#------------------------------------------------------------------------------ # Harmonized Emissions Component (HEMCO) ! #------------------------------------------------------------------------------ #BOP # # !MODULE: HEMCO_Config.rc # # !DESCRIPTION: Contains configuration information for HEMCO. Define the # emissions inventories and corresponding file paths here. Entire # configuration files can be inserted into this configuration file with # an '>>>include' statement, e.g. '>>>include HEMCO\_Config\_test.rc' # The settings of include-files will be ignored. #\\ #\\ # !REMARKS: # This file has been customized for the carbon simulation. # See The HEMCO User's Guide for file details: # http://wiki.geos-chem.org/The_HEMCO_User%27s_Guide # # !REVISION HISTORY: # See https://github.com/geoschem/geos-chem for complete history #EOP #------------------------------------------------------------------------------ #BOC ############################################################################### ### BEGIN SECTION SETTINGS ############################################################################### ROOT: /public/home/zhujw/data2/data/Geoschem/ExtData/HEMCO GCAPSCENARIO: not_used GCAPVERTRES: not_used Logfile: * DiagnFile: HEMCO_Diagn.rc DiagnPrefix: ./OutputDir/HEMCO_diagnostics DiagnFreq: Monthly Wildcard: * Separator: / Unit tolerance: 1 Negative values: 2 Only unitless scale factors: false Verbose: false VerboseOnCores: root # Accepted values: root all Mask fractions: false ### END SECTION SETTINGS ### ############################################################################### ### BEGIN SECTION EXTENSION SWITCHES ############################################################################### # ExtNr ExtName on/off Species Years avail. 0 Base : on * # ----- MAIN SWITCHES --------------------------------------------------------- --> EMISSIONS : true --> METEOROLOGY : false --> CHEMISTRY_INPUT : true --> USE_CH4_DATA : false --> USE_CO_DATA : false --> USE_CO2_DATA : true --> USE_OCS_DATA : false # 2012-2016 # ----- RESTART FIELDS -------------------------------------------------------- --> GC_RESTART : false --> HEMCO_RESTART : false # ----- NESTED GRID FIELDS ---------------------------------------------------- --> GC_BCs : false # ----- CH4 INVENTORIES AND DATA ---------------------------------------------- # ..... Regional Inventories ......... --> GHGI_v2 : false # 2012-2018 --> GHGI_v2_Express_Ext : true # 2012-2020 --> Scarpelli_Canada : true # 2018 --> Scarpelli_Mexico : true # 2015 # ..... Global Inventories ........... --> GFEIv2 : true # 2019 --> EDGARv8 : true # 2010-2022 --> QFED2 : false # 2009-2015 --> JPL_WETCHARTS : true # 2009-2017 --> SEEPS : true # 2012 --> LAKES : false # 2009-2015 --> RESERVOIRS : true # 2022 --> FUNG_TERMITES : true # 1985 --> FUNG_SOIL_ABSORPTION : false # 2009-2015 --> MeMo_SOIL_ABSORPTION : true # 1990-2009 or clim. --> CMIP6_SFC_LAND_ANTHRO : false # 1850-2100 --> CMIP6_SHIP : false # 1850-2100 --> BB4MIPS : false # 1850-2100 # ..... Non-Emissions Data ........... --> CH4_LOSS_FREQ : true # 1985 --> GLOBAL_CL : true # 2010-2019 # ----- CO and CO2-only INVENTORIES AND DATA ---------------------------------- # ..... Global inventories ........... --> AEIC2019_DAILY : false # 2019 (daily data) --> AEIC2019_MONMEAN : true # 2019 (monthly-mean data) --> AEIC_SCALE_1990_2019 : true # Scale to year in 1990-2019 --> CEDSv2 : true # 1750-2019 --> CEDS_GBDMAPS : false # 1970-2017 --> CEDS_GBDMAPS_byFuelType: false # 1970-2017 --> HTAP : false # 2008-2010 --> FOSSIL_ODIAC : true # 2000-2018 --> FOSSIL_CDIAC : false # 1980-2014 --> OCEAN_EXCH_TAKA09 : false # 2000 --> OCEAN_EXCH_SCALED : true # 2000-2013 --> BBIO_DIURNAL : false # 1985 --> BBIO_SIB3 : true # 2006-2010 --> NET_TERR_EXCH : true # 2000 --> CO2CORR : true # 2000-2018 # ..... Regional inventories ......... --> APEI : false # 1989-2014 --> NEI2016_MONMEAN : false # 2002-2020 --> DICE_Africa : false # 2013 # ..... Non-emissions data ........... --> CO2_COPROD : true # 2004-2009 --> PROD_CO_CH4 : true # 2010-2019 --> PROD_CO_NMVOC : true # 2010-2019 --> GMI_PROD_LOSS : true # 2005 --> GMD_SFC_CH4 : true # 1979-2020 --> CMIP6_SFC_CH4 : false # 1750-1978 # ..... Ship emissions ............... --> CEDSv2_SHIP : true # 1750-2017 --> CEDS_GBDMAPS_SHIP : false # 1970-2017 --> CEDS_GBDMAPS_SHIP_byFuelType: false # 1970-2017 --> ICOADS_SHIP : false # 2004 #------ OCS FLUX DATA --------------------------------------------------------- --> OCS_ANTHRO_FLUX : true # 2012-2016 --> OCS_BIOMASS_FLUX : true # 2012-2016 --> OCS_MISSING_OCEAN_FLUX : true # 2012-2016 --> OCS_OCEAN_FLUX : true # 2012-2016 # ----- FUTURE EMISSIONS ------------------------------------------------------ --> RCP_3PD : false # 2005-2100 --> RCP_45 : false # 2005-2100 --> RCP_60 : false # 2005-2100 --> RCP_85 : false # 2005-2100 # ----- NON-EMISSIONS DATA ---------------------------------------------------- --> OLSON_LANDMAP : false # 1985 --> YUAN_MODIS_LAI : false # 2000-2020 --> GLOBAL_OH_GC14 : false # 2010-2019 --> GLOBAL_OH_GCv5 : true # 1985 (recommended for CH4) # ----- Options for analytical inversions ------------------------------------- --> AnalyticalInversion : false --> UseTotalPriorEmis : false # Skips global/regional inventories --> Emis_PosteriorSF : false # Apply posterior scale factors to total emis? --> OH_PosteriorSF : false # Apply posterior scale factor to global OH? # ----------------------------------------------------------------------------- 111 GFED : on CH4/CO/CO2 --> GFED4 : true --> GFED_daily : true --> GFED_3hourly : false --> Scaling_CO : 1.05 ### END SECTION EXTENSION SWITCHES ### ############################################################################### ### BEGIN SECTION BASE EMISSIONS ############################################################################### # ExtNr Name sourceFile sourceVar sourceTime C/R/E SrcDim SrcUnit Species ScalIDs Cat Hier (((EMISSIONS #%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% #%%%%% CH4 EMISSIONS %%%%% #%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% (((USE_CH4_DATA #============================================================================== # ---Total CH4 emissions (all sectors) from prior simulation --- #============================================================================== (((UseTotalPriorEmis (((Emis_PosteriorSF 0 CH4_Emis_Prior ../../prior_run/OutputDir/HEMCO_sa_diagnostics.$YYYY$MM$DD0000.nc EmisCH4_Total $YYYY/$MM/$DD/0 C xy kg/m2/s CH4 3 1 500 )))Emis_PosteriorSF (((.not.Emis_PosteriorSF 0 CH4_Emis_Prior ../../prior_run/OutputDir/HEMCO_sa_diagnostics.$YYYY$MM$DD0000.nc EmisCH4_Total $YYYY/$MM/$DD/0 C xy kg/m2/s CH4 - 1 500 ))).not.Emis_PosteriorSF )))UseTotalPriorEmis (((.not.UseTotalPriorEmis #============================================================================== # --- CH4: Gridded GHGI v2 (Maasakkers et al., submitted to ES&T, 2023) --- # # NOTES: # - This is the main Gridded GHGI v2 dataset based off the US GHGI # published in 2020 # - Use Hier=100 to add to Canada and Mexico regional inventories # - Make sure to include offshore/coastal emissions (Hier=1 to add to EDGAR, # Hier=5 to add to GFEI; mask=1009) ### #============================================================================== (((GHGI_v2 ### Oil ### 0 GHGI_OIL_EXPLORATION $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_1B2a_Petroleum_Systems_Exploration 2012-2018/1-12/1/0 EFY xy molec/cm2/s CH4 51/1008 1 100 0 GHGI_COAST_OIL_EXPLORATION - - - - - - CH4 51/1009 1 5 0 GHGI_OIL_PRODUCTION $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_1B2a_Petroleum_Systems_Production 2012-2018/1-12/1/0 EFY xy molec/cm2/s CH4 52/1008 1 100 0 GHGI_COAST_OIL_PRODUCTION - - - - - - CH4 52/1009 1 5 0 GHGI_OIL_REFINING $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_1B2a_Petroleum_Systems_Refining 2012-2018/1-12/1/0 EFY xy molec/cm2/s CH4 53/1008 1 100 0 GHGI_COAST_OIL_REFINING - - - - - - CH4 53/1009 1 5 0 GHGI_OIL_TRANSPORT $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_1B2a_Petroleum_Systems_Transport 2012-2018/1-12/1/0 EFY xy molec/cm2/s CH4 54/1008 1 100 0 GHGI_COAST_OIL_TRANSPORT - - - - - - CH4 54/1009 1 5 ### Gas ### 0 GHGI_GAS_DISTRIBUTION $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_1B2b_Natural_Gas_Distribution 2012-2018/1/1/0 EFY xy molec/cm2/s CH4 1008 2 100 0 GHGI_COAST_GAS_DISTRIBUTION - - - - - - CH4 1009 2 5 0 GHGI_GAS_EXPLORATION $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_1B2b_Natural_Gas_Exploration 2012-2018/1-12/1/0 EFY xy molec/cm2/s CH4 55/1008 2 100 0 GHGI_COAST_GAS_EXPLORATION - - - - - - CH4 55/1009 2 5 0 GHGI_GAS_PROCESSING $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_1B2b_Natural_Gas_Processing 2012-2018/1/1/0 EFY xy molec/cm2/s CH4 1008 2 100 0 GHGI_COAST_GAS_PROCESSING - - - - - - CH4 1009 2 5 0 GHGI_GAS_PRODUCTION $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_1B2b_Natural_Gas_Production 2012-2018/1-12/1/0 EFY xy molec/cm2/s CH4 56/1008 2 100 0 GHGI_COAST_GAS_PRODUCTION - - - - - - CH4 56/1009 2 5 0 GHGI_GAS_TRANSMISSION $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_1B2b_Natural_Gas_TransmissionStorage 2012-2018/1/1/0 EFY xy molec/cm2/s CH4 1008 2 100 0 GHGI_COAST_GAS_TRANSMISSION - - - - - - CH4 1009 2 5 ### Coal ### 0 GHGI_COAL_UNDERGROUND $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_1B1a_Underground_Coal 2012-2018/1/1/0 EFY xy molec/cm2/s CH4 1008 3 100 0 GHGI_COAST_COAL_UNDERGROUND - - - - - - CH4 1009 3 5 0 GHGI_COAL_SURFACE $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_1B1a_Surface_Coal 2012-2018/1/1/0 EFY xy molec/cm2/s CH4 1008 3 100 0 GHGI_COAST_COAL_SURFACE - - - - - - CH4 1009 3 5 0 GHGI_COAL_ABANDONED $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_1B1a_Abandoned_Coal 2012-2018/1/1/0 EFY xy molec/cm2/s CH4 1008 3 100 0 GHGI_COAST_COAL_ABANDONED - - - - - - CH4 1009 3 5 ### Livestock ### 0 GHGI_LIVESTOCK_ENT $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_3A_Enteric_Fermentation 2012-2018/1/1/0 EFY xy molec/cm2/s CH4 1008 4 100 0 GHGI_COAST_LIVESTOCK_ENT - - - - - - CH4 1009 4 1 0 GHGI_LIVESTOCK_MAN $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_3B_Manure_Management 2012-2018/1-12/1/0 EFY xy molec/cm2/s CH4 57/1008 4 100 0 GHGI_COAST_LIVESTOCK_MAN - - - - - - CH4 57/1009 4 1 ### Landfills ### 0 GHGI_LANDFILLS_IND $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_5A1_Landfills_Industrial 2012-2018/1/1/0 EFY xy molec/cm2/s CH4 1008 5 100 0 GHGI_COAST_LANDFILLS_IND - - - - - - CH4 1009 5 1 0 GHGI_LANDFILLS_MSW $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_5A1_Landfills_MSW 2012-2018/1/1/0 EFY xy molec/cm2/s CH4 1008 5 100 0 GHGI_COAST_LANDFILLS_MSW - - - - - - CH4 1009 5 1 0 GHGI_LANDFILLS_COMP $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_5B1_Composting 2012-2018/1/1/0 EFY xy molec/cm2/s CH4 1008 5 100 0 GHGI_COAST_LANDFILLS_COMP - - - - - - CH4 1009 5 1 ### Wastewater ### 0 GHGI_WASTEWATER_DOM $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_5D_Wastewater_Treatment_Domestic 2012-2018/1/1/0 EFY xy molec/cm2/s CH4 1008 6 100 0 GHGI_COAST_WASTEWATER_DOM - - - - - - CH4 1009 6 1 0 GHGI_WASTEWATER_IND $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_5D_Wastewater_Treatment_Industrial 2012-2018/1/1/0 EFY xy molec/cm2/s CH4 1008 6 100 0 GHGI_COAST_WASTEWATER_IND - - - - - - CH4 1009 6 1 ### Rice ### 0 GHGI_RICE $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_3C_Rice_Cultivation 2012-2018/1-12/1/0 EFY xy molec/cm2/s CH4 58/1008 7 100 0 GHGI_COAST_RICE - - - - - - CH4 58/1009 7 1 ### Other Anthro ### 0 GHGI_OTHER_MCOMB $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_1A_Combustion_Mobile 2012-2018/1/1/0 EFY xy molec/cm2/s CH4 1008 8 100 0 GHGI_COAST_OTHER_MCOMB - - - - - - CH4 1009 8 1 0 GHGI_OTHER_SCOMB $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_1A_Combustion_Stationary 2012-2018/1-12/1/0 EFY xy molec/cm2/s CH4 50/1008 8 100 0 GHGI_COAST_OTHER_SCOMB - - - - - - CH4 50/1009 8 1 0 GHGI_OTHER_PIND $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_2B8_Industry_Petrochemical 2012-2018/1/1/0 EFY xy molec/cm2/s CH4 1008 8 100 0 GHGI_COAST_OTHER_PIND - - - - - - CH4 1009 8 1 0 GHGI_OTHER_FIND $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_2C2_Industry_Ferroalloy 2012-2018/1/1/0 EFY xy molec/cm2/s CH4 1008 8 100 0 GHGI_COAST_OTHER_FIND - - - - - - CH4 1009 8 1 0 GHGI_OTHER_BURN $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_3F_Field_Burning 2012-2018/1-12/1/0 EFY xy molec/cm2/s CH4 59/1008 8 100 0 GHGI_COAST_OTHER_BURN - - - - - - CH4 59/1009 8 1 0 GHGI_OTHER_ABOG $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_1B2ab_Abandoned_Oil_Gas 2012-2018/1/1/0 EFY xy molec/cm2/s CH4 1008 8 100 0 GHGI_COAST_OTHER_ABOG - - - - - - CH4 1009 8 1 )))GHGI_v2 #======================================================================================= # --- CH4: Gridded GHGI v2 Express Extension (Maasakkers et al., submitted to ES&T, 2023) --- # # NOTES: # - Based off the US GHGI published in 2022. # - Uses annual source-specific spatial patterns from 2012-2018 from the main # dataset to quickly incorporate more recent national methane emission estimates. # - Emissions for years after 2018 follow the 2018 spatial patterns. # - Make sure to include offshore/coastal emissions (Hier=1 to add to EDGAR, # Hier=5 to add to GFEI; mask=1009) ### #======================================================================================= (((GHGI_v2_Express_Ext (((.not.GHGI_v2 ### Oil ### 0 GHGI_EE_OIL_EXPLORATION $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Express_Extension_Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_1B2a_Petroleum_Systems_Exploration 2012-2020/1-12/1/0 C xy molec/cm2/s CH4 51/1008 1 100 0 GHGI_EE_COAST_OIL_EXPLORATION - - - - - - CH4 51/1009 1 5 0 GHGI_EE_OIL_PRODUCTION $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Express_Extension_Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_1B2a_Petroleum_Systems_Production 2012-2020/1-12/1/0 C xy molec/cm2/s CH4 52/1008 1 100 0 GHGI_EE_COAST_OIL_PRODUCTION - - - - - - CH4 52/1009 1 5 0 GHGI_EE_OIL_REFINING $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Express_Extension_Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_1B2a_Petroleum_Systems_Refining 2012-2020/1-12/1/0 C xy molec/cm2/s CH4 53/1008 1 100 0 GHGI_EE_COAST_OIL_REFINING - - - - - - CH4 53/1009 1 5 0 GHGI_EE_OIL_TRANSPORT $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Express_Extension_Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_1B2a_Petroleum_Systems_Transport 2012-2020/1-12/1/0 C xy molec/cm2/s CH4 54/1008 1 100 0 GHGI_EE_COAST_OIL_TRANSPORT - - - - - - CH4 54/1009 1 5 ### Gas ### 0 GHGI_EE_GAS_DISTRIBUTION $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Express_Extension_Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_1B2b_Natural_Gas_Distribution 2012-2020/1/1/0 C xy molec/cm2/s CH4 1008 2 100 0 GHGI_EE_COAST_GAS_DISTRIBUTION - - - - - - CH4 1009 2 5 0 GHGI_EE_GAS_EXPLORATION $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Express_Extension_Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_1B2b_Natural_Gas_Exploration 2012-2020/1-12/1/0 C xy molec/cm2/s CH4 55/1008 2 100 0 GHGI_EE_COAST_GAS_EXPLORATION - - - - - - CH4 55/1009 2 5 0 GHGI_EE_GAS_PROCESSING $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Express_Extension_Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_1B2b_Natural_Gas_Processing 2012-2020/1/1/0 C xy molec/cm2/s CH4 1008 2 100 0 GHGI_EE_COAST_GAS_PROCESSING - - - - - - CH4 1009 2 5 0 GHGI_EE_GAS_PRODUCTION $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Express_Extension_Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_1B2b_Natural_Gas_Production 2012-2020/1-12/1/0 C xy molec/cm2/s CH4 56/1008 2 100 0 GHGI_EE_COAST_GAS_PRODUCTION - - - - - - CH4 56/1009 2 5 0 GHGI_EE_GAS_TRANSMISSION $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Express_Extension_Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_1B2b_Natural_Gas_TransmissionStorage 2012-2020/1/1/0 C xy molec/cm2/s CH4 1008 2 100 0 GHGI_EE_COAST_GAS_TRANSMISSION - - - - - - CH4 1009 2 5 0 GHGI_EE_GAS_POSTMETER $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Express_Extension_Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_Supp_1B2b_PostMeter 2012-2020/1/1/0 C xy molec/cm2/s CH4 1008 2 100 ### Coal ### 0 GHGI_EE_COAL_UNDERGROUND $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Express_Extension_Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_1B1a_Underground_Coal 2012-2020/1/1/0 C xy molec/cm2/s CH4 1008 3 100 0 GHGI_EE_COAST_COAL_UNDERGROUND - - - - - - CH4 1009 3 5 0 GHGI_EE_COAL_SURFACE $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Express_Extension_Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_1B1a_Surface_Coal 2012-2020/1/1/0 C xy molec/cm2/s CH4 1008 3 100 0 GHGI_EE_COAST_COAL_SURFACE - - - - - - CH4 1009 3 5 0 GHGI_EE_COAL_ABANDONED $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Express_Extension_Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_1B1a_Abandoned_Coal 2012-2020/1/1/0 C xy molec/cm2/s CH4 1008 3 100 0 GHGI_EE_COAST_COAL_ABANDONED - - - - - - CH4 1009 3 5 ### Livestock ### 0 GHGI_EE_LIVESTOCK_ENT $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Express_Extension_Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_3A_Enteric_Fermentation 2012-2020/1/1/0 C xy molec/cm2/s CH4 1008 4 100 0 GHGI_EE_COAST_LIVESTOCK_ENT - - - - - - CH4 1009 4 1 0 GHGI_EE_LIVESTOCK_MAN $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Express_Extension_Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_3B_Manure_Management 2012-2020/1-12/1/0 C xy molec/cm2/s CH4 57/1008 4 100 0 GHGI_EE_COAST_LIVESTOCK_MAN - - - - - - CH4 57/1009 4 1 ### Landfills ### 0 GHGI_EE_LANDFILLS_IND $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Express_Extension_Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_5A1_Landfills_Industrial 2012-2020/1/1/0 C xy molec/cm2/s CH4 1008 5 100 0 GHGI_EE_COAST_LANDFILLS_IND - - - - - - CH4 1009 5 1 0 GHGI_EE_LANDFILLS_MSW $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Express_Extension_Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_5A1_Landfills_MSW 2012-2020/1/1/0 C xy molec/cm2/s CH4 1008 5 100 0 GHGI_EE_COAST_LANDFILLS_MSW - - - - - - CH4 1009 5 1 0 GHGI_EE_LANDFILLS_COMP $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Express_Extension_Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_5B1_Composting 2012-2020/1/1/0 C xy molec/cm2/s CH4 1008 5 100 0 GHGI_EE_COAST_LANDFILLS_COMP - - - - - - CH4 1009 5 1 ### Wastewater ### 0 GHGI_EE_WASTEWATER_DOM $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Express_Extension_Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_5D_Wastewater_Treatment_Domestic 2012-2020/1/1/0 C xy molec/cm2/s CH4 1008 6 100 0 GHGI_EE_COAST_WASTEWATER_DOM - - - - - - CH4 1009 6 1 0 GHGI_EE_WASTEWATER_IND $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Express_Extension_Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_5D_Wastewater_Treatment_Industrial 2012-2020/1/1/0 C xy molec/cm2/s CH4 1008 6 100 0 GHGI_EE_COAST_WASTEWATER_IND - - - - - - CH4 1009 6 1 ### Rice ### 0 GHGI_EE_RICE $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Express_Extension_Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_3C_Rice_Cultivation 2012-2020/1-12/1/0 C xy molec/cm2/s CH4 58/1008 7 100 0 GHGI_EE_COAST_RICE - - - - - - CH4 58/1009 7 1 ### Other Anthro ### 0 GHGI_EE_OTHER_MCOMB $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Express_Extension_Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_1A_Combustion_Mobile 2012-2020/1/1/0 C xy molec/cm2/s CH4 1008 8 100 0 GHGI_EE_COAST_OTHER_MCOMB - - - - - - CH4 1009 8 1 0 GHGI_EE_OTHER_SCOMB $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Express_Extension_Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_1A_Combustion_Stationary 2012-2020/1-12/1/0 C xy molec/cm2/s CH4 50/1008 8 100 0 GHGI_EE_COAST_OTHER_SCOMB - - - - - - CH4 50/1009 8 1 0 GHGI_EE_OTHER_PIND $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Express_Extension_Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_2B8_Industry_Petrochemical 2012-2020/1/1/0 C xy molec/cm2/s CH4 1008 8 100 0 GHGI_EE_COAST_OTHER_PIND - - - - - - CH4 1009 8 1 0 GHGI_EE_OTHER_FIND $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Express_Extension_Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_2C2_Industry_Ferroalloy 2012-2020/1/1/0 C xy molec/cm2/s CH4 1008 8 100 0 GHGI_EE_COAST_OTHER_FIND - - - - - - CH4 1009 8 1 0 GHGI_EE_OTHER_BURN $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Express_Extension_Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_3F_Field_Burning 2012-2020/1-12/1/0 C xy molec/cm2/s CH4 59/1008 8 100 0 GHGI_EE_COAST_OTHER_BURN - - - - - - CH4 59/1009 8 1 0 GHGI_EE_OTHER_ABOG $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Express_Extension_Gridded_GHGI_Methane_v2_$YYYY.nc emi_ch4_1B2ab_Abandoned_Oil_Gas 2012-2020/1/1/0 C xy molec/cm2/s CH4 1008 8 100 0 GHGI_EE_COAST_OTHER_ABOG - - - - - - CH4 1009 8 1 ))).not.GHGI_v2 )))GHGI_v2_Express_Ext #============================================================================== # --- CH4: Mexico emissions (Scarpelli et. al, Environ. Res. Lett., 2020) --- # # NOTES: # - Use Hier=100 to add to Canada and USA regional inventories # - Make sure to include offshore/coastal emissions # (Hier=1 to add to EDGAR, Hier=5 to add to GFEI) #============================================================================== (((Scarpelli_Mexico 0 MEX_OIL $ROOT/CH4/v2022-11/Scarpelli_Mexico/MEX_Tia2020_oil_2015.nc emis_ch4 2015/1/1/0 C xy molec/cm2/s CH4 1001 1 100 0 MEX_OIL_COAST - - - - - - CH4 1010 1 5 0 MEX_GAS $ROOT/CH4/v2022-11/Scarpelli_Mexico/MEX_Tia2020_gas_2015.nc emis_ch4 2015/1/1/0 C xy molec/cm2/s CH4 1001 2 100 0 MEX_GAS_COAST - - - - - - CH4 1010 2 5 0 MEX_COAL $ROOT/CH4/v2022-11/Scarpelli_Mexico/MEX_Tia2020_coal_2015.nc emis_ch4 2015/1/1/0 C xy molec/cm2/s CH4 1001 3 100 0 MEX_COAL_COAST - - - - - - CH4 1010 3 5 0 MEX_LIVESTOCK_A $ROOT/CH4/v2022-11/Scarpelli_Mexico/MEX_Tia2020_livestock_A_2015.nc emis_ch4 2015/1/1/0 C xy molec/cm2/s CH4 1001 4 100 0 MEX_LIVESTOCK_A_COAST - - - - - - CH4 1010 4 1 0 MEX_LIVESTOCK_B $ROOT/CH4/v2022-11/Scarpelli_Mexico/MEX_Tia2020_livestock_B_2015.nc emis_ch4 2015/1/1/0 C xy molec/cm2/s CH4 10/1001 4 100 0 MEX_LIVESTOCK_B_COAST - - - - - - CH4 10/1010 4 1 0 MEX_LANDFILLS $ROOT/CH4/v2022-11/Scarpelli_Mexico/MEX_Tia2020_landfill_2015.nc emis_ch4 2015/1/1/0 C xy molec/cm2/s CH4 1001 5 100 0 MEX_LANDFILLS_COAST - - - - - - CH4 1010 5 1 0 MEX_WASTEWATER $ROOT/CH4/v2022-11/Scarpelli_Mexico/MEX_Tia2020_waste_2015.nc emis_ch4 2015/1/1/0 C xy molec/cm2/s CH4 1001 6 100 0 MEX_WASTEWATER_COAST - - - - - - CH4 1010 6 1 0 MEX_RICE $ROOT/CH4/v2022-11/Scarpelli_Mexico/MEX_Tia2020_rice_2015.nc emis_ch4 2015/1/1/0 C xy molec/cm2/s CH4 11/1001 7 100 0 MEX_RICE_COAST - - - - - - CH4 11/1010 7 1 0 MEX_OTHER $ROOT/CH4/v2022-11/Scarpelli_Mexico/MEX_Tia2020_other_anthro_2015.nc emis_ch4 2015/1/1/0 C xy molec/cm2/s CH4 1001 8 100 0 MEX_OTHER_COAST - - - - - - CH4 1010 8 1 )))Scarpelli_Mexico #============================================================================== # --- CH4: Canada emissions (Scarpelli et al., Environ. Res. Lett., 2022) --- # # NOTES: # - Use Hier=100 to add to USA and Mexico regional inventories # - Make sure to include offshore/coastal emissions # (Hier=1 to add to EDGAR, Hier=5 to add to GFEI) #============================================================================== (((Scarpelli_Canada 0 CAN_OIL_GAS_COMBUSTION $ROOT/CH4/v2022-01/Scarpelli_Canada/can_emis_oil_gas_combustion_2018.nc oil_gas_combustion_total 2018/1/1/0 C xy kg/m2/s CH4 1002 1/2 100 0 CAN_OIL_GAS_COMBUSTION_COAST - - - - - - CH4 1011 1/2 5 0 CAN_OIL_GAS_LEAKAGE $ROOT/CH4/v2022-01/Scarpelli_Canada/can_emis_oil_gas_leakage_2018.nc oil_gas_leakage_total 2018/1/1/0 C xy kg/m2/s CH4 1002 1/2 100 0 CAN_OIL_GAS_LEAKAGE_COAST - - - - - - CH4 1011 1/2 5 0 CAN_OIL_GAS_VENT_FLARE $ROOT/CH4/v2022-01/Scarpelli_Canada/can_emis_oil_gas_vent_flare_2018.nc oil_gas_vent_flare_total 2018/1/1/0 C xy kg/m2/s CH4 1002 1/2 100 0 CAN_OIL_GAS_VENT_FLARE_COAST - - - - - - CH4 1011 1/2 5 0 CAN_COAL $ROOT/CH4/v2022-01/Scarpelli_Canada/can_emis_coal_2018.nc coal_total 2018/1/1/0 C xy kg/m2/s CH4 1002 3 100 0 CAN_COAL_COAST - - - - - - CH4 1011 3 5 0 CAN_LIVESTOCK $ROOT/CH4/v2022-01/Scarpelli_Canada/can_emis_livestock_2018.nc livestock_total 2018/1/1/0 C xy kg/m2/s CH4 1002 4 100 0 CAN_LIVESTOCK_COAST - - - - - - CH4 1011 4 1 0 CAN_SOLID_WASTE $ROOT/CH4/v2022-01/Scarpelli_Canada/can_emis_solid_waste_2018.nc solid_waste_total 2018/1/1/0 C xy kg/m2/s CH4 1002 5 100 0 CAN_SOLID_WASTE_COAST - - - - - - CH4 1011 5 1 0 CAN_WASTEWATER $ROOT/CH4/v2022-01/Scarpelli_Canada/can_emis_wastewater_2018.nc wastewater_total 2018/1/1/0 C xy kg/m2/s CH4 1002 6 100 0 CAN_WASTEWATER_COAST - - - - - - CH4 1011 6 1 0 CAN_OTHER $ROOT/CH4/v2022-01/Scarpelli_Canada/can_emis_other_minor_sources_2018.nc other_minor_sources_total 2018/1/1/0 C xy kg/m2/s CH4 1002 8 100 0 CAN_OTHER_COAST - - - - - - CH4 1011 8 1 )))Scarpelli_Canada #============================================================================== # --- CH4: Global Fuel Exploitation Inventory (GFEI v2, Scarpelli et al., 2021) # # This inventory will replace EDGAR (oil, gas, & coal) #============================================================================== (((GFEIv2 0 GFEI_CH4_OIL $ROOT/CH4/v2022-01/GFEIv2/Global_Fuel_Exploitation_Inventory_v2_2019_Oil_All.nc emis_ch4 2019/1/1/0 C xy molec/cm2/s CH4 - 1 5 0 GFEI_CH4_GAS $ROOT/CH4/v2022-01/GFEIv2/Global_Fuel_Exploitation_Inventory_v2_2019_Gas_All.nc emis_ch4 2019/1/1/0 C xy molec/cm2/s CH4 - 2 5 0 GFEI_CH4_COAL $ROOT/CH4/v2022-01/GFEIv2/Global_Fuel_Exploitation_Inventory_v2_2019_Coal.nc emis_ch4 2019/1/1/0 C xy molec/cm2/s CH4 - 3 5 )))GFEIv2 #============================================================================== # --- CH4: EDGAR v8.0 emissions --- #============================================================================== (((EDGARv8 ### Oil ### 0 EDGAR8_CH4_PRO_OIL $ROOT/CH4/v2024-02/EDGARv8/$YYYY/v8.0_FT2022_GHG_CH4_$YYYY_PRO_OIL_flx.nc emi_ch4 2010-2022/1-12/1/0 C xy kg/m2/s CH4 - 1 1 0 EDGAR8_CH4_REF_TRF $ROOT/CH4/v2024-02/EDGARv8/$YYYY/v8.0_FT2022_GHG_CH4_$YYYY_REF_TRF_flx.nc emi_ch4 2010-2022/1-12/1/0 C xy kg/m2/s CH4 - 1 1 ### Gas ### 0 EDGAR8_CH4_PRO_GAS $ROOT/CH4/v2024-02/EDGARv8/$YYYY/v8.0_FT2022_GHG_CH4_$YYYY_PRO_GAS_flx.nc emi_ch4 2010-2022/1-12/1/0 C xy kg/m2/s CH4 - 2 1 ### Coal ### 0 EDGAR8_CH4_PRO_COAL $ROOT/CH4/v2024-02/EDGARv8/$YYYY/v8.0_FT2022_GHG_CH4_$YYYY_PRO_COAL_flx.nc emi_ch4 2010-2022/1-12/1/0 C xy kg/m2/s CH4 - 3 1 ### Livestock ### 0 EDGAR8_CH4_ENF $ROOT/CH4/v2024-02/EDGARv8/$YYYY/v8.0_FT2022_GHG_CH4_$YYYY_ENF_flx.nc emi_ch4 2010-2022/1-12/1/0 C xy kg/m2/s CH4 - 4 1 0 EDGAR8_CH4_MNM $ROOT/CH4/v2024-02/EDGARv8/$YYYY/v8.0_FT2022_GHG_CH4_$YYYY_MNM_flx.nc emi_ch4 2010-2022/1-12/1/0 C xy kg/m2/s CH4 - 4 1 ### Landfills ### 0 EDGAR8_CH4_SWD_LDF $ROOT/CH4/v2024-02/EDGARv8/$YYYY/v8.0_FT2022_GHG_CH4_$YYYY_SWD_LDF_flx.nc emi_ch4 2010-2022/1-12/1/0 C xy kg/m2/s CH4 - 5 1 ### Wastewater ### 0 EDGAR8_CH4_WWT $ROOT/CH4/v2024-02/EDGARv8/$YYYY/v8.0_FT2022_GHG_CH4_$YYYY_WWT_flx.nc emi_ch4 2010-2022/1-12/1/0 C xy kg/m2/s CH4 - 6 1 ### Rice ### 0 EDGAR8_CH4_AGS $ROOT/CH4/v2024-02/EDGARv8/$YYYY/v8.0_FT2022_GHG_CH4_$YYYY_AGS_flx.nc emi_ch4 2010-2022/1-12/1/0 C xy kg/m2/s CH4 - 7 1 ### Other Anthro ### 0 EDGAR8_CH4_ENE $ROOT/CH4/v2024-02/EDGARv8/$YYYY/v8.0_FT2022_GHG_CH4_$YYYY_ENE_flx.nc emi_ch4 2010-2022/1-12/1/0 C xy kg/m2/s CH4 - 8 1 0 EDGAR8_CH4_IND $ROOT/CH4/v2024-02/EDGARv8/$YYYY/v8.0_FT2022_GHG_CH4_$YYYY_IND_flx.nc emi_ch4 2010-2022/1-12/1/0 C xy kg/m2/s CH4 - 8 1 0 EDGAR8_CH4_TNR_Aviation_CDS $ROOT/CH4/v2024-02/EDGARv8/$YYYY/v8.0_FT2022_GHG_CH4_$YYYY_TNR_Aviation_CDS_flx.nc emi_ch4 2010-2022/1-12/1/0 C xy kg/m2/s CH4 - 8 1 0 EDGAR8_CH4_TNR_Aviation_CRS $ROOT/CH4/v2024-02/EDGARv8/$YYYY/v8.0_FT2022_GHG_CH4_$YYYY_TNR_Aviation_CRS_flx.nc emi_ch4 2010-2022/1-12/1/0 C xy kg/m2/s CH4 - 8 1 0 EDGAR8_CH4_TNR_Aviation_LTO $ROOT/CH4/v2024-02/EDGARv8/$YYYY/v8.0_FT2022_GHG_CH4_$YYYY_TNR_Aviation_LTO_flx.nc emi_ch4 2010-2022/1-12/1/0 C xy kg/m2/s CH4 - 8 1 0 EDGAR8_CH4_TRO $ROOT/CH4/v2024-02/EDGARv8/$YYYY/v8.0_FT2022_GHG_CH4_$YYYY_TRO_flx.nc emi_ch4 2010-2022/1-12/1/0 C xy kg/m2/s CH4 - 8 1 0 EDGAR8_CH4_TNR_Other $ROOT/CH4/v2024-02/EDGARv8/$YYYY/v8.0_FT2022_GHG_CH4_$YYYY_TNR_Other_flx.nc emi_ch4 2010-2022/1-12/1/0 C xy kg/m2/s CH4 - 8 1 0 EDGAR8_CH4_TNR_Ship $ROOT/CH4/v2024-02/EDGARv8/$YYYY/v8.0_FT2022_GHG_CH4_$YYYY_TNR_Ship_flx.nc emi_ch4 2010-2022/1-12/1/0 C xy kg/m2/s CH4 - 8 1 0 EDGAR8_CH4_RCO $ROOT/CH4/v2024-02/EDGARv8/$YYYY/v8.0_FT2022_GHG_CH4_$YYYY_RCO_flx.nc emi_ch4 2010-2022/1-12/1/0 C xy kg/m2/s CH4 - 8 1 0 EDGAR8_CH4_CHE $ROOT/CH4/v2024-02/EDGARv8/$YYYY/v8.0_FT2022_GHG_CH4_$YYYY_CHE_flx.nc emi_ch4 2010-2022/1-12/1/0 C xy kg/m2/s CH4 - 8 1 0 EDGAR8_CH4_IRO $ROOT/CH4/v2024-02/EDGARv8/$YYYY/v8.0_FT2022_GHG_CH4_$YYYY_IRO_flx.nc emi_ch4 2010-2022/1-12/1/0 C xy kg/m2/s CH4 - 8 1 # Comment out to avoid double counting with GFED #0 EDGAR8_CH4_AWB $ROOT/CH4/v2024-02/EDGARv8/$YYYY/v8.0_FT2022_GHG_CH4_$YYYY_AWB_flx.nc emi_ch4 2010-2022/1-12/1/0 C xy kg/m2/s CH4 - 8 1 0 EDGAR8_CH4_SWD_INC $ROOT/CH4/v2024-02/EDGARv8/$YYYY/v8.0_FT2022_GHG_CH4_$YYYY_SWD_INC_flx.nc emi_ch4 2010-2022/1-12/1/0 C xy kg/m2/s CH4 - 8 1 )))EDGARv8 #============================================================================== # --- CH4: CEDS (historical) or Shared Socioeconomic Pathways (future) --- #============================================================================== (((CMIP6_SFC_LAND_ANTHRO 0 CMIP6_CH4_AGR $ROOT/CMIP6/v2021-01/$GCAPSCENARIO/$GCAPSCENARIO_$YYYY.nc4 CH4_agr 1970-2014/1-12/1/0 C xy kg/m2/s CH4 - 4 1 0 CMIP6_CH4_ENE $ROOT/CMIP6/v2021-01/$GCAPSCENARIO/$GCAPSCENARIO_$YYYY.nc4 CH4_ene 1970-2014/1-12/1/0 C xy kg/m2/s CH4 - 2 1 0 CMIP6_CH4_IND $ROOT/CMIP6/v2021-01/$GCAPSCENARIO/$GCAPSCENARIO_$YYYY.nc4 CH4_ind 1970-2014/1-12/1/0 C xy kg/m2/s CH4 - 8 1 0 CMIP6_CH4_TRA $ROOT/CMIP6/v2021-01/$GCAPSCENARIO/$GCAPSCENARIO_$YYYY.nc4 CH4_tra 1970-2014/1-12/1/0 C xy kg/m2/s CH4 - 8 1 0 CMIP6_CH4_RCO $ROOT/CMIP6/v2021-01/$GCAPSCENARIO/$GCAPSCENARIO_$YYYY.nc4 CH4_rco 1970-2014/1-12/1/0 C xy kg/m2/s CH4 - 2 1 0 CMIP6_CH4_SLV $ROOT/CMIP6/v2021-01/$GCAPSCENARIO/$GCAPSCENARIO_$YYYY.nc4 CH4_slv 1970-2014/1-12/1/0 C xy kg/m2/s CH4 - 8 1 0 CMIP6_CH4_WST $ROOT/CMIP6/v2021-01/$GCAPSCENARIO/$GCAPSCENARIO_$YYYY.nc4 CH4_wst 1970-2014/1-12/1/0 C xy kg/m2/s CH4 - 5 1 )))CMIP6_SFC_LAND_ANTHRO (((CMIP6_SHIP 0 CMIP6_CH4_SHP $ROOT/CMIP6/v2021-01/$GCAPSCENARIO/$GCAPSCENARIO_$YYYY.nc4 CH4_shp 1970-2014/1-12/1/0 C xy kg/m2/s CH4 - 8 1 )))CMIP6_SHIP #============================================================================== # --- CH4: BB4MIPs historical / SSP future biomass burning inventories --- #============================================================================== (((BB4MIPS 0 CMIP6_BB_CH4 $ROOT/CMIP6/v2021-01/$GCAPSCENARIO/$GCAPSCENARIO_$YYYY.nc4 CH4_bbn 1750-2015/1-12/1/0 C xyL=1:PBL kg/m2/s CH4 75 9 1 )))BB4MIPS #============================================================================== # --- CH4: biomass burning --- #============================================================================== # --- QFED v2.4r8 --- # NOTE: Use this instead of data in QFED/v2014-09 (these are buggy) (((QFED2 0 QFED_CH4 $ROOT/CH4/v2017-10/QFED/QFEDv2.4r8.emis_ch4.$YYYY.nc emi_ch4 2009-2015/1-12/1-31/0 C xy molec/cm2/s CH4 - 9 2 )))QFED2 #============================================================================== # --- CH4: JPL WetCHARTs v1.0 (Bloom et al., https://doi.org/10.3334/ORNLDAAC/1502) --- # # Use updated files (v2024-01); these are COARDS-compliant. #============================================================================== (((JPL_WETCHARTS 0 JPLW_CH4 $ROOT/CH4/v2024-01/JPL_WetCharts/HEensemble/JPL_WetCharts_2010-2019.Ensemble_Mean.0.5x0.5.nc emi_ch4 2010-2019/1-12/1/0 C xy molec/cm2/s CH4 - 10 1 )))JPL_WETCHARTS #============================================================================== # --- CH4: Geological Seeps --- #============================================================================== (((SEEPS 0 CH4_SEEPS $ROOT/CH4/v2020-04/Seeps/Etiope_CH4GeologicalEmis_ScaledToHmiel.1x1.nc emi_ch4 2012/1/1/0 C xy kg/m2/s CH4 - 11 1 )))SEEPS #============================================================================== # --- CH4: Emissions from Lakes (Maasakkers et al., 2019) --- #============================================================================== (((LAKES 0 CH4_LAKES $ROOT/CH4/v2022-11/Lakes/Maasakkers_Lakes_$YYYY.01x01.nc emi_ch4 $YYYY/1-12/1/0 C xy molec/cm2/s CH4 - 12 1 )))LAKES #============================================================================== # --- Emissions from Hydroelectric Reservoirs (Delwich et al., 2022) --- # # Use updated files (v2024-01); these are COARDS-compliant. #============================================================================== (((RESERVOIRS 0 CH4_RES_DAM $ROOT/CH4/v2024-01/ResME/ResME_Dam_Emissions.0.1x0.1.nc CH4emis 2022/1/1/0 C xy kg/m2/s CH4 1500 15 1 0 CH4_RES_SFC $ROOT/CH4/v2024-01/ResME/ResME_Surface_Emissions.0.1x0.1.nc CH4emis 2022/1/1/0 C xy kg/m2/s CH4 1500 15 1 )))RESERVOIRS #============================================================================== # --- CH4: Soil absorption & termites from Fung et al, 1991 --- # # NOTES: # - Multiply soil absorption by -1 to get a "negative" flux. # (Only apply the scaling factor when adding to the total CH4 simulation) # - Use updated soil absorption emissions with seasonality applied #============================================================================== (((FUNG_TERMITES 0 CH4_TERMITES $ROOT/CH4/v2022-11/4x5/termites.geos.4x5.nc CH4 1985/1/1/0 C xy kg/m2/s CH4 - 13 1 )))FUNG_TERMITES (((FUNG_SOIL_ABSORPTION 0 CH4_SOILABSORB $ROOT/CH4/v2019-10/Fung_SoilAbs/Soil_Absorption_4x5_$YYYY.nc CH4 2009-2015/1-12/1/0 C xy molec/cm2/s CH4 1 14 1 )))FUNG_SOIL_ABSORPTION #============================================================================== # --- CH4: Soil absorption from MeMo model (Murguia-Flores et al. 2018, GMD) --- # # - Multiply soil absorption by -1 to get a "negative" flux #============================================================================== (((MeMo_SOIL_ABSORPTION # Climatology 0 CH4_SOILABSORB $ROOT/CH4/v2019-10/MeMo_SoilAbs/MeMo_CH4uptake_Climatology.nc CH4uptake 2009/1-12/1/0 C xy kg/m2/s CH4 1 14 2 # 1990-2009 #0 CH4_SOILABSORB $ROOT/CH4/v2019-10/MeMo_SoilAbs/MeMo_CH4uptake_1990-2009.nc CH4uptake 1990-2009/1-12/1/0 C xy kg/m2/s CH4 1 14 2 )))MeMo_SOIL_ABSORPTION #============================================================================== # --- CH4: RCP future emission scenarios --- #============================================================================== (((RCP_3PD 0 RCP3PD_CH4 $ROOT/RCP/v2020-07/RCP_3PD/RCPs_anthro_CH4_2005-2100_23474.nc ACCMIP 2005-2100/1/1/0 ID xy kg/m2/s CH4 - 1 1 )))RCP_3PD (((RCP_45 0 RCP45_CH4 $ROOT/RCP/v2020-07/RCP_45/RCPs_anthro_CH4_2005-2100_27424.nc ACCMIP 2005-2100/1/1/0 ID xy kg/m2/s CH4 - 1 1 )))RCP_45 (((RCP_60 0 RCP60_CH4 $ROOT/RCP/v2020-07/RCP_60/RCPs_anthro_CH4_2005-2100_43190.nc ACCMIP 2005-2100/1/1/0 ID xy kg/m2/s CH4 - 1 1 )))RCP_60 (((RCP_85 0 RCP85_CH4 $ROOT/RCP/v2020-07/RCP_85/RCPs_anthro_CH4_2005-2100_43533.nc ACCMIP 2005-2100/1/1/0 ID xy kg/m2/s CH4 - 1 1 )))RCP_85 ))).not.UseTotalPriorEmis )))USE_CH4_DATA #%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% #%%%%% CO EMISSIONS %%%%% #%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% (((USE_CO_DATA #============================================================================== # --- CO: APEI (Canada) --- #============================================================================== (((APEI 0 APEI_CO $ROOT/APEI/v2016-11/APEI.0.1x0.1.nc CO 1989-2014/1/1/0 RF xy kg/m2/s CO 26/52/2002 1 30 )))APEI #============================================================================== # --- CO: EPA NEI2016 v1 (USA) --- # # NOTES: # * Barron Henderson wrote, "The EPA emission modeling platform always # includes our best estimate of that year's emissions for Canada and Mexico # (othpt, othar, ptfire_oth). Using that estimate is likely good. However, # that can lead to a discontinuity in Mexico and Canada." # - By default only emissions over the CONUS are used (via Mask #2007) # - To include emissions over Canada and Mexico, users may revert to the old # US mask file $ROOT/MASKS/v2018-09/USA_LANDMASK_NEI2011_0.1x0.1.20160921.nc # * The base year of these emissions is 2016 and emissions are scaled to # 2002-2020 using data from the EPA Trends Report for Tier 1 CAPS (obtained # 21 Sep 2021). # - See NEI2016/v2021-06/national_tier1_caps+HEMCOscaling.xlsx for details. # - Cl2 and HCl emissions are only available for 2016 because those species # aren't included in the Tier 1 CAPS file/ #============================================================================== (((NEI2016_MONMEAN 0 EPA16_CO__airportsCO $ROOT/NEI2016/v2021-06/2016fh_16j_airports_0pt1degree_month_$MM.ncf CO 2002-2020/1-12/1/0 RF xy kg/m2/s CO 26/211/252/2007 1 50 0 EPA16_CO__nonptCO $ROOT/NEI2016/v2021-06/2016fh_16j_nonpt_0pt1degree_month_$MM.ncf CO 2002-2020/1-12/1/0 RF xy kg/m2/s CO 26/211/252/2007 1 50 0 EPA16_CO__nonroadCO $ROOT/NEI2016/v2021-06/2016fh_16j_nonroad_0pt1degree_month_$MM.ncf CO 2002-2020/1-12/1/0 RF xy kg/m2/s CO 26/211/252/2007 1 50 0 EPA16_CO__npogCO $ROOT/NEI2016/v2021-06/2016fh_16j_np_oilgas_0pt1degree_month_$MM.ncf CO 2002-2020/1-12/1/0 RF xy kg/m2/s CO 26/211/252/2007 1 50 0 EPA16_CO__onroadCO $ROOT/NEI2016/v2021-06/2016fh_16j_onroad_0pt1degree_month_$MM.ncf CO 2002-2020/1-12/1/0 RF xy kg/m2/s CO 26/211/252/2007 1 50 0 EPA16_CO__onroad_caCO $ROOT/NEI2016/v2021-06/2016fh_16j_onroad_ca_adj_0pt1degree_month_$MM.ncf CO 2002-2020/1-12/1/0 RF xy kg/m2/s CO 26/211/252/2007 1 50 0 EPA16_CO__railCO $ROOT/NEI2016/v2021-06/2016fh_16j_rail_0pt1degree_month_$MM.ncf CO 2002-2020/1-12/1/0 RF xy kg/m2/s CO 26/211/252/2007 1 50 0 EPA16_CO__c1c2CO $ROOT/NEI2016/v2021-06/2016fh_16j_emln_cmv_c1c2_12_0pt1degree_3D_month_$MM.ncf CO 2002-2020/1-12/1/0 RF xyz kg/m2/s CO 26/211/252/2007 1 50 0 EPA16_CO__c3CO $ROOT/NEI2016/v2021-06/2016fh_16j_emln_cmv_c3_12_0pt1degree_3D_month_$MM.ncf CO 2002-2020/1-12/1/0 RF xyz kg/m2/s CO 26/211/252/2007 1 50 0 EPA16_CO__pteguCO $ROOT/NEI2016/v2021-06/2016fh_16j_emln_ptegu_0pt1degree_3D_month_$MM.ncf CO 2002-2020/1-12/1/0 RF xyz kg/m2/s CO 26/211/252/2007 1 50 0 EPA16_CO__ptogCO $ROOT/NEI2016/v2021-06/2016fh_16j_emln_pt_oilgas_allinln_0pt1degree_3D_month_$MM.ncf CO 2002-2020/1-12/1/0 RF xyz kg/m2/s CO 26/211/252/2007 1 50 0 EPA16_CO__ptnonipmCO $ROOT/NEI2016/v2021-06/2016fh_16j_emln_ptnonipm_allinln_0pt1degree_3D_month_$MM.ncf CO 2002-2020/1-12/1/0 RF xyz kg/m2/s CO 26/211/252/2007 1 50 0 EPA16_CO__onroad_canCO $ROOT/NEI2016/v2021-06/2016fh_16j_onroad_can_0pt1degree_month_$MM.ncf CO 2002-2020/1-12/1/0 RF xy kg/m2/s CO 26/211/252/2007 1 50 0 EPA16_CO__onroad_mexCO $ROOT/NEI2016/v2021-06/2016fh_16j_onroad_mex_0pt1degree_month_$MM.ncf CO 2002-2020/1-12/1/0 RF xy kg/m2/s CO 26/211/252/2007 1 50 0 EPA16_CO__otharCO $ROOT/NEI2016/v2021-06/2016fh_16j_othar_0pt1degree_month_$MM.ncf CO 2002-2020/1-12/1/0 RF xy kg/m2/s CO 26/211/252/2007 1 50 0 EPA16_CO__othptCO $ROOT/NEI2016/v2021-06/2016fh_16j_emln_othpt_0pt1degree_month_$MM.ncf CO 2002-2020/1-12/1/0 RF xy kg/m2/s CO 26/211/252/2007 1 50 )))NEI2016_MONMEAN #============================================================================== # --- CO: DICE-Africa emission inventory (Marais and Wiedinmyer, ES&T, 2016) --- # # DICE-Africa includes regional (Africa) emissions of biofuel and diffuse # anthropogenic emissions from cars and motorcycles, biofuels, charcoal making # and use, backup generators, agricultural waste burning for cooking, gas # flares, and ad-hoc/informal oil refining. # # Other pollution sources (formal industry, power generation using fossil # fuels) are from the EDGAR v4.3 inventory for CO, SO2, NH3, NOx BC, and OC. # # NMVOCs from sources not accounted for in DICE-Africa aren't included here, # as these emissions are likely to be low compared to the DICE pollution # sources and RETRO v1 as implemented in GEOS-Chem doesn't distinguish # emissions by sector/activity. # # Emissions for 2013 are defined below, but DICE-Africa also includes # emissions for 2006. Developers recommend using population change to # estimate emissions, if users want to use annual trends in pollutant # emissions to estimate in other years. #============================================================================== (((DICE_Africa 0 DICE_CARS_CO $ROOT/DICE_Africa/v2016-10/DICE-Africa-cars-2013-v01-4Oct2016.nc CO 2013/1/1/0 C xy g/m2/yr CO 26/2008 1 60 0 DICE_MOTORCYCLES_CO $ROOT/DICE_Africa/v2016-10/DICE-Africa-motorcycles-2013-v01-4Oct2016.nc CO 2013/1/1/0 C xy g/m2/yr CO 26/2008 1 60 0 DICE_BACKUPGEN_CO $ROOT/DICE_Africa/v2016-10/DICE-Africa-generator-use-2013-v01-4Oct2016.nc CO 2013/1/1/0 C xy g/m2/yr CO 26/2008 1 60 0 DICE_CHARCOALPROD_CO $ROOT/DICE_Africa/v2016-10/DICE-Africa-charcoal-production-2013-v01-4Oct2016.nc CO 2013/1/1/0 C xy g/m2/yr CO 26/2008/320 1 60 0 DICE_GASFLARE_CO $ROOT/DICE_Africa/v2016-10/DICE-Africa-gas-flares-2013-v01-4Oct2016.nc CO 2013/1/1/0 C xy g/m2/yr CO 26/2008 1 60 0 DICE_AGBURNING_CO $ROOT/DICE_Africa/v2016-10/DICE-Africa-household-crop-residue-use-2013-v01-4Oct2016.nc CO 2013/1/1/0 C xy g/m2/yr CO 26/2008 2 60 0 DICE_CHARCOALUSE_CO $ROOT/DICE_Africa/v2016-10/DICE-Africa-charcoal-use-2013-v01-4Oct2016.nc CO 2013/1/1/0 C xy g/m2/yr CO 26/2008 2 60 0 DICE_KEROSENE_CO $ROOT/DICE_Africa/v2016-10/DICE-Africa-kerosene-use-2013-v01-4Oct2016.nc CO 2013/1/1/0 C xy g/m2/yr CO 26/2008 1 60 0 DICE_OILREFINING_CO $ROOT/DICE_Africa/v2016-10/DICE-Africa-adhoc-oil-refining-2006-v01-4Oct2016.nc CO 2013/1/1/0 C xy g/m2/yr CO 26/2008 1 60 0 DICE_HOUSEFUELWOOD_CO $ROOT/DICE_Africa/v2016-10/DICE-Africa-household-fuelwood-use-2013-v01-4Oct2016.nc CO 2013/1/1/0 C xy g/m2/yr CO 26/2008 2 60 0 DICE_OTHERFUELWOOD_CO $ROOT/DICE_Africa/v2016-10/DICE-Africa-other-fuelwood-use-2013-v01-4Oct2016.nc CO 2013/1/1/0 C xy g/m2/yr CO 26/2008 2 60 # --------------------------------------------------- # Efficient Combustion Emissions from EDGAR # This makes up for sources that DICE-Africa lacks # --------------------------------------------------- 0 AF_EDGAR_CO_POW $ROOT/EDGARv43/v2016-11/EDGAR_v43.CO.POW.0.1x0.1.nc emi_co 1970-2010/1/1/0 RF xy kg/m2/s CO 1201/26/52/2008 1 60 0 AF_EDGAR_CO_ENG $ROOT/EDGARv43/v2016-11/EDGAR_v43.CO.ENG.0.1x0.1.nc emi_co 1970-2010/1/1/0 RF xy kg/m2/s CO 1202/26/52/2008 1 60 0 AF_EDGAR_CO_IND $ROOT/EDGARv43/v2016-11/EDGAR_v43.CO.IND.0.1x0.1.nc emi_co 1970-2010/1/1/0 RF xy kg/m2/s CO 1203/26/52/2008 1 60 0 AF_EDGAR_CO_TNG $ROOT/EDGARv43/v2016-11/EDGAR_v43.CO.TNG.0.1x0.1.nc emi_co 1970-2010/1/1/0 RF xy kg/m2/s CO 1205/26/52/2008 1 60 0 AF_EDGAR_CO_PPA $ROOT/EDGARv43/v2016-11/EDGAR_v43.CO.PPA.0.1x0.1.nc emi_co 1970-2010/1/1/0 RF xy kg/m2/s CO 1207/26/52/2008 1 60 0 AF_EDGAR_CO_SWD $ROOT/EDGARv43/v2016-11/EDGAR_v43.CO.SWD.0.1x0.1.nc emi_co 1970-2010/1/1/0 RF xy kg/m2/s CO 1211/26/52/2008 1 60 )))DICE_Africa #============================================================================== # --- CO: CEDS v2 --- # # %%% This is the default global inventory. You may select either CEDS, # EDGAR, HTAP or CMIP6_SFC_LAND_ANTHRO for the global base emissions %%% #============================================================================== (((CEDSv2 0 CEDS_CO_AGR $ROOT/CEDS/v2021-06/$YYYY/CO-em-anthro_CMIP_CEDS_$YYYY.nc CO_agr 1750-2019/1-12/1/0 C xy kg/m2/s CO 2401 1 5 0 CEDS_CO_ENE $ROOT/CEDS/v2021-06/$YYYY/CO-em-anthro_CMIP_CEDS_$YYYY.nc CO_ene 1750-2019/1-12/1/0 C xyL* kg/m2/s CO 2406/706/315 1 5 0 CEDS_CO_IND $ROOT/CEDS/v2021-06/$YYYY/CO-em-anthro_CMIP_CEDS_$YYYY.nc CO_ind 1750-2019/1-12/1/0 C xyL* kg/m2/s CO 2407/707/316 1 5 0 CEDS_CO_TRA $ROOT/CEDS/v2021-06/$YYYY/CO-em-anthro_CMIP_CEDS_$YYYY.nc CO_tra 1750-2019/1-12/1/0 C xy kg/m2/s CO 2411/711 1 5 0 CEDS_CO_RCO $ROOT/CEDS/v2021-06/$YYYY/CO-em-anthro_CMIP_CEDS_$YYYY.nc CO_rco 1750-2019/1-12/1/0 C xy kg/m2/s CO 2409/709 1 5 0 CEDS_CO_SLV $ROOT/CEDS/v2021-06/$YYYY/CO-em-anthro_CMIP_CEDS_$YYYY.nc CO_slv 1750-2019/1-12/1/0 C xy kg/m2/s CO 2407/707 1 5 0 CEDS_CO_WST $ROOT/CEDS/v2021-06/$YYYY/CO-em-anthro_CMIP_CEDS_$YYYY.nc CO_wst 1750-2019/1-12/1/0 C xy kg/m2/s CO 26 1 5 )))CEDSv2 #============================================================================== # --- CO: CEDS GBD-MAPS --- # # NOTES: # -- Reference: McDuffie et al. (2020, Earth System Science Data) # -- Anthropogenic source sectors: agriculture, energy, industry, road transport, # non-road/off-road transport, residential, commercial, other energy use, # solvents, waste, international shipping # -- Fuel categories: the combustion of total coal, solid biofuel, liquid oil # and gas, and all remaining sources # **To use, enable CEDS_byFuelType and CEDS_SHIP_byFuelType** #============================================================================== (((CEDS_GBDMAPS >>>include $ROOT/CEDS/v2020-08/HEMCO_Config.CEDS_GBD-MAPS.rc )))CEDS_GBDMAPS (((CEDS_GBDMAPS_byFuelType (((.not.CEDS_GBDMAPS (((.not.CEDSv2 >>>include $ROOT/CEDS/v2020-08/HEMCO_Config.CEDS_GBD-MAPS_byFuelType.rc ))).not.CEDSv2 ))).not.CEDS_GBDMAPS )))CEDS_GBDMAPS_byFuelType #============================================================================== # --- CO: CMIP6_SFC_LAND_ANTHRO --- # CEDS (historical) or Shared Socioeconomic Pathways (future), consistent with # the CMIP6 simulation experimental design. # # Make sure that the desired $GCAPSCENARIO is set above in SECTION SETTINGS #============================================================================== (((CMIP6_SFC_LAND_ANTHRO 0 CMIP6_CO_AGR $ROOT/CMIP6/v2021-01/$GCAPSCENARIO/$GCAPSCENARIO_$YYYY.nc4 CO_agr 1750-2100/1-12/1/0 C xy kg/m2/s CO 26 1 5 0 CMIP6_CO_ENE $ROOT/CMIP6/v2021-01/$GCAPSCENARIO/$GCAPSCENARIO_$YYYY.nc4 CO_ene 1750-2100/1-12/1/0 C xy kg/m2/s CO 26 1 5 0 CMIP6_CO_IND $ROOT/CMIP6/v2021-01/$GCAPSCENARIO/$GCAPSCENARIO_$YYYY.nc4 CO_ind 1750-2100/1-12/1/0 C xy kg/m2/s CO 26 1 5 0 CMIP6_CO_TRA $ROOT/CMIP6/v2021-01/$GCAPSCENARIO/$GCAPSCENARIO_$YYYY.nc4 CO_tra 1750-2100/1-12/1/0 C xy kg/m2/s CO 26 1 5 0 CMIP6_CO_RCO $ROOT/CMIP6/v2021-01/$GCAPSCENARIO/$GCAPSCENARIO_$YYYY.nc4 CO_rco 1750-2100/1-12/1/0 C xy kg/m2/s CO 26 1 5 0 CMIP6_CO_SLV $ROOT/CMIP6/v2021-01/$GCAPSCENARIO/$GCAPSCENARIO_$YYYY.nc4 CO_slv 1750-2100/1-12/1/0 C xy kg/m2/s CO 26 1 5 0 CMIP6_CO_WST $ROOT/CMIP6/v2021-01/$GCAPSCENARIO/$GCAPSCENARIO_$YYYY.nc4 CO_wst 1750-2100/1-12/1/0 C xy kg/m2/s CO 26 1 5 )))CMIP6_SFC_LAND_ANTHRO #============================================================================== # CO: CEDS (historical) or Shared Socioeconomic Pathways (future) aircraft # emissions, consistent with the CMIP6 simulation experimental design # # Make sure that the desired $GCAPSCENARIO is set above in SECTION SETTINGS #============================================================================== (((CMIP6_AIRCRAFT 0 CMIP6_AIR_CO $ROOT/CMIP6/v2021-01/$GCAPSCENARIO/$GCAPSCENARIO_$YYYY_AIR.$GCAP2VERTRESL.nc4 CO_air 1750-2100/1-12/1/0 C xyz kg/m2/s CO 26 20 1 )))CMIP6_AIRCRAFT #============================================================================== # --- CO: HTAP v2 --- # # %%% This is an optional inventory. You may select either CEDS, EDGAR, # or HTAP for the global base emissions %%% # # ==> HTAP ship emissions are listed in the ship emissions section below # ==> Disable aircraft emissions and get them from AEIC instead. #============================================================================== (((HTAP 0 HTAP_CO_IND $ROOT/HTAP/v2015-03/CO/EDGAR_HTAP_CO_INDUSTRY.generic.01x01.nc emi_co 2008-2010/1-12/1/0 C xy kg/m2/s CO 506/528/26 1 4 0 HTAP_CO_POW $ROOT/HTAP/v2015-03/CO/EDGAR_HTAP_CO_ENERGY.generic.01x01.nc emi_co 2008-2010/1-12/1/0 C xy kg/m2/s CO 506/528/26 1 4 0 HTAP_CO_RES $ROOT/HTAP/v2015-03/CO/EDGAR_HTAP_CO_RESIDENTIAL.generic.01x01.nc emi_co 2008-2010/1-12/1/0 C xy kg/m2/s CO 506/528/26 1 4 0 HTAP_CO_TRA $ROOT/HTAP/v2015-03/CO/EDGAR_HTAP_CO_TRANSPORT.generic.01x01.nc emi_co 2008-2010/1-12/1/0 C xy kg/m2/s CO 506/528/26 1 4 #0 HTAP_CO_AIR1 $ROOT/HTAP/v2015-03/CO/EDGAR_HTAP_CO_AIR_LTO.generic.01x01.nc emi_co 2008-2010/1/1/0 C xy kg/m2/s CO 506/528/26 1 4 #0 HTAP_CO_AIR2 $ROOT/HTAP/v2015-03/CO/EDGAR_HTAP_CO_AIR_CDS.generic.01x01.nc emi_co 2008-2010/1/1/0 C xy kg/m2/s CO 506/528/26 1 4 #0 HTAP_CO_AIR3 $ROOT/HTAP/v2015-03/CO/EDGAR_HTAP_CO_AIR_CRS.generic.01x01.nc emi_co 2008-2010/1/1/0 C xy kg/m2/s CO 506/528/26 1 4 )))HTAP #============================================================================== # --- CO: Ship emissions --- # # ==> CEDS ship emissions are now the default. # ==> If CEDS_SHIP is turned off above then ARCTAS should be used over ICOADS, # CORBETT, and HTAP for SO2 and ICOADS should be used for CO and NO. # ==> Ship NO emissions are used by PARANOx and the extension number must be # adjusted accordingly. If PARANOx is turned off, set the ExtNr back to # zero. #============================================================================== (((SHIP (((ICOADS_SHIP 0 ICOADS_SHIP_CO $ROOT/ICOADS_SHIP/v2014-07/ICOADS.generic.1x1.nc CO 2002/1-12/1/0 C xy kg/m2/s CO 6/10 10 2 )))ICOADS_SHIP (((HTAP_SHIP 0 HTAP_SHIP_CO $ROOT/HTAP/v2015-03/EDGAR_HTAP_CO_SHIPS.generic.01x01.nc CO 2008-2010/1/1/0 C xy kg/m2/s CO 506/528 10 4 )))HTAP_SHIP (((CEDSv2_SHIP 0 CEDS_CO_SHP $ROOT/CEDS/v2021-06/$YYYY/CO-em-anthro_CMIP_CEDS_$YYYY.nc CO_shp 1750-2019/1-12/1/0 C xy kg/m2/s CO 26 10 5 )))CEDSv2_SHIP #============================================================================== # --- CO: CMIP6_SHIP --- # CEDS (historical) or Shared Socioeconomic Pathways (future), consistent with # the CMIP6 simulation experimental design. # # Make sure that the desired $GCAPSCENARIO is set above in SECTION SETTINGS #============================================================================== (((CMIP6_SHIP 0 CMIP6_CO_SHP $ROOT/CMIP6/v2021-01/$GCAPSCENARIO/$GCAPSCENARIO_$YYYY.nc4 CO_shp 1750-2100/1-12/1/0 C xy kg/m2/s CO 26 10 5 )))CMIP6_SHIP )))SHIP #============================================================================== # --- CO: AEIC 2019 aircraft emissions --- # # Data files are for 2019, but scale factors from 1990-2019 can be applied # in order to get year-specific emissions. See the notes in the AEIC2019 # scale factor section below for more information. #============================================================================== (((AEIC2019_DAILY 0 AEIC19_DAILY_CO $ROOT/AEIC2019/v2022-03/2019/AEIC_2019$MM$DD.0.5x0.625.36L.nc CO 2019/1-12/1-31/0 C xyz kg/m2/s CO 241 20 1 )))AEIC2019_DAILY (((AEIC2019_MONMEAN 0 AEIC19_MONMEAN_CO $ROOT/AEIC2019/v2022-03/2019_monmean/AEIC_monmean_2019$MM.0.5x0.625.36L.nc CO 2019/1-12/1/0 C xyz kg/m2/s CO 241 20 1 )))AEIC2019_MONMEAN #============================================================================== # --- CO: RCP future emissions scenarios --- #============================================================================== (((RCP_3PD 0 RCP3PD_CO $ROOT/RCP/v2020-07/RCP_3PD/RCPs_anthro_CO_2005-2100_23474.nc ACCMIP 2005-2100/1/1/0 ID xy kg/m2/s CO - 1 1 )))RCP_3PD (((RCP_45 0 RCP45_CO $ROOT/RCP/v2020-07/RCP_45/RCPs_anthro_CO_2005-2100_27424.nc ACCMIP 2005-2100/1/1/0 ID xy kg/m2/s CO - 1 1 )))RCP_45 (((RCP_60 0 RCP60_CO $ROOT/RCP/v2020-07/RCP_60/RCPs_anthro_CO_2005-2100_43190.nc ACCMIP 2005-2100/1/1/0 ID xy kg/m2/s CO - 1 1 )))RCP_60 (((RCP_85 0 RCP85_CO $ROOT/RCP/v2020-07/RCP_85/RCPs_anthro_CO_2005-2100_43533.nc ACCMIP 2005-2100/1/1/0 ID xy kg/m2/s CO - 1 1 )))RCP_85 #============================================================================== # --- CO biomass burning (base emissions) --- #============================================================================== # --- QFED2 (v2.5r1) --- (((QFED2 0 QFED_CO_PBL $ROOT/QFED/v2018-07/$YYYY/$MM/qfed2.emis_co.006.$YYYY$MM$DD.nc4 biomass 2000-2022/1-12/1-31/0/+12hour EF xyL=1:PBL kg/m2/s CO 54/75/311 5 2 0 QFED_CO_FT $ROOT/QFED/v2018-07/$YYYY/$MM/qfed2.emis_co.006.$YYYY$MM$DD.nc4 biomass 2000-2022/1-12/1-31/0/+12hour EF xyL=PBL:5500m kg/m2/s CO 54/75/312 5 2 )))QFED2 # --- GFAS --- (((GFAS 0 GFAS_CO $ROOT/GFAS/v2018-09/$YYYY/GFAS_$YYYY$MM.nc cofire 2003-2021/1-12/1-31/0 C xyL=1:scal300 kg/m2/s CO 75 5 3 )))GFAS # --- BB4MIPs --- (((BB4MIPS 0 CMIP6_BB_CO $ROOT/CMIP6/v2021-01/$GCAPSCENARIO/$GCAPSCENARIO_$YYYY.nc4 CO_bbn 1750-2100/1-12/1/0 C xyL=1:PBL kg/m2/s CO 75 5 3 )))BB4MIPS )))USE_CO_DATA #%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% #%%%%% CO2 EMISSIONS %%%%% #%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% (((USE_CO2_DATA #============================================================================== # --- CO2: FOSSIL FUEL EMISSIONS --- # # National CO2 fossil fuel emissions exclude international shipping and aviation # Carbon Dioxide Information Analysis Center (CDIAC) 1x1 national emissions # (Andres et al., 2011) # Open-source Data Inventory of Anthropogenic CO2 (ODIAC) 1x1 national emissions # (Oda & Maksyutov, 2011) # # ---> Recommended option: ODIAC (set FOSSIL_ODIAC = true) # ODIAC updated to v2019 by J. Fisher and Y. Cao, 12/2019 #============================================================================== (((FOSSIL_CDIAC 0 FOSSILCO2_CDIAC $ROOT/CO2/v2014-09/FOSSIL/CDIAC_v2014.monthly.generic.1x1.nc CO2 1980-2014/1-12/1/0 C xy kg/m2/s CO2 440/441/480 1 1 )))FOSSIL_CDIAC (((FOSSIL_ODIAC 0 FOSSILCO2_ODIAC $ROOT/CO2/v2022-11/FOSSIL/ODIAC_CO2.monthly.generic.1x1.nc CO2 2000-2018/1-12/1/0 C xy kg/m2/s CO2 440/441/480 1 2 )))FOSSIL_ODIAC #============================================================================== # --- CO2: OCEAN EXCHANGE EMISSIONS --- # # Ocean uptake/emission from Takahashi et al. (2009) and earlier works. # Climatological exchange for 2000 (-1.4 PgC/yr) or scaled ocean exchange, which # accounts for changing atmospheric CO2 (as in the paper) are now available. # # ---> Recommended option: scaled ocean exchange (set OCEAN_EXCH_SCALED = true) #============================================================================== (((OCEAN_EXCH_TAKA09 0 OCEANCO2_TAKA_ANNUAL $ROOT/CO2/v2022-11/OCEAN/Taka2009_CO2_Annual.nc CO2 2000/1/1/0 C xy kg/m2/s CO2 - 2 1 0 OCEANCO2_TAKA_MONTHLY $ROOT/CO2/v2022-11/OCEAN/Taka2009_CO2_Monthly.nc CO2 2000/1-12/1/0 C xy kg/m2/s CO2 - 2 2 )))OCEAN_EXCH_TAKA09 (((OCEAN_EXCH_SCALED 0 OCEANCO2_SCALED_MONTHLY $ROOT/CO2/v2022-11/OCEAN/Scaled_Ocean_CO2_monthly.nc CO2 2000-2013/1-12/1/0 C xy kg/m2/s CO2 - 2 3 )))OCEAN_EXCH_SCALED #============================================================================== # --- CO2: BALANCED BIOSPHERE EXCHANGE --- # # These emissions have a seasonal cycle of uptake/emission but have a net # annual uptake of close to zero (balanced). # CASA model daily emissions for a single year at coarse resolution have a # diurnal cycle imposed (Olsen & Randerson, 2004) # SiB3 emissions are from Nick Parazoo (Messerschmidt et al., 2011) for # 2006-2010. # # ---> Recommended option: SiB3 (set BBIO_SIB3 = true) #============================================================================== (((BBIO_DIURNAL 0 BBIOCO2_DIURNAL $ROOT/CO2/v2014-09/BBIO/BBIO_diurnal_CO2.nc CO2 1985/1-12/1-31/0-23 C xy kg/m2/s CO2 - 3 1 )))BBIO_DIURNAL (((BBIO_SIB3 0 SIB_BBIO_CO2 $ROOT/CO2/v2022-11/BIO/SiB3_3hr_NEP.nc CO2 2006-2010/1-12/1-31/0-23 C xy kg/m2/s CO2 - 3 1 )))BBIO_SIB3 #============================================================================== # --- CO2: NET TERRESTRIAL EXCHANGE --- # # TransCom annual net/residual terrestrial biosperhic CO2 (Baker et al., 2006) # # ---> Recommended for use in forward modelling, optional for # inversion/assimilation #============================================================================== (((NET_TERR_EXCH 0 CO2_NET_TERRESTRIAL $ROOT/CO2/v2022-11/BIO/Net_terrestrial_exch_5.29Pg.generic.1x1.nc CO2 2000/1/1/0 C xy kg/m2/s CO2 - 5 1 )))NET_TERR_EXCH #============================================================================== # --- CO2: SHIP EMISSIONS --- #============================================================================== (((SHIP (((ICOADS_SHIP # The spatial distribution is scaled with global annual scale factors #50 0 ICOADS_CO2_SHIP $ROOT/ICOADS_SHIP/v2014-07/ICOADS_ship_CO2_2004.generic.1x1.nc CO2 2004/1-12/1/0 C xy kg/m2/s CO2 50 6 1 )))ICOADS_SHIP (((CEDSv2_SHIP 0 CEDS_CO2_SHP $ROOT/CEDS/v2021-06/$YYYY/CO2-em-anthro_CMIP_CEDS_$YYYY.nc CO2_shp 1750-2019/1-12/1/0 C xy kg/m2/s CO2 - 6 1 )))CEDSv2_SHIP )))SHIP #============================================================================== # --- CO2: AEIC 2019 aircraft emissions --- # # Data files are for 2019, but scale factors from 1990-2019 can be applied # in order to get year-specific emissions. See the notes in the AEIC2019 # scale factor section below for more information. #============================================================================== (((AEIC2019_DAILY 0 AEIC19_DAILY_CO2 $ROOT/AEIC2019/v2022-03/2019/AEIC_2019$MM$DD.0.5x0.625.36L.nc FUELBURN 2019/1-12/1-31/0 C xyz kg/m2/s CO2 241/260 20 1 )))AEIC2019_DAILY (((AEIC2019_MONMEAN 0 AEIC19_MONMEAN_CO2 $ROOT/AEIC2019/v2022-03/2019_monmean/AEIC_monmean_2019$MM.0.5x0.625.36L.nc FUELBURN 2019/1-12/1/0 C xyz kg/m2/s CO2 241/260 20 1 )))AEIC2019_MONMEAN #============================================================================== # --- CO2: SURFACE CORRECTION FOR CO OXIDATION --- # # These emissions will be subtracted! # Fossil fuel CO and CH4 are based on the national distribution scaled with #10. # Biogenic CH4 data is converted to CO2 using scale factor #20. # Isoprene and monoterpene are converted from kgC to kgCO2 by scale factor #21. # Approach is described in Nassar et al. (2010) # # ---> Recommended for use if chemical production (above) is turned on # # Now multiply by scale factor of -1.0 (#1 in scale factor section below) # to make these emissions negative, so that they will be subtracted. =============================================================================== (((CO2CORR 0 FOSSILCO2_MONTHLY $ROOT/CO2/v2022-11/FOSSIL/ODIAC_CO2.monthly.generic.1x1.nc CO2 2000-2018/1-12/1/0 C xy kg/m2/s CO2 410/440/441/480/1 8 1 0 CO2_LIVESTOCK $ROOT/CO2/v2022-11/CHEM/CH4_source.geos.2x25.nc CH4_004 2004/1-12/1/0 C xy kg/m2/s CO2 420/1 8 1 0 CO2_WASTE $ROOT/CO2/v2022-11/CHEM/CH4_source.geos.2x25.nc CH4_005 2004/1-12/1/0 C xy kg/m2/s CO2 420/1 8 1 0 CO2_RICE $ROOT/CO2/v2022-11/CHEM/CH4_source.geos.2x25.nc CH4_007 2004/1-12/1/0 C xy kg/m2/s CO2 420/1 8 1 0 CO2_WETLANDS $ROOT/CO2/v2022-11/CHEM/CH4_source.geos.2x25.nc CH4_010 2004/1-12/1/0 C xy kg/m2/s CO2 420/1 8 1 0 CO2_NATURAL $ROOT/CO2/v2022-11/CHEM/CH4_source.geos.2x25.nc CH4_012 2004/1-12/1/0 C xy kg/m2/s CO2 420/1 8 1 0 CO2_ISOPRENE $ROOT/CO2/v2022-11/CHEM/Isoprene-2004.geos.2x25.nc ISOP 2004/1-12/1/0 C xy kg/m2/s CO2 421/430/1 8 1 0 CO2_MONOTERP $ROOT/CO2/v2022-11/CHEM/Monoterpene-2004.geos.2x25.nc MONOT 2004/1-12/1/0 C xy kg/m2/s CO2 421/430/1 8 1 )))CO2CORR )))USE_CO2_DATA #%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% #%%%%% OCS FLUXES (cf Kevin Bowman/JPL) %%%%% #%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% (((USE_OCS_DATA (((OCS_ANTHRO_FLUX 0 OCS_ANTHRO $ROOT/OCS_FLUX/v2022-11/anthro_v3/v3_anthro/$YYYY/$MM.nc COS_Flux 2012-2016/1-12/1/0 C xy kgS/km2/s OCS 70/71 1 1 )))OCS_ANTHRO_FLUX (((OCS_BIOMASS_FLUX 0 OCS_BIOMASS $ROOT/OCS_FLUX/v2022-11/Biomassburn/CMSV2-CO2-GFED3-ZC/$YYYY/$MM.nc COS_Flux 2012-2016/1-12/1/0 C xy kgS/km2/s OCS 70/71 2 1 )))OCS_BIOMASS_FLUX (((OCS_MISSING_OCEAN_FLUX 0 OCS_MISSING_OCEAN $ROOT/OCS_FLUX/v2022-11/MissingOcean/LUKAI/$YYYY/$MM.nc COS_Flux 2012-2016/1-12/1/0 C xy kgS/km2/s OCS 70/71 3 1 )))OCS_MISSING_OCEAN_FLUX (((OCS_OCEAN_FLUX 0 OCS_OCEAN $ROOT/OCS_FLUX/v2022-11/OceanCOS/Kettle/$YYYY/$MM.nc COS_Flux 2012-2016/1-12/1/0 C xy kgS/km2/s OCS 70/71 4 1 )))OCS_OCEAN_FLUX )))USE_OCS_DATA ############################################################################### ### EXTENSION DATA (subsection of BASE EMISSIONS SECTION) ### ### These fields are needed by the extensions listed above. The assigned ExtNr ### must match the ExtNr entry in section 'Extension switches'. These fields ### are only read if the extension is enabled. The fields are imported by the ### extensions by field name. The name given here must match the name used ### in the extension's source code. ############################################################################### #============================================================================== # --- GFED biomass burning emissions (Extension 111) # NOTE: These are the base emissions in kgDM/m2/s. #============================================================================== (((GFED4 111 GFED_TEMP $ROOT/GFED4/v2023-03/$YYYY/GFED4_gen.025x025.$YYYY$MM.nc DM_TEMP 2010-2023/1-12/01/0 RF xy kgDM/m2/s * - 1 1 111 GFED_AGRI $ROOT/GFED4/v2023-03/$YYYY/GFED4_gen.025x025.$YYYY$MM.nc DM_AGRI 2010-2023/1-12/01/0 RF xy kgDM/m2/s * - 1 1 111 GFED_DEFO $ROOT/GFED4/v2023-03/$YYYY/GFED4_gen.025x025.$YYYY$MM.nc DM_DEFO 2010-2023/1-12/01/0 RF xy kgDM/m2/s * - 1 1 111 GFED_BORF $ROOT/GFED4/v2023-03/$YYYY/GFED4_gen.025x025.$YYYY$MM.nc DM_BORF 2010-2023/1-12/01/0 RF xy kgDM/m2/s * - 1 1 111 GFED_PEAT $ROOT/GFED4/v2023-03/$YYYY/GFED4_gen.025x025.$YYYY$MM.nc DM_PEAT 2010-2023/1-12/01/0 RF xy kgDM/m2/s * - 1 1 111 GFED_SAVA $ROOT/GFED4/v2023-03/$YYYY/GFED4_gen.025x025.$YYYY$MM.nc DM_SAVA 2010-2023/1-12/01/0 RF xy kgDM/m2/s * - 1 1 (((GFED_daily 111 GFED_FRAC_DAY $ROOT/GFED4/v2023-03/$YYYY/GFED4_dailyfrac_gen.025x025.$YYYY$MM.nc GFED_FRACDAY 2010-2023/1-12/1-31/0 RF xy 1 * - 1 1 )))GFED_daily (((GFED_3hourly 111 GFED_FRAC_3HOUR $ROOT/GFED4/v2023-03/$YYYY/GFED4_3hrfrac_gen.025x025.$YYYY$MM.nc GFED_FRAC3HR 2010-2023/1-12/1/0-23 RF xy 1 * - 1 1 )))GFED_3hourly )))GFED4 )))EMISSIONS ############################################################################### ### NON-EMISSIONS DATA (subsection of BASE EMISSIONS SECTION) ### ### Non-emissions data. The following fields are read through HEMCO but do ### not contain emissions data. The extension number is set to wildcard ### character denoting that these fields will not be considered for emission ### calculation. A given entry is only read if the assigned species name is ### an HEMCO species. ############################################################################### #============================================================================== # --- Time zones (offset to UTC) --- #============================================================================== * TIMEZONES $ROOT/TIMEZONES/v2024-02/timezones_vohra_2017_0.1x0.1.nc UTC_OFFSET 2017/1-12/1/0 C xy count * - 1 1 #============================================================================== # --- Meteorology fields --- #============================================================================== (((METEOROLOGY >>>include ${RUNDIR_MET_FIELD_CONFIG} )))METEOROLOGY #============================================================================== # --- GEOS-Chem restart file --- #============================================================================== (((GC_RESTART * SPC_ ./Restarts/GEOSChem.Restart.$YYYY$MM$DD_$HH$MNz.nc4 SpeciesRst_?ALL? $YYYY/$MM/$DD/$HH EFYO xyz 1 * - 1 1 * DELPDRY ./Restarts/GEOSChem.Restart.$YYYY$MM$DD_$HH$MNz.nc4 Met_DELPDRY $YYYY/$MM/$DD/$HH EY xyz 1 * - 1 1 )))GC_RESTART #============================================================================== # --- GEOS-Chem boundary condition file --- #============================================================================== (((GC_BCs * BC_ $ROOT/SAMPLE_BCs/v2021-07/CH4/GEOSChem.BoundaryConditions.$YYYY$MM$DD_0000z.nc4 SpeciesBC_?ADV? 1900-2100/1-12/1-31/* EFY xyz 1 * - 1 1 )))GC_BCs #============================================================================== # --- Olson land map masks --- #============================================================================== (((OLSON_LANDMAP * LANDTYPE00 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE00 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE01 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE01 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE02 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE02 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE03 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE03 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE04 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE04 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE05 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE05 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE06 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE06 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE07 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE07 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE08 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE08 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE09 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE09 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE10 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE10 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE11 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE11 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE12 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE12 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE13 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE13 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE14 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE14 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE15 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE15 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE16 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE16 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE17 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE17 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE18 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE18 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE19 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE19 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE20 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE20 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE21 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE21 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE22 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE22 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE23 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE23 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE24 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE24 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE25 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE25 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE26 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE26 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE27 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE27 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE28 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE28 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE29 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE29 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE30 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE30 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE31 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE31 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE32 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE32 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE33 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE33 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE34 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE34 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE35 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE35 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE36 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE36 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE37 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE37 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE38 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE38 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE39 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE39 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE40 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE40 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE41 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE41 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE42 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE42 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE43 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE43 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE44 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE44 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE45 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE45 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE46 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE46 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE47 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE47 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE48 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE48 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE49 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE49 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE50 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE50 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE51 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE51 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE52 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE52 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE53 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE53 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE54 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE54 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE55 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE55 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE56 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE56 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE57 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE57 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE58 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE58 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE59 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE59 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE60 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE60 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE61 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE61 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE62 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE62 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE63 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE63 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE64 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE64 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE65 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE65 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE66 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE66 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE67 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE67 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE68 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE68 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE69 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE69 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE70 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE70 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE71 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE71 1985/1/1/0 C xy 1 * - 1 1 * LANDTYPE72 $ROOT/OLSON_MAP/v2019-02/Olson_2001_Land_Type_Masks.025x025.generic.nc LANDTYPE72 1985/1/1/0 C xy 1 * - 1 1 )))OLSON_LANDMAP #============================================================================== # --- Yuan processed MODIS leaf area index data --- # # Source: Yuan et al 2011, doi:10.1016/j.rse.2011.01.001 # http://globalchange.bnu.edu.cn/research/lai # # NOTES: # (1) LAI data corresponding to each Olson land type is stored in # separate netCDF variables (XLAI00, XLAI01, ... XLAI72). # The "XLAI" denotes that the files are prepared in this way. # (2) Units are "cm2 leaf/cm2 grid box". # (3) Data is timestamped every 8 days, starting from the 2nd of the month. #============================================================================== (((YUAN_MODIS_LAI * XLAI00 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI00 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI01 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI01 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI02 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI02 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI03 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI03 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI04 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI04 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI05 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI05 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI06 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI06 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI07 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI07 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI08 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI08 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI09 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI09 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI10 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI10 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI11 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI11 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI12 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI12 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI13 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI13 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI14 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI14 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI15 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI15 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI16 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI16 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI17 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI17 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI18 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI18 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI19 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI19 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI20 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI20 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI21 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI21 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI22 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI22 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI23 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI23 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI24 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI24 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI25 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI25 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI26 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI26 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI27 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI27 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI28 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI28 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI29 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI29 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI30 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI30 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI31 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI31 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI32 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI32 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI33 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI33 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI34 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI34 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI35 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI35 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI36 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI36 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI37 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI37 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI38 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI38 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI39 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI39 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI40 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI40 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI41 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI41 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI42 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI42 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI43 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI43 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI44 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI44 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI45 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI45 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI46 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI46 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI47 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI47 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI48 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI48 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI49 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI49 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI50 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI50 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI51 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI51 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI52 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI52 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI53 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI53 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI54 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI54 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI55 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI55 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI56 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI56 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI57 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI57 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI58 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI58 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI59 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI59 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI60 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI60 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI61 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI61 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI62 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI62 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI63 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI63 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI64 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI64 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI65 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI65 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI66 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI66 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI67 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI67 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI68 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI68 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI69 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI69 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI70 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI70 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI71 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI71 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 * XLAI72 $ROOT/Yuan_XLAI/v2021-06/Yuan_proc_MODIS_XLAI.025x025.$YYYY.nc XLAI72 2000-2020/1-12/1-31/0 I xy cm2/cm2 * - 1 1 )))YUAN_MODIS_LAI #============================================================================== # --- Quantities needed for the analytical inversion (via IMI) --- #============================================================================== (((USE_CH4_DATA #------------------------------------------------------------------------------ # --- Files needed for analytical inversion --- #------------------------------------------------------------------------------ (((AnalyticalInversion * CH4_STATE_VECTOR StateVector.nc StateVector 2009/1/1/0 C xy 1 * - 1 1 )))AnalyticalInversion )))USE_CH4_DATA #============================================================================== # --- Chemistry inputs --- #============================================================================== (((CHEMISTRY_INPUT #------------------------------------------------------------------------------ # --- Global OH fields --- #------------------------------------------------------------------------------ # --- OH from GEOS-Chem v5-07 [kg/m3], needed for CH4/IMI --- (((GLOBAL_OH_GCv5 (((OH_PosteriorSF * GLOBAL_OH $ROOT/OH/v2022-11/v5-07-08/OH_3Dglobal.geos5.72L.4x5.nc OH 1985/1-12/1/0 C xyz kg/m3 * 2/4 1 1 )))OH_PosteriorSF (((.not.OH_PosteriorSF * GLOBAL_OH $ROOT/OH/v2022-11/v5-07-08/OH_3Dglobal.geos5.72L.4x5.nc OH 1985/1-12/1/0 C xyz kg/m3 * 2 1 1 ))).not.OH_PosteriorSF )))GLOBAL_OH_GCv5 # --- OH from the last 10-yr benchmark [mol/mol dry] --- (((GLOBAL_OH_GC14 (((.not.GLOBAL_OH_GCv5 * GLOBAL_OH $ROOT/CH4/v2024-01/GCC_14_Output/$YYYY/GEOSChem.SpeciesConc.$YYYY$MM01_0000z.nc4 SpeciesConc_OH 2010-2019/1-12/1/0 C xyz 1 * - 1 1 ))).not.GLOBAL_OH_GCv5 )))GLOBAL_OH_GC14 #------------------------------------------------------------------------------ # --- Quantities needed for CH4 chemistry --- #------------------------------------------------------------------------------ # --- Global CH4 loss frequencies [1/s] ----------- (((CH4_LOSS_FREQ * CH4_LOSS $ROOT/CH4/v2024-01/GC_CH4_LOSS/GCC14_72LM.ch4loss.4x5.nc4 CH4loss 1985/1-12/1/0 C xyz s-1 * - 1 1 )))CH4_LOSS_FREQ # --- Global Cl [mol/mol dry air] --- (((GLOBAL_CL * GLOBAL_Cl $ROOT/CH4/v2024-01/GCC_14_Output/$YYYY/GEOSChem.SpeciesConc.$YYYY$MM01_0000z.nc4 SpeciesConc_Cl 2010-2019/1-12/1/0 C xyz 1 * - 1 1 )))GLOBAL_CL #------------------------------------------------------------------------------ # --- Quantities needed for CO chemistry --- #------------------------------------------------------------------------------ # -- P(CO) from CH4 and NMVOC from the last 10-yr benchmark [molec/cm3/s] --- (((PROD_CO_CH4 * PCO_CH4 $ROOT/CH4/v2024-01/GCC_14_Output/$YYYY/GEOSChem.ProdLoss.$YYYY$MM01_0000z.nc4 ProdCOfromCH4 2010-2019/1-12/1/0 C xyz 1 * - 1 1 )))PROD_CO_CH4 (((PROD_CO_NMVOC * PCO_NMVOC $ROOT/CH4/v2024-01/GCC_14_Output/$YYYY/GEOSChem.ProdLoss.$YYYY$MM01_0000z.nc4 ProdCOfromNMVOC 2010-2019/1-12/1/0 C xyz 1 * - 1 1 )))PROD_CO_NMVOC # --- GMI chemistry: prod/loss rates (for strato-/mesosphere) --- # --- Units: prod [v/v/s]; loss [1/s] --- (((USE_CO_DATA (((GMI_PROD_LOSS * GMI_LOSS_CO $ROOT/GMI/v2022-11/gmi.clim.CO.geos5.2x25.nc loss 2005/1-12/1/0 C xyz s-1 CO - 1 1 * GMI_PROD_CO $ROOT/GMI/v2022-11/gmi.clim.CO.geos5.2x25.nc prod 2005/1-12/1/0 C xyz v/v/s CO - 1 1 )))GMI_PROD_LOSS )))USE_CO_DATA # If CO is not an advected species, then just read as a chemistry input (((.not.USE_CO_DATA (((GMI_PROD_LOSS * GMI_LOSS_CO $ROOT/GMI/v2022-11/gmi.clim.CO.geos5.2x25.nc loss 2005/1-12/1/0 C xyz s-1 * - 1 1 * GMI_PROD_CO $ROOT/GMI/v2022-11/gmi.clim.CO.geos5.2x25.nc prod 2005/1-12/1/0 C xyz v/v/s * - 1 1 )))GMI_PROD_LOSS ))).not.USE_CO_DATA #------------------------------------------------------------------------------ # --- Quantities needed for CO2 chemistry --- #------------------------------------------------------------------------------ # --- CHEMICAL PRODUCTION FROM CO OXIDATION ------ # --- Recommended for use in forward modelling --- # --- Optional for inversion/assimilation -------- (((USE_CO2_DATA (((CO2_COPROD * CO2_COPROD $ROOT/CO2/v2024-01/CHEM/CO2_prod_rates.GEOS5.2x25.72L.nc LCO 2004-2009/1-12/1/0 C xyz kgC/m3/s * - 1 1 )))CO2_COPROD )))USE_CO2_DATA )))CHEMISTRY_INPUT ### END SECTION BASE EMISSIONS ### ############################################################################### ### BEGIN SECTION SCALE FACTORS ############################################################################### # ScalID Name sourceFile sourceVar sourceTime C/R/E SrcDim SrcUnit Oper #------------------------------------------------------------------------------ # --- Multiply by -1 to get a "negative" flux. #------------------------------------------------------------------------------ 1 NEGATIVE -1.0 - - - xy 1 1 #------------------------------------------------------------------------------ # --- Perturbation factors --- # # Add factors to perturb OH, emissions, and other fields here for # analytical inversions. #------------------------------------------------------------------------------ 2 OH_pert_factor 1.0 - - - xy 1 1 #============================================================================== # --- Scale factors for posterior run --- # # Enable emission scale factors by setting the use_emission_scale_factor or # use_OH_scale_factor options to true in geoschem_config.yml. These fields are # obtained from HEMCO and applied in GEOS-Chem/GeosCore/global_ch4_mod.F90. # # Entries below are provided for examples only. Add your own here! #============================================================================== (((Emis_PosteriorSF 3 EMIS_SF gridded_posterior.nc ScaleFactor 2000/1/1/0 C xy 1 1 )))Emis_PosteriorSF (((OH_PosteriorSF 4 OH_SF Post_SF_OH.nc SF_OH 2010-2017/1/1/0 C xy 1 1 )))OH_PosteriorSF #============================================================================== # --- Scale factors for analytical inversions --- #============================================================================== (((AnalyticalInversion # Add perturbations to individual state vector element (N) following this format # Start scale factor ID at 2000 to avoid conflicts with other SFs/masks #200N SCALE_ELEM_000N ./Perturbations.txt - - - xy count 1 )))AnalyticalInversion (((EMISSIONS #============================================================================== # --- Scale factors for CH4 emissions ---- #============================================================================== (((USE_CH4_DATA #------------------------------------------------------------------------------ # --- GHGI monthly scaling factors --- #------------------------------------------------------------------------------ (((GHGI_v2.or.GHGI_v2_Express_Ext 50 GHGI_OTH_STA_SF $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Gridded_GHGI_Methane_v2_Monthly_Scale_Factors_$YYYY.nc monthly_scale_factor_1A_Combustion_Stationary 2012-2018/1-12/1/0 C xy 1 1 51 GHGI_OIL_EXP_SF $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Gridded_GHGI_Methane_v2_Monthly_Scale_Factors_$YYYY.nc monthly_scale_factor_1B2a_Petroleum_Systems_Exploration 2012-2018/1-12/1/0 C xy 1 1 52 GHGI_OIL_PRD_SF $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Gridded_GHGI_Methane_v2_Monthly_Scale_Factors_$YYYY.nc monthly_scale_factor_1B2a_Petroleum_Systems_Production 2012-2018/1-12/1/0 C xy 1 1 53 GHGI_OIL_REF_SF $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Gridded_GHGI_Methane_v2_Monthly_Scale_Factors_$YYYY.nc monthly_scale_factor_1B2a_Petroleum_Systems_Refining 2012-2018/1-12/1/0 C xy 1 1 54 GHGI_OIL_TRA_SF $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Gridded_GHGI_Methane_v2_Monthly_Scale_Factors_$YYYY.nc monthly_scale_factor_1B2a_Petroleum_Systems_Transport 2012-2018/1-12/1/0 C xy 1 1 55 GHGI_GAS_EXP_SF $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Gridded_GHGI_Methane_v2_Monthly_Scale_Factors_$YYYY.nc monthly_scale_factor_1B2b_Natural_Gas_Exploration 2012-2018/1-12/1/0 C xy 1 1 56 GHGI_GAS_PRD_SF $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Gridded_GHGI_Methane_v2_Monthly_Scale_Factors_$YYYY.nc monthly_scale_factor_1B2b_Natural_Gas_Production 2012-2018/1-12/1/0 C xy 1 1 57 GHGI_LIV_MAN_SF $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Gridded_GHGI_Methane_v2_Monthly_Scale_Factors_$YYYY.nc monthly_scale_factor_3B_Manure_Management 2012-2018/1-12/1/0 C xy 1 1 58 GHGI_RIC_CUL_SF $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Gridded_GHGI_Methane_v2_Monthly_Scale_Factors_$YYYY.nc monthly_scale_factor_3C_Rice_Cultivation 2012-2018/1-12/1/0 C xy 1 1 59 GHGI_OTH_BUR_SF $ROOT/CH4/v2023-07/Gridded_GHGI_v2/Gridded_GHGI_Methane_v2_Monthly_Scale_Factors_$YYYY.nc monthly_scale_factor_3F_Field_Burning 2012-2018/1-12/1/0 C xy 1 1 )))GHGI_v2.or.GHGI_v2_Express_Ext #------------------------------------------------------------------------------ # --- Scarpelli et al Mexico manure & rice scale factors --- #------------------------------------------------------------------------------ (((Scarpelli_Mexico 10 MANURE_SF $ROOT/CH4/v2017-10/Seasonal_SF/EMICH4_Manure_ScalingFactors.WithClimatology.nc sf_ch4 2008-2016/1-12/1/0 C xy 1 1 11 RICE_SF $ROOT/CH4/v2017-10/Seasonal_SF/EMICH4_Rice_ScalingFactors.SetMissing.nc sf_ch4 2012/1-12/1/0 C xy 1 1 )))Scarpelli_Mexico )))USE_CH4_DATA #============================================================================== # --- Scale factors for CO2 emissions --- #============================================================================== (((USE_CO2_DATA #------------------------------------------------------------------------------ # --- FOSSIL FUEL CO2 SURFACE CORRECTION FACTOR --- # # Fossil fuel CO2 emissions must be scaled down to avoid counting emissions # already accounted for by CO and CH4 oxidation to CO2. # # The necssary annual reduction in emissions related to fossil fuels is # determined as: global C mass from FF (CO+CH4) / global C mass from FF CO2 # # Note: GEOS-Chem v8-03-02 to v9-02, assumed: 0.0489 for all years but that # value seems to correspond to mid-1980s fossil fuel combustion since CO # emissions have held constant (Granier et al., 2011) while CO2 has risen. # # All scale factors for years 2000-2013 lumped into a single entry #------------------------------------------------------------------------------ (((CO2CORR #410 CO2_FOSSFUEL_CORR 0.0489 - - - xy 1 1 ## CO2 scale factors from CO oxidation by decade (comment out for now) ##410 CO2_FOSSFUEL_CORR 0.052815/0.054486/0.054902/0.055107/0.053166/0.051611/0.050065/0.048803/0.047060/0.046041 - 1980-1989/1/1/0 C xy 1 1 ##410 CO2_FOSSFUEL_CORR 0.045816/0.045153/0.045541/0.045556/0.044800/0.043875/0.042910/0.042206/0.042257/0.042468 - 1990-1999/1/1/0 C xy 1 1 ##410 CO2_FOSSFUEL_CORR 0.041495/0.040525/0.040125/0.037853/0.035957/0.034686/0.033538/0.032771/0.031961/0.032118 - 2000-2009/1/1/0 C xy 1 1 ##410 CO2_FOSSFUEL_CORR 0.030622/0.029674/0.029029/0.028355 - 2010-2013/1/1/0 C xy 1 1 410 CO2_FOSSFUEL_CORR 0.041495/0.040525/0.040125/0.037853/0.035957/0.034686/0.033538/0.032771/0.031961/0.032118/0.030622/0.029674/0.029029/0.028355 - 2000-2013/1/1/0 C xy 1 1 )))CO2CORR # ----------------------------------------------------------------------------- # --- CO2 conversion factors --- # ----------------------------------------------------------------------------- 420 CH4TOCO2 2.75 - - - xy 1 1 421 CTOCO2 3.6667 - - - xy 1 1 430 NMHCSCALE 0.3333 - - - xy 1 1 #------------------------------------------------------------------------------ # --- National fossil fuel CO2 scale factors (Nassar et al, 2013) --- #------------------------------------------------------------------------------ (((FOSSIL_CDIAC.or.FOSSIL_ODIAC.or.CO2CORR 440 CO2_DIURNAL $ROOT/CO2/v2015-04/FOSSIL/TIMES_diurnal_scale_factors.nc diurnal_scale_factors 2006/1/1/1-24 C xy 1 1 441 CO2_WEEKLY $ROOT/CO2/v2015-04/FOSSIL/TIMES_weekly_scale_factors.nc weekly_scale_factors 2006/1/WD/0 C xy 1 1 )))FOSSIL_CDIAC.or.FOSSIL_ODIAC.or.CO2CORR #------------------------------------------------------------------------------ # --- DOMESTIC AVIATION SURFACE CORRECTION FACTOR --- # # Regional scale factors slightly less than 1 remove surface contribution from # domestic aviation in national fossil fuel emisisons, which should instead be # counted in the air as a 3D field. This scale factor should be applied to the # main/national fossil fuel emission field if using avaition emissions. #------------------------------------------------------------------------------ (((FOSSIL_CDIAC.or.FOSSIL_ODIAC.or.CO2CORR 480 AVIATION_SURF_CORR $ROOT/CO2/v2022-11/FOSSIL/Aviation_SurfCorr_SclFac.1x1.nc CO2 2004/1/1/0 C xy 1 1 )))FOSSIL_CDIAC.or.FOSSIL_ODIAC.or.CO2CORR )))USE_CO2_DATA #============================================================================== # --- Scale factors for CO emissions --- #============================================================================== (((USE_CO_DATA #------------------------------------------------------------------------------ # --- Diurnal scale factors for CO --- #------------------------------------------------------------------------------ 26 GEIA_TOD_FOSSIL 0.45/0.45/0.6/0.6/0.6/0.6/1.45/1.45/1.45/1.45/1.4/1.4/1.4/1.4/1.45/1.45/1.45/1.45/0.65/0.65/0.65/0.65/0.45/0.45 - - - xy 1 1 #------------------------------------------------------------------------------ # --- Diurnal variablity of Chinese power plants from Liu et al. (EST, 2019) --- # # Also need to undo (Oper=-1) the global diurnal scale factors over China #------------------------------------------------------------------------------ 35 PKU_pow_PM_BC_POC_VOC_CO 0.95/0.93/0.92/0.91/0.90/0.93/0.97/0.97/0.99/1.03/1.04/1.03/1.02/1.03/1.05/1.07/1.07/1.07/1.06/1.04/1.03/1.02/1.00/0.97 - - - xy unitless 1 2009 37 GEIA_TOD_FOSSIL_UNDO 0.45/0.45/0.6/0.6/0.6/0.6/1.45/1.45/1.45/1.45/1.4/1.4/1.4/1.4/1.45/1.45/1.45/1.45/0.65/0.65/0.65/0.65/0.45/0.45 - - - xy unitless -1 2009 #------------------------------------------------------------------------------ # --- Account for CO production by VOCs --- #------------------------------------------------------------------------------ (((APEI.or.EDGARv43.or.DICE_Africa.or.QFED2 52 COPROD_FOSSIL 1.02 - - - xy unitless 1 54 COPROD_BIOMASS 1.05 - - - xy unitless 1 )))APEI.or.EDGARv43.or.DICE_Africa.or.QFED2 #------------------------------------------------------------------------------ # --- DICE-Africa --- # Charcoal production scale factor to reduce charcoal production # by a factor of 5 after finding error in implementation of emission factors. #------------------------------------------------------------------------------ (((DICE_Africa 320 DICE_CP_SF 0.20 - - - xy 1 1 )))DICE_Africa #------------------------------------------------------------------------------ # --- CO: HTAP Annual scale factors --- #------------------------------------------------------------------------------ (((HTAP 506 LIQFUEL_THISYR $ROOT/AnnualScalar/v2014-07/AnnualScalar.geos.1x1.nc COscalar 1985-2010/1/1/0 C xy 1 1 507 LIQFUEL_1985 $ROOT/AnnualScalar/v2014-07/AnnualScalar.geos.1x1.nc COscalar 1985/1/1/0 C xy 1 -1 509 LIQFUEL_2006 $ROOT/AnnualScalar/v2014-07/AnnualScalar.geos.1x1.nc COscalar 2006/1/1/0 C xy 1 -1 510 LIQFUEL_2002 $ROOT/AnnualScalar/v2014-07/AnnualScalar.geos.1x1.nc COscalar 2002/1/1/0 C xy 1 -1 528 LIQFUEL_2008_2010 $ROOT/AnnualScalar/v2014-07/AnnualScalar.geos.1x1.nc COscalar 2008-2010/1/1/0 C xy 1 -1 )))HTAP )))USE_CO_DATA #============================================================================== # --- Scale factors for OCS emissions --- #============================================================================== (((USE_OCS_DATA #------------------------------------------------------------------------------ # --- S to OCS ratio --- #------------------------------------------------------------------------------ 70 StoOCS MATH:60.07/32.06 - - - xy unitless 1 #------------------------------------------------------------------------------ # --- km-2 to m-2 --- #------------------------------------------------------------------------------ 71 Km2ToM2 1.0e-6 - - - xy unitless 1 )))USE_OCS_DATA #============================================================================== # --- Inventory-specific scale factors --- #============================================================================== #------------------------------------------------------------------------------ # --- AEIC2019 aircraft emissions scale factors --- # # See http://geoschemdata.wustl.edu/ExtData/HEMCO/AEIC2019/v2022-03/AEIC_2019_technical_note.pdf # # Scaling factors for 1990-2019 derived from Lee et al. (2021). Lee et al. # (2021) only covers 1990 to 2018, so to get to 2019 it is assumed that the # growth from 2017 to 2018 is the same as that from 2018 to 2019. # So the formula is something like: # # Emissions of CO in 2009 = AEIC 2019 emissions of CO # * (Lee 2017 CO / Lee 2018 fuel burn) # * (Lee 2009 fuel burn / Lee 2018 fuel burn) # # So in this case, we use the Lee 2017/Lee 2018 value to scale AEIC’s # emissions to the “2018” values, and then scale directly using the Lee et al # fuel burn. This ensures that, when running with year 2019, you get an # unadjusted version of the AEIC2019 inventory, and all previous years are # scaled down. # # All scaling factors are included in here in HEMCO_Config.rc. #------------------------------------------------------------------------------ (((AEIC2019_DAILY.or.AEIC2019_MONMEAN # If applying 1990-2019 scale factors (((AEIC_SCALE_1990_2019 241 AC_FBMULT 0.506/0.489/0.490/0.493/0.517/0.529/0.553/0.570/0.581/0.600/0.631/0.607/0.608/0.608/0.646/0.678/0.686/0.706/0.703/0.666/0.700/0.721/0.728/0.749/0.773/0.815/0.854/0.905/0.952/1.000 - 1990-2019/1/1/0 C xy 1 1 )))AEIC_SCALE_1990_2019 # If not applying 1990-2019 scale factors, use 1.0 (((.not.AEIC_SCALE_1990_2019 241 AC_FBMULT 1.000000e+0 - - - xy 1 1 ))).not.AEIC_SCALE_1990_2019 # Assume 3.159 kg CO2 from every kg of fuel burned # cf Hileman, Stratton, & Donohoo, _J. Propul. Power_, 26(6), 1184–1196, 2010. 260 AEIC19_FBtoCO2 3.159 - - - xy unitless 1 )))AEIC2019_DAILY.or.AEIC2019_MONMEAN #------------------------------------------------------------------------------ # --- CEDS vertical partitioning --- #------------------------------------------------------------------------------ (((CEDSv2.or.CEDS_GBDMAPS 315 ENERGY_LEVS $ROOT/VerticalScaleFactors/v2021-05/gc_layers.nc g_energy 2017/1/1/0 C xyz 1 1 316 INDUSTRY_LEVS $ROOT/VerticalScaleFactors/v2021-05/gc_layers.nc g_industry 2017/1/1/0 C xyz 1 1 317 SHIP_LEVS $ROOT/VerticalScaleFactors/v2021-05/gc_layers.nc cmv_c3 2017/1/1/0 C xyz 1 1 )))CEDSv2.or.CEDS_GBDMAPS #------------------------------------------------------------------------------ # --- GFAS scale factors --- #------------------------------------------------------------------------------ (((GFAS 300 GFAS_EMITL $ROOT/GFAS/v2018-09/$YYYY/GFAS_$YYYY$MM.nc mami 2003-2021/1-12/1-31/0 C xy m 1 )))GFAS #------------------------------------------------------------------------------ # --- EPA NEI2016 (monthly-mean inventory) scale factors --- #------------------------------------------------------------------------------ (((NEI2016_MONMEAN # Weekday/Weekend scale factors 211 NEI99_DOW_CO $ROOT/NEI2005/v2023-02/NEI99.dow.geos.1x1.corrected.012023.nc CO 1999/1-12/WD/0 C xy 1 1 # Annual scale factors were computed from the EPA Trends Report for Tier 1 CAPS # (obtained 21 Sep 2021) using the "Total without wildfires" field. NH3 and # PM2.5 only had values for 2002-2020, while the remaining species had yearly # values for 1990-2020 (we include only 2002-2020 here). # See NEI2016/v2021-06/national_tier1_caps+HEMCOscaling.xlsx for details. 252 NEI2016_CO_YRSCALE 1.817/1.767/1.716/1.666/1.610/1.554/1.393/1.251/1.272/1.261/1.220/1.178/1.137/1.095/1.000/0.973/0.950/0.927/0.904 - 2002-2020/1/1/0 C xy 1 1 )))NEI2016_MONMEAN #------------------------------------------------------------------------------ # --- QFED2 diurnal scale factors --- # Fire diurnal scaling factors (% per hour) from WRAP Report to Project # No. 178-6, July 2005 #------------------------------------------------------------------------------ (((QFED2.or.GFAS.or.BB4MIPS 75 QFED2_TOD 0.1392/0.1392/0.1368/0.1368/0.1368/0.1368/0.1368/0.1368/0.1368/0.48/0.96/1.68/2.4/3.12/3.84/4.08/2.88/1.68/0.96/0.1368/0.1368/0.1368/0.1368/0.1368 - - - xy unitless 1 )))QFED2.or.GFAS.or.BB4MIPS #------------------------------------------------------------------------------ # --- QFED vertical partitioning --- # Following Fischer et al. (2014) and Travis et al. (2016), # emit 35% of QFED emissions above the PBL. #------------------------------------------------------------------------------ (((QFED2 311 QFED_PBL_FRAC 0.65 - - - xy 1 1 312 QFED_FT_FRAC 0.35 - - - xy 1 1 )))QFED2 (((CEDSv2 #========================================================================= # --- Sector-wise diel scale factors for CEDSv2 --- # These scale factors could potentially be used for other global base emissions if modified accordingly. #========================================================================= 2401 TOD_AGRICULTURE 0.599/0.599/0.599/0.599/0.599/0.649/0.748/0.898/1.098/1.247/1.447/1.597/1.796/1.746/1.696/1.547/1.347/1.098/0.898/0.748/0.649/0.599/0.599/0.599 - - - xy unitless 1 2406 TOD_ENERGY 0.790/0.720/0.720/0.710/0.740/0.800/0.920/1.080/1.190/1.220/1.210/1.210/1.170/1.150/1.140/1.130/1.100/1.070/1.040/1.020/1.020/1.010/0.960/0.880 - - - xy unitless 1 2407 TOD_INDUSTRY 0.750/0.750/0.780/0.820/0.880/0.950/1.020/1.090/1.160/1.220/1.280/1.300/1.220/1.240/1.250/1.160/1.080/1.010/0.950/0.900/0.850/0.810/0.780/0.750 - - - xy unitless 1 2409 TOD_RESIDENTIAL 0.393/0.393/0.393/0.393/0.393/0.492/1.180/1.475/1.574/1.574/1.377/1.180/1.082/1.082/0.984/0.984/0.984/1.082/1.377/1.475/1.377/1.377/0.984/0.393 - - - xy unitless 1 2411 TOD_TRANSPORT 0.190/0.090/0.060/0.050/0.090/0.220/0.860/1.840/1.860/1.410/1.240/1.200/1.320/1.440/1.450/1.590/2.030/2.080/1.510/1.060/0.740/0.620/0.610/0.440 - - - xy unitless 1 #========================================================================= # --- Sector-wise day-of-week scale factors for CEDSv2 --- # These scale factors could potentially be used for other global base emissions if modified accordingly. #========================================================================= 706 DOW_ENERGY 0.850/1.060/1.060/1.060/1.060/1.060/0.850 - - - xy unitless 1 707 DOW_INDUSTRY 0.800/1.080/1.080/1.080/1.080/1.080/0.800 - - - xy unitless 1 709 DOW_RESIDENTIAL 0.800/1.080/1.080/1.080/1.080/1.080/0.800 - - - xy unitless 1 711 DOW_TRANSPORT 0.790/1.020/1.060/1.080/1.100/1.140/0.810 - - - xy unitless 1 )))CEDSv2 )))EMISSIONS ### END SECTION SCALE FACTORS ### ############################################################################### ### BEGIN SECTION MASKS ############################################################################### # ScalID Name sourceFile sourceVar sourceTime C/R/E SrcDim SrcUnit Oper Lon1/Lat1/Lon2/Lat2 (((EMISSIONS #============================================================================== # --- Masks used for CH4 simulation emissions --- #============================================================================== (((USE_CH4_DATA (((Scarpelli_Mexico 1001 MEX_MASK $ROOT/MASKS/v2024-04/Mexico_Mask.01x01.nc MASK 2000/1/1/0 C xy 1 1 -118/17/-95/33 1010 MEX_MASK_MIRROR $ROOT/MASKS/v2024-04/Mexico_Mask_Mirror.01x01.nc MASK 2000/1/1/0 C xy 1 1 -118/17/-95/33 )))Scarpelli_Mexico (((Scarpelli_Canada 1002 CAN_MASK $ROOT/MASKS/v2024-04/Canada_Mask.01x01.nc MASK 2000/1/1/0 C xy 1 1 -141/40/-52/85 1011 CAN_MASK_MIRROR $ROOT/MASKS/v2024-04/Canada_Mask_Mirror.01x01.nc MASK 2000/1/1/0 C xy 1 1 -141/40/-52/85 )))Scarpelli_Canada (((GHGI_v2.or.GHGI_v2_Express_Ext 1008 CONUS_MASK $ROOT/MASKS/v2024-04/CONUS_Mask.01x01.nc MASK 2000/1/1/0 C xy 1 1 -140/20/-50/60 1009 CONUS_MASK_MIRROR $ROOT/MASKS/v2024-04/CONUS_Mask_Mirror.01x01.nc MASK 2000/1/1/0 C xy 1 1 -140/20/-50/60 )))GHGI_v2.or.GHGI_v2_Express_Ext )))USE_CH4_DATA #============================================================================== # --- Masks used for CO and CO2 simulation emissions --- #============================================================================== (((USE_CO_DATA.or.USE_CO2_DATA (((APEI 2002 CANADA_MASK $ROOT/MASKS/v2018-09/Canada_mask.geos.1x1.nc MASK 2000/1/1/0 C xy 1 1 -141/40/-52/85 )))APEI # Renamed to avoid a namespace collision w/ GHGI mask above!!! (((NEI2016_MONMEAN 2007 NEI_CONUS_MASK $ROOT/MASKS/v2018-09/CONUS_Mask.01x01.nc MASK 2000/1/1/0 C xy 1 1 -140/20/-50/60 )))NEI2016_MONMEAN (((DICE_Africa 2008 AFRICA_MASK $ROOT/MASKS/v2018-09/AF_LANDMASK.geos.05x0666.global.nc LANDMASK 1985/1/1/0 C xy 1 1 -20/-37/54/40 )))DICE_Africa )))USE_CO_DATA.or.USE_CO2_DATA #============================================================================== # --- Masks used for CH4, CO and CO2 simulation emissions --- #============================================================================== (((CEDSv2.or.CEDS_GBDMAPS.or.CEDS_GBDMAPS_byFuelType 2009 CHINA_MASK $ROOT/MASKS/v2018-09/China_mask.generic.1x1.nc MASK 2000/1/1/0 C xy 1 1 70/10/150/60 )))CEDSv2.or.CEDS_GBDMAPS.or.CEDS_GBDMAPS_byFuelType #(((RESERVOIRS #1500 SEASONAL_RES_MASK $ROOT/CH4/v2024-01/ResME/reservoir_mask.01x01.nc Mask 2022/1-12/1/0 C xy 1 1 -180/-90/180/90 #)))RESERVOIRS )))EMISSIONS ### END SECTION MASKS ### ############################################################################### ### REFERENCES ############################################################################### # # Andres. 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Barrett, Aviation Emissions Inventory # Code (AEIC ) User Manual (R1), Laboratory for Aviation and the Environment, # Massachusetts Institute of Technology, January 2013, Report No: # LAE-2013-001-N, # www.LAE.MIT.edu. # # Takahashi, T., et al. (2009), Climatological mean and decadal change in # surface ocean pCO2, and net sea-air CO2 flux over the global oceans, Deep-Sea # Res. II, 56(8?10), 554?577, doi:10.1016/j.dsr2.2008.12.009. # ### END OF HEMCO INPUT FILE ### #EOC