netcdf RC1-base-07_scav_gp_accu_1_9015384406846292283 {
dimensions:
time = UNLIMITED ; // (1 currently)
lev = 90 ;
lat = 64 ;
lon = 128 ;
variables:
float Br2_scte(time, lev, lat, lon) ;
Br2_scte:long_name = "Br2 tendency from scavenging" ;
Br2_scte:units = "mol/mol/s" ;
float BrCl_scte(time, lev, lat, lon) ;
BrCl_scte:long_name = "BrCl tendency from scavenging" ;
BrCl_scte:units = "mol/mol/s" ;
float Cl2_scte(time, lev, lat, lon) ;
Cl2_scte:long_name = "Cl2 tendency from scavenging" ;
Cl2_scte:units = "mol/mol/s" ;
float HBr_scte(time, lev, lat, lon) ;
HBr_scte:long_name = "HBr tendency from scavenging" ;
HBr_scte:units = "mol/mol/s" ;
float HCl_scte(time, lev, lat, lon) ;
HCl_scte:long_name = "HCl tendency from scavenging" ;
HCl_scte:units = "mol/mol/s" ;
float HOBr_scte(time, lev, lat, lon) ;
HOBr_scte:long_name = "HOBr tendency from scavenging" ;
HOBr_scte:units = "mol/mol/s" ;
float HOCl_scte(time, lev, lat, lon) ;
HOCl_scte:long_name = "HOCl tendency from scavenging" ;
HOCl_scte:units = "mol/mol/s" ;
float Hp_cloud_cv_ave(time, lev, lat, lon) ;
Hp_cloud_cv_ave:long_name = "convective cloud H+ concentration" ;
Hp_cloud_cv_ave:units = "molecules/kg(air)" ;
float Hp_cloud_ls_ave(time, lev, lat, lon) ;
Hp_cloud_ls_ave:long_name = "large scale cloud H+ concentration" ;
Hp_cloud_ls_ave:units = "molecules/kg(air)" ;
float KPP_rsteps_cloud_cv(time, lev, lat, lon) ;
KPP_rsteps_cloud_cv:long_name = "# of rejected KPP steps for cv cloud integration" ;
KPP_rsteps_cloud_cv:units = "-" ;
float KPP_rsteps_cloud_ls(time, lev, lat, lon) ;
KPP_rsteps_cloud_ls:long_name = "# of rejected KPP steps for ls cloud integration" ;
KPP_rsteps_cloud_ls:units = "-" ;
float KPP_rsteps_rain_cv(time, lev, lat, lon) ;
KPP_rsteps_rain_cv:long_name = "# of rejected KPP steps for cv rain integration" ;
KPP_rsteps_rain_cv:units = "-" ;
float KPP_rsteps_rain_ls(time, lev, lat, lon) ;
KPP_rsteps_rain_ls:long_name = "# of rejected KPP steps for ls cloud integration" ;
KPP_rsteps_rain_ls:units = "-" ;
float KPP_steps_cloud_cv(time, lev, lat, lon) ;
KPP_steps_cloud_cv:long_name = "# of KPP steps for cv cloud integration" ;
KPP_steps_cloud_cv:units = "-" ;
float KPP_steps_cloud_ls(time, lev, lat, lon) ;
KPP_steps_cloud_ls:long_name = "# of KPP steps for ls cloud integration" ;
KPP_steps_cloud_ls:units = "-" ;
float KPP_steps_rain_cv(time, lev, lat, lon) ;
KPP_steps_rain_cv:long_name = "# of KPP steps for cv rain integration" ;
KPP_steps_rain_cv:units = "-" ;
float KPP_steps_rain_ls(time, lev, lat, lon) ;
KPP_steps_rain_ls:long_name = "# of KPP steps for ls rain integration" ;
KPP_steps_rain_ls:units = "-" ;
double YYYYMMDD(time) ;
YYYYMMDD:long_name = "time" ;
YYYYMMDD:units = "days as %Y%m%d.%f" ;
YYYYMMDD:calendar = "gregorian" ;
float aps(time, lat, lon) ;
aps:long_name = "surface pressure" ;
aps:units = "Pa" ;
aps:representation = "GP_2D_HORIZONTAL" ;
aps:grid_type = "gaussian" ;
aps:table = 128 ;
aps:code = 134 ;
aps:REFERENCE_TO = "g3b: aps" ;
float cloudpH_cv(time, lev, lat, lon) ;
cloudpH_cv:long_name = "convective cloud pH" ;
cloudpH_cv:units = "0-14, NA=19.99" ;
float cloudpH_ls(time, lev, lat, lon) ;
cloudpH_ls:long_name = "large scale cloud pH" ;
cloudpH_ls:units = "0-14, NA=19.99" ;
double dt(time) ;
dt:long_name = "delta_time" ;
dt:units = "s" ;
float frac_evap_iwc_cv(time, lev, lat, lon) ;
frac_evap_iwc_cv:long_name = "fraction of evaporation into the largest mode (cloud ice)" ;
frac_evap_iwc_cv:units = "-" ;
float frac_evap_iwc_ls(time, lev, lat, lon) ;
frac_evap_iwc_ls:long_name = "fraction of evaporation into the largest mode (cloud ice)" ;
frac_evap_iwc_ls:units = "-" ;
float frac_evap_lwc_cv(time, lev, lat, lon) ;
frac_evap_lwc_cv:long_name = "fraction of evaporation into the largest mode (cloud water)" ;
frac_evap_lwc_cv:units = "-" ;
float frac_evap_lwc_ls(time, lev, lat, lon) ;
frac_evap_lwc_ls:long_name = "fraction of evaporation into the largest mode (cloud water)" ;
frac_evap_lwc_ls:units = "-" ;
float frac_evap_rain_cv(time, lev, lat, lon) ;
frac_evap_rain_cv:long_name = "fraction of evaporation into the largest mode (rain)" ;
frac_evap_rain_cv:units = "-" ;
float frac_evap_rain_ls(time, lev, lat, lon) ;
frac_evap_rain_ls:long_name = "fraction of evaporation into the largest mode (rain)" ;
frac_evap_rain_ls:units = "-" ;
float frac_evap_snow_cv(time, lev, lat, lon) ;
frac_evap_snow_cv:long_name = "fraction of evaporation into the largest mode (snow)" ;
frac_evap_snow_cv:units = "-" ;
float frac_evap_snow_ls(time, lev, lat, lon) ;
frac_evap_snow_ls:long_name = "fraction of evaporation into the largest mode (snow)" ;
frac_evap_snow_ls:units = "-" ;
float hyam(lev) ;
hyam:long_name = "hybrid A coefficient at layer midpoints" ;
hyam:units = "Pa" ;
float hybm(lev) ;
hybm:long_name = "hybrid B coefficient at layer midpoints" ;
hybm:units = "1" ;
float iwc_T_cv(time, lev, lat, lon) ;
iwc_T_cv:long_name = "T based convective IWC" ;
iwc_T_cv:units = "kg/m^3" ;
float iwc_T_ls(time, lev, lat, lon) ;
iwc_T_ls:long_name = "T based large scale IWC" ;
iwc_T_ls:units = "kg/m^3" ;
float iwc_cv(time, lev, lat, lon) ;
iwc_cv:long_name = "convective IWC" ;
iwc_cv:units = "kg/m^3" ;
float iwc_ls(time, lev, lat, lon) ;
iwc_ls:long_name = "large scale IWC" ;
iwc_ls:units = "kg/m^3" ;
float lat(lat) ;
lat:long_name = "latitude" ;
lat:units = "degrees_north" ;
float lev(lev) ;
lev:long_name = "hybrid level at layer midpoints" ;
lev:standard_name = "hybrid_sigma_pressure" ;
lev:units = "level" ;
lev:positive = "down" ;
lev:formula = "hyam hybm (press=hyam+hybm*aps)" ;
lev:borders = "ilev" ;
float lon(lon) ;
lon:long_name = "longitude" ;
lon:units = "degrees_east" ;
float mju_i_cv(time, lev, lat, lon) ;
mju_i_cv:long_name = "convective [HNO3_ice]/[H2O_ice]" ;
mju_i_cv:units = "-" ;
float mju_i_ls(time, lev, lat, lon) ;
mju_i_ls:long_name = "large scale [HNO3_ice]/[H2O_ice]" ;
mju_i_ls:units = "-" ;
double nstep(time) ;
nstep:long_name = "current time step" ;
float phi_i_cv(time, lev, lat, lon) ;
phi_i_cv:long_name = "convective [HNO3_ice]/[HNO3_tot]" ;
phi_i_cv:units = "-" ;
float phi_i_ls(time, lev, lat, lon) ;
phi_i_ls:long_name = "large scale [HNO3_ice]/[HNO3_tot]" ;
phi_i_ls:units = "-" ;
float rainpH_cv(time, lev, lat, lon) ;
rainpH_cv:long_name = "convective rain pH" ;
rainpH_cv:units = "0-14, NA=19.99" ;
float rainpH_ls(time, lev, lat, lon) ;
rainpH_ls:long_name = "large scale rain pH" ;
rainpH_ls:units = "0-14, NA=19.99" ;
double time(time) ;
time:long_name = "time" ;
time:units = "day since 1950-01-01 00:00:00" ;
time:calendar = "gregorian" ;
float wetflx_aer_cv_Pb210(time, lat, lon) ;
wetflx_aer_cv_Pb210:long_name = "cv aerosol wet dep. flux Pb210" ;
wetflx_aer_cv_Pb210:units = "molecules / (m^2 * s)" ;
float wetflx_aer_cv_sum_Pb210(time, lat, lon) ;
wetflx_aer_cv_sum_Pb210:long_name = "sum of cv aerosol wet dep. flux Pb210" ;
wetflx_aer_cv_sum_Pb210:units = "molecules / m^2" ;
float wetflx_aer_ls_Pb210(time, lat, lon) ;
wetflx_aer_ls_Pb210:long_name = "ls aerosol wet dep. flux Pb210" ;
wetflx_aer_ls_Pb210:units = "molecules / (m^2 * s)" ;
float wetflx_aer_ls_sum_Pb210(time, lat, lon) ;
wetflx_aer_ls_sum_Pb210:long_name = "sum of ls aerosol wet dep. flux Pb210" ;
wetflx_aer_ls_sum_Pb210:units = "molecules / m^2" ;
float wetflx_ammoni(time, lat, lon) ;
wetflx_ammoni:long_name = "wet dep. flux of ammonia/ammonium" ;
wetflx_ammoni:units = "molecules / (m^2 * s)" ;
float wetflx_cv_CH3CHO_l(time, lat, lon) ;
wetflx_cv_CH3CHO_l:long_name = "cv wet dep. flux CH3CHO_l" ;
wetflx_cv_CH3CHO_l:units = "molecules /(m^2 * s)" ;
float wetflx_cv_CH3CO2H_l(time, lat, lon) ;
wetflx_cv_CH3CO2H_l:long_name = "cv wet dep. flux CH3CO2H_l" ;
wetflx_cv_CH3CO2H_l:units = "molecules /(m^2 * s)" ;
float wetflx_cv_CH3COCH3_l(time, lat, lon) ;
wetflx_cv_CH3COCH3_l:long_name = "cv wet dep. flux CH3COCH3_l" ;
wetflx_cv_CH3COCH3_l:units = "molecules /(m^2 * s)" ;
float wetflx_cv_CH3COOm_l(time, lat, lon) ;
wetflx_cv_CH3COOm_l:long_name = "cv wet dep. flux CH3COOm_l" ;
wetflx_cv_CH3COOm_l:units = "molecules /(m^2 * s)" ;
float wetflx_cv_CH3O2_l(time, lat, lon) ;
wetflx_cv_CH3O2_l:long_name = "cv wet dep. flux CH3O2_l" ;
wetflx_cv_CH3O2_l:units = "molecules /(m^2 * s)" ;
float wetflx_cv_CH3OH_l(time, lat, lon) ;
wetflx_cv_CH3OH_l:long_name = "cv wet dep. flux CH3OH_l" ;
wetflx_cv_CH3OH_l:units = "molecules /(m^2 * s)" ;
float wetflx_cv_CH3OOH_l(time, lat, lon) ;
wetflx_cv_CH3OOH_l:long_name = "cv wet dep. flux CH3OOH_l" ;
wetflx_cv_CH3OOH_l:units = "molecules /(m^2 * s)" ;
float wetflx_cv_CO2_l(time, lat, lon) ;
wetflx_cv_CO2_l:long_name = "cv wet dep. flux CO2_l" ;
wetflx_cv_CO2_l:units = "molecules /(m^2 * s)" ;
float wetflx_cv_Clm_l(time, lat, lon) ;
wetflx_cv_Clm_l:long_name = "cv wet dep. flux Clm_l" ;
wetflx_cv_Clm_l:units = "molecules /(m^2 * s)" ;
float wetflx_cv_H2O2_l(time, lat, lon) ;
wetflx_cv_H2O2_l:long_name = "cv wet dep. flux H2O2_l" ;
wetflx_cv_H2O2_l:units = "molecules /(m^2 * s)" ;
float wetflx_cv_HCHO_l(time, lat, lon) ;
wetflx_cv_HCHO_l:long_name = "cv wet dep. flux HCHO_l" ;
wetflx_cv_HCHO_l:units = "molecules /(m^2 * s)" ;
float wetflx_cv_HCO3m_l(time, lat, lon) ;
wetflx_cv_HCO3m_l:long_name = "cv wet dep. flux HCO3m_l" ;
wetflx_cv_HCO3m_l:units = "molecules /(m^2 * s)" ;
float wetflx_cv_HCOOH_l(time, lat, lon) ;
wetflx_cv_HCOOH_l:long_name = "cv wet dep. flux HCOOH_l" ;
wetflx_cv_HCOOH_l:units = "molecules /(m^2 * s)" ;
float wetflx_cv_HCOOm_l(time, lat, lon) ;
wetflx_cv_HCOOm_l:long_name = "cv wet dep. flux HCOOm_l" ;
wetflx_cv_HCOOm_l:units = "molecules /(m^2 * s)" ;
float wetflx_cv_HCl_l(time, lat, lon) ;
wetflx_cv_HCl_l:long_name = "cv wet dep. flux HCl_l" ;
wetflx_cv_HCl_l:units = "molecules /(m^2 * s)" ;
float wetflx_cv_HNO3_l(time, lat, lon) ;
wetflx_cv_HNO3_l:long_name = "cv wet dep. flux HNO3_l" ;
wetflx_cv_HNO3_l:units = "molecules /(m^2 * s)" ;
float wetflx_cv_HNO4_l(time, lat, lon) ;
wetflx_cv_HNO4_l:long_name = "cv wet dep. flux HNO4_l" ;
wetflx_cv_HNO4_l:units = "molecules /(m^2 * s)" ;
float wetflx_cv_HO2_l(time, lat, lon) ;
wetflx_cv_HO2_l:long_name = "cv wet dep. flux HO2_l" ;
wetflx_cv_HO2_l:units = "molecules /(m^2 * s)" ;
float wetflx_cv_HONO_l(time, lat, lon) ;
wetflx_cv_HONO_l:long_name = "cv wet dep. flux HONO_l" ;
wetflx_cv_HONO_l:units = "molecules /(m^2 * s)" ;
float wetflx_cv_HSO3m_l(time, lat, lon) ;
wetflx_cv_HSO3m_l:long_name = "cv wet dep. flux HSO3m_l" ;
wetflx_cv_HSO3m_l:units = "molecules /(m^2 * s)" ;
float wetflx_cv_HSO4m_l(time, lat, lon) ;
wetflx_cv_HSO4m_l:long_name = "cv wet dep. flux HSO4m_l" ;
wetflx_cv_HSO4m_l:units = "molecules /(m^2 * s)" ;
float wetflx_cv_Hp_l_ave(time, lat, lon) ;
wetflx_cv_Hp_l_ave:long_name = "cv wet dep. flux Hp_l" ;
wetflx_cv_Hp_l_ave:units = "molecules /(m^2 * s)" ;
float wetflx_cv_NH3_l(time, lat, lon) ;
wetflx_cv_NH3_l:long_name = "cv wet dep. flux NH3_l" ;
wetflx_cv_NH3_l:units = "molecules /(m^2 * s)" ;
float wetflx_cv_NH4p_l(time, lat, lon) ;
wetflx_cv_NH4p_l:long_name = "cv wet dep. flux NH4p_l" ;
wetflx_cv_NH4p_l:units = "molecules /(m^2 * s)" ;
float wetflx_cv_NH50W_l(time, lat, lon) ;
wetflx_cv_NH50W_l:long_name = "cv wet dep. flux NH50W_l" ;
wetflx_cv_NH50W_l:units = "molecules /(m^2 * s)" ;
float wetflx_cv_NO2_l(time, lat, lon) ;
wetflx_cv_NO2_l:long_name = "cv wet dep. flux NO2_l" ;
wetflx_cv_NO2_l:units = "molecules /(m^2 * s)" ;
float wetflx_cv_NO2m_l(time, lat, lon) ;
wetflx_cv_NO2m_l:long_name = "cv wet dep. flux NO2m_l" ;
wetflx_cv_NO2m_l:units = "molecules /(m^2 * s)" ;
float wetflx_cv_NO3m_l(time, lat, lon) ;
wetflx_cv_NO3m_l:long_name = "cv wet dep. flux NO3m_l" ;
wetflx_cv_NO3m_l:units = "molecules /(m^2 * s)" ;
float wetflx_cv_NO4m_l(time, lat, lon) ;
wetflx_cv_NO4m_l:long_name = "cv wet dep. flux NO4m_l" ;
wetflx_cv_NO4m_l:units = "molecules /(m^2 * s)" ;
float wetflx_cv_NO_l(time, lat, lon) ;
wetflx_cv_NO_l:long_name = "cv wet dep. flux NO_l" ;
wetflx_cv_NO_l:units = "molecules /(m^2 * s)" ;
float wetflx_cv_O3_l(time, lat, lon) ;
wetflx_cv_O3_l:long_name = "cv wet dep. flux O3_l" ;
wetflx_cv_O3_l:units = "molecules /(m^2 * s)" ;
float wetflx_cv_OH_l(time, lat, lon) ;
wetflx_cv_OH_l:long_name = "cv wet dep. flux OH_l" ;
wetflx_cv_OH_l:units = "molecules /(m^2 * s)" ;
float wetflx_cv_OHm_l(time, lat, lon) ;
wetflx_cv_OHm_l:long_name = "cv wet dep. flux OHm_l" ;
wetflx_cv_OHm_l:units = "molecules /(m^2 * s)" ;
float wetflx_cv_PAN_l(time, lat, lon) ;
wetflx_cv_PAN_l:long_name = "cv wet dep. flux PAN_l" ;
wetflx_cv_PAN_l:units = "molecules /(m^2 * s)" ;
float wetflx_cv_SO2_l(time, lat, lon) ;
wetflx_cv_SO2_l:long_name = "cv wet dep. flux SO2_l" ;
wetflx_cv_SO2_l:units = "molecules /(m^2 * s)" ;
float wetflx_cv_SO2t_l(time, lat, lon) ;
wetflx_cv_SO2t_l:long_name = "cv wet dep. flux SO2t_l" ;
wetflx_cv_SO2t_l:units = "molecules /(m^2 * s)" ;
float wetflx_cv_SO3mm_l(time, lat, lon) ;
wetflx_cv_SO3mm_l:long_name = "cv wet dep. flux SO3mm_l" ;
wetflx_cv_SO3mm_l:units = "molecules /(m^2 * s)" ;
float wetflx_cv_SO4mm_l(time, lat, lon) ;
wetflx_cv_SO4mm_l:long_name = "cv wet dep. flux SO4mm_l" ;
wetflx_cv_SO4mm_l:units = "molecules /(m^2 * s)" ;
float wetflx_cv_sum_CH3CHO_l(time, lat, lon) ;
wetflx_cv_sum_CH3CHO_l:long_name = "time integral of cv wet dep. flux CH3CHO_l" ;
wetflx_cv_sum_CH3CHO_l:units = "molecules / m^2" ;
float wetflx_cv_sum_CH3CO2H_l(time, lat, lon) ;
wetflx_cv_sum_CH3CO2H_l:long_name = "time integral of cv wet dep. flux CH3CO2H_l" ;
wetflx_cv_sum_CH3CO2H_l:units = "molecules / m^2" ;
float wetflx_cv_sum_CH3COCH3_l(time, lat, lon) ;
wetflx_cv_sum_CH3COCH3_l:long_name = "time integral of cv wet dep. flux CH3COCH3_l" ;
wetflx_cv_sum_CH3COCH3_l:units = "molecules / m^2" ;
float wetflx_cv_sum_CH3COOm_l(time, lat, lon) ;
wetflx_cv_sum_CH3COOm_l:long_name = "time integral of cv wet dep. flux CH3COOm_l" ;
wetflx_cv_sum_CH3COOm_l:units = "molecules / m^2" ;
float wetflx_cv_sum_CH3O2_l(time, lat, lon) ;
wetflx_cv_sum_CH3O2_l:long_name = "time integral of cv wet dep. flux CH3O2_l" ;
wetflx_cv_sum_CH3O2_l:units = "molecules / m^2" ;
float wetflx_cv_sum_CH3OH_l(time, lat, lon) ;
wetflx_cv_sum_CH3OH_l:long_name = "time integral of cv wet dep. flux CH3OH_l" ;
wetflx_cv_sum_CH3OH_l:units = "molecules / m^2" ;
float wetflx_cv_sum_CH3OOH_l(time, lat, lon) ;
wetflx_cv_sum_CH3OOH_l:long_name = "time integral of cv wet dep. flux CH3OOH_l" ;
wetflx_cv_sum_CH3OOH_l:units = "molecules / m^2" ;
float wetflx_cv_sum_CO2_l(time, lat, lon) ;
wetflx_cv_sum_CO2_l:long_name = "time integral of cv wet dep. flux CO2_l" ;
wetflx_cv_sum_CO2_l:units = "molecules / m^2" ;
float wetflx_cv_sum_Clm_l(time, lat, lon) ;
wetflx_cv_sum_Clm_l:long_name = "time integral of cv wet dep. flux Clm_l" ;
wetflx_cv_sum_Clm_l:units = "molecules / m^2" ;
float wetflx_cv_sum_H2O2_l(time, lat, lon) ;
wetflx_cv_sum_H2O2_l:long_name = "time integral of cv wet dep. flux H2O2_l" ;
wetflx_cv_sum_H2O2_l:units = "molecules / m^2" ;
float wetflx_cv_sum_HCHO_l(time, lat, lon) ;
wetflx_cv_sum_HCHO_l:long_name = "time integral of cv wet dep. flux HCHO_l" ;
wetflx_cv_sum_HCHO_l:units = "molecules / m^2" ;
float wetflx_cv_sum_HCO3m_l(time, lat, lon) ;
wetflx_cv_sum_HCO3m_l:long_name = "time integral of cv wet dep. flux HCO3m_l" ;
wetflx_cv_sum_HCO3m_l:units = "molecules / m^2" ;
float wetflx_cv_sum_HCOOH_l(time, lat, lon) ;
wetflx_cv_sum_HCOOH_l:long_name = "time integral of cv wet dep. flux HCOOH_l" ;
wetflx_cv_sum_HCOOH_l:units = "molecules / m^2" ;
float wetflx_cv_sum_HCOOm_l(time, lat, lon) ;
wetflx_cv_sum_HCOOm_l:long_name = "time integral of cv wet dep. flux HCOOm_l" ;
wetflx_cv_sum_HCOOm_l:units = "molecules / m^2" ;
float wetflx_cv_sum_HCl_l(time, lat, lon) ;
wetflx_cv_sum_HCl_l:long_name = "time integral of cv wet dep. flux HCl_l" ;
wetflx_cv_sum_HCl_l:units = "molecules / m^2" ;
float wetflx_cv_sum_HNO3_l(time, lat, lon) ;
wetflx_cv_sum_HNO3_l:long_name = "time integral of cv wet dep. flux HNO3_l" ;
wetflx_cv_sum_HNO3_l:units = "molecules / m^2" ;
float wetflx_cv_sum_HNO4_l(time, lat, lon) ;
wetflx_cv_sum_HNO4_l:long_name = "time integral of cv wet dep. flux HNO4_l" ;
wetflx_cv_sum_HNO4_l:units = "molecules / m^2" ;
float wetflx_cv_sum_HO2_l(time, lat, lon) ;
wetflx_cv_sum_HO2_l:long_name = "time integral of cv wet dep. flux HO2_l" ;
wetflx_cv_sum_HO2_l:units = "molecules / m^2" ;
float wetflx_cv_sum_HONO_l(time, lat, lon) ;
wetflx_cv_sum_HONO_l:long_name = "time integral of cv wet dep. flux HONO_l" ;
wetflx_cv_sum_HONO_l:units = "molecules / m^2" ;
float wetflx_cv_sum_HSO3m_l(time, lat, lon) ;
wetflx_cv_sum_HSO3m_l:long_name = "time integral of cv wet dep. flux HSO3m_l" ;
wetflx_cv_sum_HSO3m_l:units = "molecules / m^2" ;
float wetflx_cv_sum_HSO4m_l(time, lat, lon) ;
wetflx_cv_sum_HSO4m_l:long_name = "time integral of cv wet dep. flux HSO4m_l" ;
wetflx_cv_sum_HSO4m_l:units = "molecules / m^2" ;
float wetflx_cv_sum_Hp_l(time, lat, lon) ;
wetflx_cv_sum_Hp_l:long_name = "time integral of cv wet dep. flux Hp_l" ;
wetflx_cv_sum_Hp_l:units = "molecules / m^2" ;
float wetflx_cv_sum_NH3_l(time, lat, lon) ;
wetflx_cv_sum_NH3_l:long_name = "time integral of cv wet dep. flux NH3_l" ;
wetflx_cv_sum_NH3_l:units = "molecules / m^2" ;
float wetflx_cv_sum_NH4p_l(time, lat, lon) ;
wetflx_cv_sum_NH4p_l:long_name = "time integral of cv wet dep. flux NH4p_l" ;
wetflx_cv_sum_NH4p_l:units = "molecules / m^2" ;
float wetflx_cv_sum_NH50W_l(time, lat, lon) ;
wetflx_cv_sum_NH50W_l:long_name = "time integral of cv wet dep. flux NH50W_l" ;
wetflx_cv_sum_NH50W_l:units = "molecules / m^2" ;
float wetflx_cv_sum_NO2_l(time, lat, lon) ;
wetflx_cv_sum_NO2_l:long_name = "time integral of cv wet dep. flux NO2_l" ;
wetflx_cv_sum_NO2_l:units = "molecules / m^2" ;
float wetflx_cv_sum_NO2m_l(time, lat, lon) ;
wetflx_cv_sum_NO2m_l:long_name = "time integral of cv wet dep. flux NO2m_l" ;
wetflx_cv_sum_NO2m_l:units = "molecules / m^2" ;
float wetflx_cv_sum_NO3m_l(time, lat, lon) ;
wetflx_cv_sum_NO3m_l:long_name = "time integral of cv wet dep. flux NO3m_l" ;
wetflx_cv_sum_NO3m_l:units = "molecules / m^2" ;
float wetflx_cv_sum_NO4m_l(time, lat, lon) ;
wetflx_cv_sum_NO4m_l:long_name = "time integral of cv wet dep. flux NO4m_l" ;
wetflx_cv_sum_NO4m_l:units = "molecules / m^2" ;
float wetflx_cv_sum_NO_l(time, lat, lon) ;
wetflx_cv_sum_NO_l:long_name = "time integral of cv wet dep. flux NO_l" ;
wetflx_cv_sum_NO_l:units = "molecules / m^2" ;
float wetflx_cv_sum_O3_l(time, lat, lon) ;
wetflx_cv_sum_O3_l:long_name = "time integral of cv wet dep. flux O3_l" ;
wetflx_cv_sum_O3_l:units = "molecules / m^2" ;
float wetflx_cv_sum_OH_l(time, lat, lon) ;
wetflx_cv_sum_OH_l:long_name = "time integral of cv wet dep. flux OH_l" ;
wetflx_cv_sum_OH_l:units = "molecules / m^2" ;
float wetflx_cv_sum_OHm_l(time, lat, lon) ;
wetflx_cv_sum_OHm_l:long_name = "time integral of cv wet dep. flux OHm_l" ;
wetflx_cv_sum_OHm_l:units = "molecules / m^2" ;
float wetflx_cv_sum_PAN_l(time, lat, lon) ;
wetflx_cv_sum_PAN_l:long_name = "time integral of cv wet dep. flux PAN_l" ;
wetflx_cv_sum_PAN_l:units = "molecules / m^2" ;
float wetflx_cv_sum_SO2_l(time, lat, lon) ;
wetflx_cv_sum_SO2_l:long_name = "time integral of cv wet dep. flux SO2_l" ;
wetflx_cv_sum_SO2_l:units = "molecules / m^2" ;
float wetflx_cv_sum_SO2t_l(time, lat, lon) ;
wetflx_cv_sum_SO2t_l:long_name = "time integral of cv wet dep. flux SO2t_l" ;
wetflx_cv_sum_SO2t_l:units = "molecules / m^2" ;
float wetflx_cv_sum_SO3mm_l(time, lat, lon) ;
wetflx_cv_sum_SO3mm_l:long_name = "time integral of cv wet dep. flux SO3mm_l" ;
wetflx_cv_sum_SO3mm_l:units = "molecules / m^2" ;
float wetflx_cv_sum_SO4mm_l(time, lat, lon) ;
wetflx_cv_sum_SO4mm_l:long_name = "time integral of cv wet dep. flux SO4mm_l" ;
wetflx_cv_sum_SO4mm_l:units = "molecules / m^2" ;
float wetflx_ls_CH3CHO_l(time, lat, lon) ;
wetflx_ls_CH3CHO_l:long_name = "ls wet dep. flux CH3CHO_l" ;
wetflx_ls_CH3CHO_l:units = "molecules /(m^2 * s)" ;
float wetflx_ls_CH3CO2H_l(time, lat, lon) ;
wetflx_ls_CH3CO2H_l:long_name = "ls wet dep. flux CH3CO2H_l" ;
wetflx_ls_CH3CO2H_l:units = "molecules /(m^2 * s)" ;
float wetflx_ls_CH3COCH3_l(time, lat, lon) ;
wetflx_ls_CH3COCH3_l:long_name = "ls wet dep. flux CH3COCH3_l" ;
wetflx_ls_CH3COCH3_l:units = "molecules /(m^2 * s)" ;
float wetflx_ls_CH3COOm_l(time, lat, lon) ;
wetflx_ls_CH3COOm_l:long_name = "ls wet dep. flux CH3COOm_l" ;
wetflx_ls_CH3COOm_l:units = "molecules /(m^2 * s)" ;
float wetflx_ls_CH3O2_l(time, lat, lon) ;
wetflx_ls_CH3O2_l:long_name = "ls wet dep. flux CH3O2_l" ;
wetflx_ls_CH3O2_l:units = "molecules /(m^2 * s)" ;
float wetflx_ls_CH3OH_l(time, lat, lon) ;
wetflx_ls_CH3OH_l:long_name = "ls wet dep. flux CH3OH_l" ;
wetflx_ls_CH3OH_l:units = "molecules /(m^2 * s)" ;
float wetflx_ls_CH3OOH_l(time, lat, lon) ;
wetflx_ls_CH3OOH_l:long_name = "ls wet dep. flux CH3OOH_l" ;
wetflx_ls_CH3OOH_l:units = "molecules /(m^2 * s)" ;
float wetflx_ls_CO2_l(time, lat, lon) ;
wetflx_ls_CO2_l:long_name = "ls wet dep. flux CO2_l" ;
wetflx_ls_CO2_l:units = "molecules /(m^2 * s)" ;
float wetflx_ls_Clm_l(time, lat, lon) ;
wetflx_ls_Clm_l:long_name = "ls wet dep. flux Clm_l" ;
wetflx_ls_Clm_l:units = "molecules /(m^2 * s)" ;
float wetflx_ls_H2O2_l(time, lat, lon) ;
wetflx_ls_H2O2_l:long_name = "ls wet dep. flux H2O2_l" ;
wetflx_ls_H2O2_l:units = "molecules /(m^2 * s)" ;
float wetflx_ls_HCHO_l(time, lat, lon) ;
wetflx_ls_HCHO_l:long_name = "ls wet dep. flux HCHO_l" ;
wetflx_ls_HCHO_l:units = "molecules /(m^2 * s)" ;
float wetflx_ls_HCO3m_l(time, lat, lon) ;
wetflx_ls_HCO3m_l:long_name = "ls wet dep. flux HCO3m_l" ;
wetflx_ls_HCO3m_l:units = "molecules /(m^2 * s)" ;
float wetflx_ls_HCOOH_l(time, lat, lon) ;
wetflx_ls_HCOOH_l:long_name = "ls wet dep. flux HCOOH_l" ;
wetflx_ls_HCOOH_l:units = "molecules /(m^2 * s)" ;
float wetflx_ls_HCOOm_l(time, lat, lon) ;
wetflx_ls_HCOOm_l:long_name = "ls wet dep. flux HCOOm_l" ;
wetflx_ls_HCOOm_l:units = "molecules /(m^2 * s)" ;
float wetflx_ls_HCl_l(time, lat, lon) ;
wetflx_ls_HCl_l:long_name = "ls wet dep. flux HCl_l" ;
wetflx_ls_HCl_l:units = "molecules /(m^2 * s)" ;
float wetflx_ls_HNO3_l(time, lat, lon) ;
wetflx_ls_HNO3_l:long_name = "ls wet dep. flux HNO3_l" ;
wetflx_ls_HNO3_l:units = "molecules /(m^2 * s)" ;
float wetflx_ls_HNO4_l(time, lat, lon) ;
wetflx_ls_HNO4_l:long_name = "ls wet dep. flux HNO4_l" ;
wetflx_ls_HNO4_l:units = "molecules /(m^2 * s)" ;
float wetflx_ls_HO2_l(time, lat, lon) ;
wetflx_ls_HO2_l:long_name = "ls wet dep. flux HO2_l" ;
wetflx_ls_HO2_l:units = "molecules /(m^2 * s)" ;
float wetflx_ls_HONO_l(time, lat, lon) ;
wetflx_ls_HONO_l:long_name = "ls wet dep. flux HONO_l" ;
wetflx_ls_HONO_l:units = "molecules /(m^2 * s)" ;
float wetflx_ls_HSO3m_l(time, lat, lon) ;
wetflx_ls_HSO3m_l:long_name = "ls wet dep. flux HSO3m_l" ;
wetflx_ls_HSO3m_l:units = "molecules /(m^2 * s)" ;
float wetflx_ls_HSO4m_l(time, lat, lon) ;
wetflx_ls_HSO4m_l:long_name = "ls wet dep. flux HSO4m_l" ;
wetflx_ls_HSO4m_l:units = "molecules /(m^2 * s)" ;
float wetflx_ls_Hp_l_ave(time, lat, lon) ;
wetflx_ls_Hp_l_ave:long_name = "ls wet dep. flux Hp_l" ;
wetflx_ls_Hp_l_ave:units = "molecules /(m^2 * s)" ;
float wetflx_ls_NH3_l(time, lat, lon) ;
wetflx_ls_NH3_l:long_name = "ls wet dep. flux NH3_l" ;
wetflx_ls_NH3_l:units = "molecules /(m^2 * s)" ;
float wetflx_ls_NH4p_l(time, lat, lon) ;
wetflx_ls_NH4p_l:long_name = "ls wet dep. flux NH4p_l" ;
wetflx_ls_NH4p_l:units = "molecules /(m^2 * s)" ;
float wetflx_ls_NH50W_l(time, lat, lon) ;
wetflx_ls_NH50W_l:long_name = "ls wet dep. flux NH50W_l" ;
wetflx_ls_NH50W_l:units = "molecules /(m^2 * s)" ;
float wetflx_ls_NO2_l(time, lat, lon) ;
wetflx_ls_NO2_l:long_name = "ls wet dep. flux NO2_l" ;
wetflx_ls_NO2_l:units = "molecules /(m^2 * s)" ;
float wetflx_ls_NO2m_l(time, lat, lon) ;
wetflx_ls_NO2m_l:long_name = "ls wet dep. flux NO2m_l" ;
wetflx_ls_NO2m_l:units = "molecules /(m^2 * s)" ;
float wetflx_ls_NO3m_l(time, lat, lon) ;
wetflx_ls_NO3m_l:long_name = "ls wet dep. flux NO3m_l" ;
wetflx_ls_NO3m_l:units = "molecules /(m^2 * s)" ;
float wetflx_ls_NO4m_l(time, lat, lon) ;
wetflx_ls_NO4m_l:long_name = "ls wet dep. flux NO4m_l" ;
wetflx_ls_NO4m_l:units = "molecules /(m^2 * s)" ;
float wetflx_ls_NO_l(time, lat, lon) ;
wetflx_ls_NO_l:long_name = "ls wet dep. flux NO_l" ;
wetflx_ls_NO_l:units = "molecules /(m^2 * s)" ;
float wetflx_ls_O3_l(time, lat, lon) ;
wetflx_ls_O3_l:long_name = "ls wet dep. flux O3_l" ;
wetflx_ls_O3_l:units = "molecules /(m^2 * s)" ;
float wetflx_ls_OH_l(time, lat, lon) ;
wetflx_ls_OH_l:long_name = "ls wet dep. flux OH_l" ;
wetflx_ls_OH_l:units = "molecules /(m^2 * s)" ;
float wetflx_ls_OHm_l(time, lat, lon) ;
wetflx_ls_OHm_l:long_name = "ls wet dep. flux OHm_l" ;
wetflx_ls_OHm_l:units = "molecules /(m^2 * s)" ;
float wetflx_ls_PAN_l(time, lat, lon) ;
wetflx_ls_PAN_l:long_name = "ls wet dep. flux PAN_l" ;
wetflx_ls_PAN_l:units = "molecules /(m^2 * s)" ;
float wetflx_ls_SO2_l(time, lat, lon) ;
wetflx_ls_SO2_l:long_name = "ls wet dep. flux SO2_l" ;
wetflx_ls_SO2_l:units = "molecules /(m^2 * s)" ;
float wetflx_ls_SO2t_l(time, lat, lon) ;
wetflx_ls_SO2t_l:long_name = "ls wet dep. flux SO2t_l" ;
wetflx_ls_SO2t_l:units = "molecules /(m^2 * s)" ;
float wetflx_ls_SO3mm_l(time, lat, lon) ;
wetflx_ls_SO3mm_l:long_name = "ls wet dep. flux SO3mm_l" ;
wetflx_ls_SO3mm_l:units = "molecules /(m^2 * s)" ;
float wetflx_ls_SO4mm_l(time, lat, lon) ;
wetflx_ls_SO4mm_l:long_name = "ls wet dep. flux SO4mm_l" ;
wetflx_ls_SO4mm_l:units = "molecules /(m^2 * s)" ;
float wetflx_ls_sum_CH3CHO_l(time, lat, lon) ;
wetflx_ls_sum_CH3CHO_l:long_name = "time integral of ls wet dep. fluxCH3CHO_l" ;
wetflx_ls_sum_CH3CHO_l:units = "molecules /(m^2)" ;
float wetflx_ls_sum_CH3CO2H_l(time, lat, lon) ;
wetflx_ls_sum_CH3CO2H_l:long_name = "time integral of ls wet dep. fluxCH3CO2H_l" ;
wetflx_ls_sum_CH3CO2H_l:units = "molecules /(m^2)" ;
float wetflx_ls_sum_CH3COCH3_l(time, lat, lon) ;
wetflx_ls_sum_CH3COCH3_l:long_name = "time integral of ls wet dep. fluxCH3COCH3_l" ;
wetflx_ls_sum_CH3COCH3_l:units = "molecules /(m^2)" ;
float wetflx_ls_sum_CH3COOm_l(time, lat, lon) ;
wetflx_ls_sum_CH3COOm_l:long_name = "time integral of ls wet dep. fluxCH3COOm_l" ;
wetflx_ls_sum_CH3COOm_l:units = "molecules /(m^2)" ;
float wetflx_ls_sum_CH3O2_l(time, lat, lon) ;
wetflx_ls_sum_CH3O2_l:long_name = "time integral of ls wet dep. fluxCH3O2_l" ;
wetflx_ls_sum_CH3O2_l:units = "molecules /(m^2)" ;
float wetflx_ls_sum_CH3OH_l(time, lat, lon) ;
wetflx_ls_sum_CH3OH_l:long_name = "time integral of ls wet dep. fluxCH3OH_l" ;
wetflx_ls_sum_CH3OH_l:units = "molecules /(m^2)" ;
float wetflx_ls_sum_CH3OOH_l(time, lat, lon) ;
wetflx_ls_sum_CH3OOH_l:long_name = "time integral of ls wet dep. fluxCH3OOH_l" ;
wetflx_ls_sum_CH3OOH_l:units = "molecules /(m^2)" ;
float wetflx_ls_sum_CO2_l(time, lat, lon) ;
wetflx_ls_sum_CO2_l:long_name = "time integral of ls wet dep. fluxCO2_l" ;
wetflx_ls_sum_CO2_l:units = "molecules /(m^2)" ;
float wetflx_ls_sum_Clm_l(time, lat, lon) ;
wetflx_ls_sum_Clm_l:long_name = "time integral of ls wet dep. fluxClm_l" ;
wetflx_ls_sum_Clm_l:units = "molecules /(m^2)" ;
float wetflx_ls_sum_H2O2_l(time, lat, lon) ;
wetflx_ls_sum_H2O2_l:long_name = "time integral of ls wet dep. fluxH2O2_l" ;
wetflx_ls_sum_H2O2_l:units = "molecules /(m^2)" ;
float wetflx_ls_sum_HCHO_l(time, lat, lon) ;
wetflx_ls_sum_HCHO_l:long_name = "time integral of ls wet dep. fluxHCHO_l" ;
wetflx_ls_sum_HCHO_l:units = "molecules /(m^2)" ;
float wetflx_ls_sum_HCO3m_l(time, lat, lon) ;
wetflx_ls_sum_HCO3m_l:long_name = "time integral of ls wet dep. fluxHCO3m_l" ;
wetflx_ls_sum_HCO3m_l:units = "molecules /(m^2)" ;
float wetflx_ls_sum_HCOOH_l(time, lat, lon) ;
wetflx_ls_sum_HCOOH_l:long_name = "time integral of ls wet dep. fluxHCOOH_l" ;
wetflx_ls_sum_HCOOH_l:units = "molecules /(m^2)" ;
float wetflx_ls_sum_HCOOm_l(time, lat, lon) ;
wetflx_ls_sum_HCOOm_l:long_name = "time integral of ls wet dep. fluxHCOOm_l" ;
wetflx_ls_sum_HCOOm_l:units = "molecules /(m^2)" ;
float wetflx_ls_sum_HCl_l(time, lat, lon) ;
wetflx_ls_sum_HCl_l:long_name = "time integral of ls wet dep. fluxHCl_l" ;
wetflx_ls_sum_HCl_l:units = "molecules /(m^2)" ;
float wetflx_ls_sum_HNO3_l(time, lat, lon) ;
wetflx_ls_sum_HNO3_l:long_name = "time integral of ls wet dep. fluxHNO3_l" ;
wetflx_ls_sum_HNO3_l:units = "molecules /(m^2)" ;
float wetflx_ls_sum_HNO4_l(time, lat, lon) ;
wetflx_ls_sum_HNO4_l:long_name = "time integral of ls wet dep. fluxHNO4_l" ;
wetflx_ls_sum_HNO4_l:units = "molecules /(m^2)" ;
float wetflx_ls_sum_HO2_l(time, lat, lon) ;
wetflx_ls_sum_HO2_l:long_name = "time integral of ls wet dep. fluxHO2_l" ;
wetflx_ls_sum_HO2_l:units = "molecules /(m^2)" ;
float wetflx_ls_sum_HONO_l(time, lat, lon) ;
wetflx_ls_sum_HONO_l:long_name = "time integral of ls wet dep. fluxHONO_l" ;
wetflx_ls_sum_HONO_l:units = "molecules /(m^2)" ;
float wetflx_ls_sum_HSO3m_l(time, lat, lon) ;
wetflx_ls_sum_HSO3m_l:long_name = "time integral of ls wet dep. fluxHSO3m_l" ;
wetflx_ls_sum_HSO3m_l:units = "molecules /(m^2)" ;
float wetflx_ls_sum_HSO4m_l(time, lat, lon) ;
wetflx_ls_sum_HSO4m_l:long_name = "time integral of ls wet dep. fluxHSO4m_l" ;
wetflx_ls_sum_HSO4m_l:units = "molecules /(m^2)" ;
float wetflx_ls_sum_Hp_l(time, lat, lon) ;
wetflx_ls_sum_Hp_l:long_name = "time integral of ls wet dep. fluxHp_l" ;
wetflx_ls_sum_Hp_l:units = "molecules /(m^2)" ;
float wetflx_ls_sum_NH3_l(time, lat, lon) ;
wetflx_ls_sum_NH3_l:long_name = "time integral of ls wet dep. fluxNH3_l" ;
wetflx_ls_sum_NH3_l:units = "molecules /(m^2)" ;
float wetflx_ls_sum_NH4p_l(time, lat, lon) ;
wetflx_ls_sum_NH4p_l:long_name = "time integral of ls wet dep. fluxNH4p_l" ;
wetflx_ls_sum_NH4p_l:units = "molecules /(m^2)" ;
float wetflx_ls_sum_NH50W_l(time, lat, lon) ;
wetflx_ls_sum_NH50W_l:long_name = "time integral of ls wet dep. fluxNH50W_l" ;
wetflx_ls_sum_NH50W_l:units = "molecules /(m^2)" ;
float wetflx_ls_sum_NO2_l(time, lat, lon) ;
wetflx_ls_sum_NO2_l:long_name = "time integral of ls wet dep. fluxNO2_l" ;
wetflx_ls_sum_NO2_l:units = "molecules /(m^2)" ;
float wetflx_ls_sum_NO2m_l(time, lat, lon) ;
wetflx_ls_sum_NO2m_l:long_name = "time integral of ls wet dep. fluxNO2m_l" ;
wetflx_ls_sum_NO2m_l:units = "molecules /(m^2)" ;
float wetflx_ls_sum_NO3m_l(time, lat, lon) ;
wetflx_ls_sum_NO3m_l:long_name = "time integral of ls wet dep. fluxNO3m_l" ;
wetflx_ls_sum_NO3m_l:units = "molecules /(m^2)" ;
float wetflx_ls_sum_NO4m_l(time, lat, lon) ;
wetflx_ls_sum_NO4m_l:long_name = "time integral of ls wet dep. fluxNO4m_l" ;
wetflx_ls_sum_NO4m_l:units = "molecules /(m^2)" ;
float wetflx_ls_sum_NO_l(time, lat, lon) ;
wetflx_ls_sum_NO_l:long_name = "time integral of ls wet dep. fluxNO_l" ;
wetflx_ls_sum_NO_l:units = "molecules /(m^2)" ;
float wetflx_ls_sum_O3_l(time, lat, lon) ;
wetflx_ls_sum_O3_l:long_name = "time integral of ls wet dep. fluxO3_l" ;
wetflx_ls_sum_O3_l:units = "molecules /(m^2)" ;
float wetflx_ls_sum_OH_l(time, lat, lon) ;
wetflx_ls_sum_OH_l:long_name = "time integral of ls wet dep. fluxOH_l" ;
wetflx_ls_sum_OH_l:units = "molecules /(m^2)" ;
float wetflx_ls_sum_OHm_l(time, lat, lon) ;
wetflx_ls_sum_OHm_l:long_name = "time integral of ls wet dep. fluxOHm_l" ;
wetflx_ls_sum_OHm_l:units = "molecules /(m^2)" ;
float wetflx_ls_sum_PAN_l(time, lat, lon) ;
wetflx_ls_sum_PAN_l:long_name = "time integral of ls wet dep. fluxPAN_l" ;
wetflx_ls_sum_PAN_l:units = "molecules /(m^2)" ;
float wetflx_ls_sum_SO2_l(time, lat, lon) ;
wetflx_ls_sum_SO2_l:long_name = "time integral of ls wet dep. fluxSO2_l" ;
wetflx_ls_sum_SO2_l:units = "molecules /(m^2)" ;
float wetflx_ls_sum_SO2t_l(time, lat, lon) ;
wetflx_ls_sum_SO2t_l:long_name = "time integral of ls wet dep. fluxSO2t_l" ;
wetflx_ls_sum_SO2t_l:units = "molecules /(m^2)" ;
float wetflx_ls_sum_SO3mm_l(time, lat, lon) ;
wetflx_ls_sum_SO3mm_l:long_name = "time integral of ls wet dep. fluxSO3mm_l" ;
wetflx_ls_sum_SO3mm_l:units = "molecules /(m^2)" ;
float wetflx_ls_sum_SO4mm_l(time, lat, lon) ;
wetflx_ls_sum_SO4mm_l:long_name = "time integral of ls wet dep. fluxSO4mm_l" ;
wetflx_ls_sum_SO4mm_l:units = "molecules /(m^2)" ;
float wetflx_nitrate(time, lat, lon) ;
wetflx_nitrate:long_name = "wet dep. flux of nitrate" ;
wetflx_nitrate:units = "molecules / (m^2 * s)" ;
float wetflx_sulfate(time, lat, lon) ;
wetflx_sulfate:long_name = "wet dep. flux of sulfate" ;
wetflx_sulfate:units = "molecules / (m^2 * s)" ;
float wetflx_sum_ammoni(time, lat, lon) ;
wetflx_sum_ammoni:long_name = "time integral of wet dep. flux of ammonia/ammonium" ;
wetflx_sum_ammoni:units = "molecules / m^2" ;
float wetflx_sum_nitrate(time, lat, lon) ;
wetflx_sum_nitrate:long_name = "time integral of wet dep. flux of nitrate" ;
wetflx_sum_nitrate:units = "molecules / m^2" ;
float wetflx_sum_sulfate(time, lat, lon) ;
wetflx_sum_sulfate:long_name = "time integral of wet dep. flux of sulfate" ;
wetflx_sum_sulfate:units = "molecules / m^2" ;
// global attributes:
:MESSy = "MESSy version 2.50.4, http://www.messy-interface.org" ;
:MESSy_switch = "version 1.0" ;
:MESSy_channel = "version 2.1" ;
:MESSy_tracer = "version 2.3" ;
:MESSy_timer = "version 0.1" ;
:MESSy_qtimer = "version 2.0" ;
:MESSy_import = "version 1.0" ;
:MESSy_rnd = "version 1.1" ;
:MESSy_aeropt = "version 2.0.0" ;
:MESSy_airsea = "version 2.0" ;
:MESSy_ch4 = "version 1.0" ;
:MESSy_cloud = "version 2.1" ;
:MESSy_cloudopt = "version 1.2" ;
:MESSy_contrail = "version 1.1" ;
:MESSy_convect = "version 2.0" ;
:MESSy_cvtrans = "version 2.3" ;
:MESSy_ddep = "version 2.1" ;
:MESSy_dradon = "version 2.1" ;
:MESSy_gwave = "version 1.0" ;
:MESSy_h2o = "version 2.1" ;
:MESSy_jval = "version 13" ;
:MESSy_lnox = "version 2.4" ;
:MESSy_mecca = "version 3.6" ;
:MESSy_msbm = "version 2.4" ;
:MESSy_o3orig = "version 0.2" ;
:MESSy_offemis = "version 1.0" ;
:MESSy_onemis = "version 2.1.5" ;
:MESSy_orbit = "version 0.9" ;
:MESSy_ptrac = "version 2.2" ;
:MESSy_qbo = "version 2.3" ;
:MESSy_rad = "version 2.2" ;
:MESSy_satsims = "version 1.0" ;
:MESSy_scalc = "version 0.1" ;
:MESSy_scav = "version 2.4.0" ;
:MESSy_scout = "version 2.0" ;
:MESSy_sedi = "version 2.4" ;
:MESSy_sorbit = "version 1.1" ;
:MESSy_surface = "version 1.1" ;
:MESSy_tbudget = "version 1.1" ;
:MESSy_tnudge = "version 2.1" ;
:MESSy_trexp = "version 3.1" ;
:MESSy_tropop = "version 2.1" ;
:MESSy_viso = "version 2.0" ;
:MESSy_experiment = "RC1-base-07" ;
:EXEC_CHECKSUM = "c49b72aa615fef5015f7f92193b82bea bin/echam5.exe (md5sum)" ;
:GCM = "ECHAM5 version 5.3.02, Max-Planck Institute for Meteorology, Hamburg" ;
:GCM_spherical_trunc_n = 42 ;
:GCM_spherical_trunc_m = 42 ;
:GCM_spherical_trunc_k = 42 ;
:GCM_vertical_mode = "middle atmosphere (MA)" ;
:GCM_horizontal_mode = "global" ;
:GCM_advection = "Lin&Rood" ;
:GCM_start_date_time = "19500101 000000" ;
:GCM_timestep = 720. ;
:F95_COMPILER_VERSION = "IBM XL Fortran for AIX, V13.1 (5724-X15) Version: 13.01.0000.0008" ;
:F95_COMPILER_CALL = "mpxlf95_r -g -qfullpath" ;
:F95_COMPILER_FLAGS_01 = "-q64 -qsuppress=1518-061:1518-128 -qsuppress=1500-036 -O3 -qstrict -qMAXMEM=-1 -qsuffix=cpp=f90 -qzerosize -WF,-D__ibm__ -d -WF,-qlanglvl=classic -qlanglvl=95pure -qspillsize=32648 -qarch=auto -qtune=auto -Q -qhot -qxlf90=nosignedzero -bdatapsize:64k -bsta" ;
:F95_COMPILER_FLAGS_02 = "ckpsize:64k -btextpsize:64k" ;
:F95_PREPROC_DEFINITIONS = "-WF,-DMPI -WF,-DMESSY -WF,-D_rs6000 -WF,-DPNETCDF -WF,-DPNCREGRID -WF,-DMPIOM_13B" ;
:F95_COMPILER_INCLUDES = "-I/pf/b/b302019/soft/netcdf/v3.6.3/include -I/pf/b/b302019/soft/netcdf/v3.6.3/include -I/pf/b/b302019/soft/pnetcdf/v1.1.1/include" ;
:operating_date_time = "20140424 063151" ;
:operating_system = "AIX 1 on 00C83D624C00" ;
:operating_host = "blizzard2" ;
:operating_user = "Patrick Joeckel (b302019)" ;
:MESSy_mecca_eqn = "gas_mim1.eqn" ;
:MESSy_mecca_rpl = "CCMI-base-02" ;
:MESSy_mecca_nism = "(((Tr && (G || Het) && !I) || St) && !Hg)" ;
:MESSy_mecca_diag = "CCMI" ;
:channel_time_slo = 56160. ;
:channel_name = "scav_gp" ;
:channel_file_type = "output" ;
:channel_file_name = "RC1-base-07____19600101_0200_scav_gp.nc" ;
:channel_netcdf_lib = "\"3.6.3\" of Apr 23 2009 17:24:40 $" ;
:history = "Sun Jun 22 21:27:05 2014: ncks -F -d time,75 scav_gp/RC1-base-07____196001_scav_gp.nc scav_gp/RC1-base-07____19600131_2200_scav_gp.nc\n",
"Fri Apr 25 06:11:18 2014: ncrcat --overwrite ./RC1-base-07____19600101_0200_scav_gp.nc /work/id0853/b302019/RC1-base-07/./scav_gp/RC1-base-07____196001_scav_gp.nc" ;
:nco_openmp_thread_number = 1 ;
}