:table = 128 ;
trfliac:CDI_grid_type = "gaussian" ;
trfliac:CDI_grid_num_LPE = 96 ;
trfliac:standard_name = "surface_net_downward_longwave_flux" ;
float trfllac(time, lat, lon) ;
trfllac:long_name = "LW flux over land" ;
trfllac:units = "W m-2" ;
trfllac:code = 93 ;
trfllac:table = 128 ;
trfllac:CDI_grid_type = "gaussian" ;
trfllac:CDI_grid_num_LPE = 96 ;
trfllac:standard_name = "surface_net_downward_longwave_flux" ;
float trflwac(time, lat, lon) ;
trflwac:long_name = "LW flux over water" ;
trflwac:units = "W m-2" ;
trflwac:code = 92 ;
trflwac:table = 128 ;
trflwac:CDI_grid_type = "gaussian" ;
trflwac:CDI_grid_num_LPE = 96 ;
trflwac:standard_name = "surface_net_downward_longwave_flux" ;
float tsi(time, lat, lon) ;
tsi:long_name = "surface temperature of ice" ;
tsi:units = "K" ;
tsi:code = 102 ;
tsi:table = 128 ;
tsi:CDI_grid_type = "gaussian" ;
tsi:CDI_grid_num_LPE = 96 ;
float tslm1(time, lat, lon) ;
tslm1:long_name = "surface temperature of land" ;
tslm1:units = "K" ;
tslm1:code = 139 ;
tslm1:table = 128 ;
tslm1:CDI_grid_type = "gaussian" ;
tslm1:CDI_grid_num_LPE = 96 ;
tslm1:standard_name = "surface_temperature" ;
float tsurf(time, lat, lon) ;
tsurf:long_name = "surface temperature" ;
tsurf:units = "K" ;
tsurf:code = 169 ;
tsurf:table = 128 ;
tsurf:CDI_grid_type = "gaussian" ;
tsurf:CDI_grid_num_LPE = 96 ;
tsurf:standard_name = "surface_temperature" ;
float tsw(time, lat, lon) ;
tsw:long_name = "surface temperature of water" ;
tsw:units = "K" ;
tsw:code = 103 ;
tsw:table = 128 ;
tsw:CDI_grid_type = "gaussian" ;
tsw:CDI_grid_num_LPE = 96 ;
tsw:standard_name = "sea_surface_temperature" ;
float u10(time, lat, lon) ;
u10:long_name = "10m u-velocity" ;
u10:units = "m/s" ;
u10:code = 165 ;
u10:table = 128 ;
u10:CDI_grid_type = "gaussian" ;
u10:CDI_grid_num_LPE = 96 ;
u10:standard_name = "eastward_wind" ;
float ustr(time, lat, lon) ;
ustr:long_name = "u-stress" ;
ustr:units = "Pa" ;
ustr:code = 180 ;
ustr:table = 128 ;
ustr:CDI_grid_type = "gaussian" ;
ustr:CDI_grid_num_LPE = 96 ;
ustr:standard_name = "surface_downward_eastward_stress" ;
float ustri(time, lat, lon) ;
ustri:long_name = "zonal wind stress over ice" ;
ustri:units = "Pa" ;
ustri:code = 104 ;
ustri:table = 128 ;
ustri:CDI_grid_type = "gaussian" ;
ustri:CDI_grid_num_LPE = 96 ;
ustri:standard_name = "surface_downward_eastward_stress" ;
float ustrl(time, lat, lon) ;
ustrl:long_name = "zonal wind stress over land" ;
ustrl:units = "Pa" ;
ustrl:code = 108 ;
ustrl:table = 128 ;
ustrl:CDI_grid_type = "gaussian" ;
ustrl:CDI_grid_num_LPE = 96 ;
ustrl:standard_name = "surface_downward_eastward_stress" ;
float ustrw(time, lat, lon) ;
ustrw:long_name = "zonal wind stress over water" ;
ustrw:units = "Pa" ;
ustrw:code = 106 ;
ustrw:table = 128 ;
ustrw:CDI_grid_type = "gaussian" ;
ustrw:CDI_grid_num_LPE = 96 ;
ustrw:standard_name = "surface_downward_eastward_stress" ;
float v10(time, lat, lon) ;
v10:long_name = "10m v-velocity" ;
v10:units = "m/s" ;
v10:code = 166 ;
v10:table = 128 ;
v10:CDI_grid_type = "gaussian" ;
v10:CDI_grid_num_LPE = 96 ;
v10:standard_name = "northward_wind" ;
float vdis(time, lat, lon) ;
vdis:long_name = "boundary layer dissipation" ;
vdis:units = "W m-2" ;
vdis:code = 145 ;
vdis:table = 128 ;
vdis:CDI_grid_type = "gaussian" ;
vdis:CDI_grid_num_LPE = 96 ;
vdis:standard_name = "dissipation_in_atmosphere_boundary_layer" ;
float vdisgw(time, lat, lon) ;
vdisgw:long_name = "gravity wave dissipation" ;
vdisgw:units = "W m-2" ;
vdisgw:code = 197 ;
vdisgw:table = 128 ;
vdisgw:CDI_grid_type = "gaussian" ;
vdisgw:CDI_grid_num_LPE = 96 ;
float vstr(time, lat, lon) ;
vstr:long_name = "v-stress" ;
vstr:units = "Pa" ;
vstr:code = 181 ;
vstr:table = 128 ;
vstr:CDI_grid_type = "gaussian" ;
vstr:CDI_grid_num_LPE = 96 ;
vstr:standard_name = "surface_downward_northward_stress" ;
float vstri(time, lat, lon) ;
vstri:long_name = "meridional wind stress over ice" ;
vstri:units = "Pa" ;
vstri:code = 105 ;
vstri:table = 128 ;
vstri:CDI_grid_type = "gaussian" ;
vstri:CDI_grid_num_LPE = 96 ;
vstri:standard_name = "surface_downward_northward_stress" ;
float vstrl(time, lat, lon) ;
vstrl:long_name = "meridional wind stress over land" ;
vstrl:units = "Pa" ;
vstrl:code = 109 ;
vstrl:table = 128 ;
vstrl:CDI_grid_type = "gaussian" ;
vstrl:CDI_grid_num_LPE = 96 ;
vstrl:standard_name = "surface_downward_northward_stress" ;
float vstrw(time, lat, lon) ;
vstrw:long_name = "meridional wind stress over water" ;
vstrw:units = "Pa" ;
vstrw:code = 107 ;
vstrw:table = 128 ;
vstrw:CDI_grid_type = "gaussian" ;
vstrw:CDI_grid_num_LPE = 96 ;
vstrw:standard_name = "surface_downward_northward_stress" ;
float wimax(time, lat, lon) ;
wimax:long_name = "maximum 10m-wind speed" ;
wimax:units = "m/s" ;
wimax:code = 216 ;
wimax:table = 128 ;
wimax:CDI_grid_type = "gaussian" ;
wimax:CDI_grid_num_LPE = 96 ;
wimax:standard_name = "wind_speed" ;
float wind10(time, lat, lon) ;
wind10:long_name = "10m windspeed" ;
wind10:units = "m/s" ;
wind10:code = 171 ;
wind10:table = 128 ;
wind10:CDI_grid_type = "gaussian" ;
wind10:CDI_grid_num_LPE = 96 ;
wind10:standard_name = "wind_speed" ;
float wl(time, lat, lon) ;
wl:long_name = "skin reservoir content" ;
wl:units = "m" ;
wl:code = 193 ;
wl:table = 128 ;
wl:CDI_grid_type = "gaussian" ;
wl:CDI_grid_num_LPE = 96 ;
wl:standard_name = "lwe_thickness_of_canopy_water_amount" ;
float ws(time, lat, lon) ;
ws:long_name = "soil wetness" ;
ws:units = "m" ;
ws:code = 140 ;
ws:table = 128 ;
ws:CDI_grid_type = "gaussian" ;
ws:CDI_grid_num_LPE = 96 ;
ws:standard_name = "soil_moisture_content" ;
float wsmx(time, lat, lon) ;
wsmx:long_name = "field capacity of soil" ;
wsmx:units = "m" ;
wsmx:code = 229 ;
wsmx:table = 128 ;
wsmx:CDI_grid_type = "gaussian" ;
wsmx:CDI_grid_num_LPE = 96 ;
wsmx:standard_name = "soil_moisture_content_at_field_capacity" ;
float xivi(time, lat, lon) ;
xivi:long_name = "vertically integrated cloud ice" ;
xivi:units = "kg m-2" ;
xivi:code = 150 ;
xivi:table = 128 ;
xivi:CDI_grid_type = "gaussian" ;
xivi:CDI_grid_num_LPE = 96 ;
xivi:standard_name = "atmosphere_mass_content_of_cloud_ice" ;
float xlvi(time, lat, lon) ;
xlvi:long_name = "vertically integrated cloud water" ;
xlvi:units = "kg m-2" ;
xlvi:code = 231 ;
xlvi:table = 128 ;
xlvi:CDI_grid_type = "gaussian" ;
xlvi:CDI_grid_num_LPE = 96 ;
xlvi:standard_name = "atmosphere_mass_content_of_cloud_liquid_water" ;
// global attributes:
:CDI = "Climate Data Interface version 2.2.4 (https://mpimet.mpg.de/cdi)" ;
:Conventions = "CF-1.4" ;
:CDO = "Climate Data Operators version 2.2.0 (https://mpimet.mpg.de/cdo)" ;
:NCO = "netCDF Operators version 5.0.6 (Homepage = http://nco.sf.net, Code = http://github.com/nco/nco)" ;
:institution = "Max Planck Institute for Meteorology, Hamburg 20146, Germany" ;
:activity_id = "HighResMIP" ;
:experiment_id = "hist" ;
:title = "PRIMAVERA: Eddy Rich version of MPI-ESM" ;
:contact = " dian.putrasahan@
nullmpimet.mpg.de
:nominal_resolution = "100 km" ;
:source = "MPIESM 1.2.01" ;
:experiment = "historical atmospheric run" ;
:source_id = "MPI-ESM1-2-ER" ;
:creation_date = "2024-07-16T14:14:52Z" ;
:frequency = "mon" ;
:grid = "native atmosphere T127 gaussian grid (384x192 lonxlat) with 95 levels and top level 0.01 hPa; native ocean TP6M tri-polar grid (3602x2394 lonxlat) with 40 levels" ;
:realm = "atmosphere (echam6.3)" ;
:source_type = "AOGCM" ;
:realization_index = "1" ;
:institution_id = "MPI-M" ;
:history = "2024-07-19T11:56:01Z ; rewrote netcdf files to be compatible with WDCC publication standards" ;
}