New Standard Names

ccpp/config/ccpp_prebuild_config.py

@@ -242,50 +242,50 @@
 OPTIONAL_ARGUMENTS = {
     'rrtmg_sw' : {
         'rrtmg_sw_run' : [
-            'tendency_of_air_temperature_due_to_shortwave_heating_assuming_clear_sky_on_radiation_time_step_and_radiation_levels',
+            'tendency_of_air_temperature_due_to_shortwave_heating_assuming_clear_sky_on_radiation_timestep_and_radiation_levels',
             'components_of_surface_downward_shortwave_fluxes',
             'cloud_liquid_water_path',
-            'mean_effective_radius_for_liquid_cloud',
+            'effective_radius_of_cloud_liquid_water_particles_in_um',
             'cloud_ice_water_path',
-            'mean_effective_radius_for_ice_cloud',
+            'effective_radius_of_ice_liquid_water_particles_in_um',
             'cloud_rain_water_path',
-            'mean_effective_radius_for_rain_drop',
+            'effective_radius_of_cloud_rain_particles_in_um',
             'cloud_snow_water_path',
-            'mean_effective_radius_for_snow_flake',
+            'effective_radius_of_cloud_snow_particles_in_um',
             ],
         },
     'rrtmg_lw' : {
         'rrtmg_lw_run' : [
-            'tendency_of_air_temperature_due_to_longwave_heating_assuming_clear_sky_on_radiation_time_step_and_radiation_levels',
+            'tendency_of_air_temperature_due_to_longwave_heating_assuming_clear_sky_on_radiation_timestep_and_radiation_levels',
             'cloud_liquid_water_path',
-            'mean_effective_radius_for_liquid_cloud',
+            'effective_radius_of_cloud_liquid_water_particles_in_um',
             'cloud_ice_water_path',
-            'mean_effective_radius_for_ice_cloud',
+            'effective_radius_of_ice_liquid_water_particles_in_um',
             'cloud_rain_water_path',
-            'mean_effective_radius_for_rain_drop',
+            'effective_radius_of_cloud_rain_particles_in_um',
             'cloud_snow_water_path',
-            'mean_effective_radius_for_snow_flake',
+            'effective_radius_of_cloud_snow_particles_in_um',
             ],
         },
     'mp_thompson' : {
         'mp_thompson_init' : [
-            'cloud_droplet_number_concentration',
-            'water_friendly_aerosol_number_concentration',
-            'ice_friendly_aerosol_number_concentration',
-            'tendency_of_water_friendly_aerosols_at_surface',
-            'tendency_of_ice_friendly_aerosols_at_surface',
+            'mass_number_concentration_of_cloud_droplets',
+            'mass_number_concentration_of_hygroscopic_aerosols',
+            'mass_number_concentration_of_nonhygroscopic_ice_nucleating_aerosols',
+            'tendency_of_hygroscopic_aerosols_at_surface_adjacent_layer',
+            'tendency_of_nonhygroscopic_ice_nucleating_aerosols_at_surface_adjacent_layer',
             # DH* 2020-06-01: turn off calculation of effective radii, now done in GFS_rrtmg_pre
-            #'effective_radius_of_stratiform_cloud_liquid_water_particle_in_um',
-            #'effective_radius_of_stratiform_cloud_ice_particle_in_um',
-            #'effective_radius_of_stratiform_cloud_snow_particle_in_um',
+            #'effective_radius_of_stratiform_cloud_liquid_water_particle',
+            #'effective_radius_of_stratiform_cloud_ice_particle',
+            #'effective_radius_of_stratiform_cloud_snow_particle',
             # *DH 2020-06-01
             ],
         'mp_thompson_run' : [
-            'cloud_droplet_number_concentration_updated_by_physics',
-            'water_friendly_aerosol_number_concentration_updated_by_physics',
-            'ice_friendly_aerosol_number_concentration_updated_by_physics',
-            'tendency_of_water_friendly_aerosols_at_surface',
-            'tendency_of_ice_friendly_aerosols_at_surface',
+            'mass_number_concentration_of_cloud_droplets_updated_by_physics',
+            'mass_number_concentration_of_hygroscopic_aerosols_updated_by_physics',
+            'mass_number_concentration_of_nonhygroscopic_ice_nucleating_aerosols_updated_by_physics',
+            'tendency_of_hygroscopic_aerosols_at_surface_adjacent_layer',
+            'tendency_of_nonhygroscopic_ice_nucleating_aerosols_at_surface_adjacent_layer',
             ],
         },
     'mp_fer_hires' : {
@@ -302,13 +302,13 @@
          },
     'GFS_rrtmgp_sw_post' : {
          'GFS_rrtmgp_sw_post_run' : [
-             'tendency_of_air_temperature_due_to_shortwave_heating_assuming_clear_sky_on_radiation_time_step',
+             'tendency_of_air_temperature_due_to_shortwave_heating_assuming_clear_sky_on_radiation_timestep',
              'components_of_surface_downward_shortwave_fluxes',
              ],
          },
     'GFS_rrtmgp_lw_post' : {
          'GFS_rrtmgp_lw_post_run' : [
-             'tendency_of_air_temperature_due_to_longwave_heating_assuming_clear_sky_on_radiation_time_step',
+             'tendency_of_air_temperature_due_to_longwave_heating_assuming_clear_sky_on_radiation_timestep',
              ],
          },
     #'subroutine_name_1' : 'all',

scm/src/CCPP_STATIC_API.sh

@@ -0,0 +1,6 @@
+# The CCPP static API is defined here.
+#
+# This file is auto-generated using ccpp_prebuild.py
+# at compile time, do not edit manually.
+#
+export CCPP_STATIC_API="/glade/work/weiweili/GMTB/ccpp_std_nm/ccpp_code/scm_new_meta/ccpp-scm/scm/src/ccpp_static_api.F90"