Skip to content

MOM6 coupled model configuration for replaying to MERRA 2 reanalysis

Santha Akella edited this page Nov 19, 2022 · 4 revisions

All remain same as in these sample files, except AGCM.rc. For your convenience see below.


# Atmospheric Model Configuration Parameters
# ------------------------------------------
           NX: 10
           NY: 36

 IOSERVER_NODES: 2
NUM_BACKEND_PES: 9

      AGCM_IM: 180
      AGCM_JM: 1080
      AGCM_LM: 72
AGCM_GRIDNAME: PE180x1080-CF

      AGCM.GRID_TYPE: Cubed-Sphere
      AGCM.GRIDNAME: PE180x1080-CF
       AGCM.NF: 6
      AGCM.LM: 72
      AGCM.IM_WORLD: 180

DYCORE: FV3

 SOLAR_DT: 3600
 IRRAD_DT: 3600
SATSIM_DT: 1800

SOLARAvrg: 0
IRRADAvrg: 0

EOT: .TRUE.
ORBIT_ANAL2B: .TRUE.

# UNCOMMENT to use Morrison-Gettelman-Barahona cloud microphysics
CLDMICRO: 1MOMENT

# UNCOMMENT to use GFDL 6-phase cloud microphysics
# CLDMICRO: GFDL
# UNCOMMENT to when GFDL microphysics is run with NonHydrostatic FV3
# HYDROSTATIC: FALSE

# UNCOMMENT to disable aerosol activation in 1-moment cloud microphysics
#USE_AEROSOL_NN: 0

###########################################################
# Flag for definition of the convection scheme
# The options are RAS or GF
# ----------------------------------------
CONVPAR_OPTION: GF

# Override default aerosol convective scavenging and use dz method
USE_TRACER_SCAVEN: 1

# Flag to activated scale-awareness approach (0 false, 1 true)
USE_SCALE_DEP: 1

# Flag to activated diurnal cycle closure (0 false, 1 true)
DICYCLE: 1

# Convective plumes to be activated (1 true, 0 false)
# ----------------------------------------
DEEP: 1
SHALLOW: 0
CONGESTUS: 1

# UW shallow cumulus settings
DOSHLW: 1

# Choice for the closures:
# ----------------------------------------
# deep : 0 ensemble (all) , 1 GR, 4 ll omega, 7 moist conv, 10 PB
# shallow : 0 ensemble (Wstar/BLQE) , 1 Wstar, 4 heat-engine or 7 BLQE
# congestus: 0 ensemble (Wstar/BLQE/PB), 1 Wstar, 2 BLQE, 3 PB, 4 PB_BL
CLOSURE_DEEP:0
CLOSURE_SHALLOW:7
CLOSURE_CONGESTUS:3

# GWD Parameterization
# --------------------

# if .FALSE., use GEOS GWD code (default); .TRUE., use new NCAR GWD code
USE_NCAR_GWD: .FALSE.

# This is only used if USE_NCAR_GWD is .TRUE.
BERES_FILE_NAME: ExtData/g5gcm/gwd/newmfspectra40_dc25.nc

# Ocean Model Configuration Parameters
# ------------------------------------
      OGCM.GRID_TYPE: Tripolar
      OGCM.GRIDNAME: PE1440x1080-TM
      OGCM.IM_WORLD: 1440
      OGCM.JM_WORLD: 1080
      OGCM.LM: 75
       OGCM.NX: 36
       OGCM.NY: 10
       OGCM.GRIDSPEC: MAPL_Tripolar.nc


OGCM_RUN_DT: 450

##############################################################################################
####                                                                                      ####
####   SST REMAPPING                                                                      ####
####      Comparing Grid Resolutions of GRID_ocean and GRID_atmos:                        ####
####                                                                                      ####
####         IF(       GRID_ocean is equal  resolution to   GRID_atmos )  THEN            ####
####             INTERPOLATE_SST = 0 ! Conservatively BIN   GRID_ocean to GRID_atmos      ####
####         ELSE IF ( GRID_ocean is higher resolution than GRID_atmos )  THEN            ####
####             INTERPOLATE_SST = 0 ! Conservatively BIN   GRID_ocean to GRID_atmos      ####
####         ELSE    ( GRID_ocean is lower  resolution than GRID_atmos )                  ####
####             INTERPOLATE_SST = 1 ! Linearly Interpolate GRID_ocean to GRID_atmos      ####
####         ENDIF                                                                        ####
####                                                                                      ####
##############################################################################################

# INTERPOLATE_SST: 0 or 1 # (Default based on comparison of GRID_ocean and GRID_atmos)

# Print Resource Parameters (0: Non-Default values, 1: ALL values)
#-----------------------------------------------------------------
PRINTRC: 1

# Set the number of parallel I/O processes to use when
# RESTART_TYPE and or CHECKPOINT_TYPE are set to pbinary or pnc4
#---------------------------------------------------------------
PARALLEL_READFORCING: 0
NUM_READERS: 2
NUM_WRITERS: 1

# Write restarts by oserver (Default: NO)
WRITE_RESTART_BY_OSERVER: NO

# Active observer when desired
# ----------------------------
BKG_FREQUENCY: 0

# Resolution of state passed to atmos analysis
# --------------------------------------------
ANA_GRIDNAME: PC180x1080-DC
ANA_LM: 72

# Restart Record Parameters
# -------------------------
#RECORD_FINAL:  >>>RECFINL<<<
#RECORD_FREQUENCY: 000000       000000
#RECORD_REF_DATE: >>>REFDATE<<< >>>FCSDATE<<<
#RECORD_REF_TIME: >>>REFTIME<<< >>>FCSTIME<<<


###################################################################################################
####                                   DAS/Replay Options                                      ####
####                                   ------------------                                      ####
####                                                                                           ####
####   The REPLAY mechanism operates within 2 distinct "flavors":                              ####
####              1) Exact    (Uses Archived Increment Files)                                  ####
####              2) Regular  (Uses Archived Analysis/Assimilation Files)                      ####
####                                                                                           ####
####   Exact Replays identically reproduce (bit-for-bit) a previous GEOS DAS experiment        ####
####         by simply using the archived IAU forcing from the DAS experiment.                 ####
####         For these cases, only the CORRECTOR step is employed and is, therefore, as        ####
####         efficient as a stand-alone model run.                                             ####
####                                                                                           ####
####         In order to guarantee reproducibility, the model and its BUILD parameters         ####
####         (Compilers and Options) as well as all INPUT data must be identical to the        ####
####         original DAS experiment.  This type of REPLAY is useful when producing            ####
####         additional passive, diagnostic data, or when the original data is lost.           ####
####                                                                                           ####
####                                                                                           ####
####   Regular Replays are used to mimic the original IAU methodology, i.e., both the          ####
####           PREDICTOR and the CORRECTOR steps are employed.  The key difference being       ####
####           that the Analysis is based on archived datasets.  These Analyses may be from    ####
####           the GEOS DAS system, or from any other source that is written using the         ####
####           appropriate GEOS DAS ana.eta data format.                                       ####
####                                                                                           ####
####           Regular Replays will reproduce data (bit-for-bit) from the original source      ####
####           Analysis experiment provided all model, input data, and Predictor/Corrector     ####
####           configurations are identical to the original experiment.  Otherwise,            ####
####           differences in the model and/or IAU procedure will produce changes to the       ####
####           assimilation and forecasts which may improve or degrade the results.            ####
####                                                                                           ####
####                                                                                           ####
####   Note:  The Operational GEOS DAS always operates in an "Exact" mode since the IAU        ####
####        Increments are produced off-line, separate from the GCM and GSI executables,       ####
####        based on ana.eta and bkg.eta files.  Thus, the increments produces from these      ####
####        files are REPLAYed in an "Exact" manner.                                           ####
####                                                                                           ####
####                                                                                           ####
####   Exact Replay Details:                                                                   ####
####   ---------------------                                                                   ####
####        Exact Replays perform the CORRECTOR step by integrating the model forward in       ####
####        time forced by the IAU Analysis increments.  In MERRA-2, a single Analysis was     ####
####        computed at the center of the Assimilation Cycle (6-hrs). Thus, as an example,     ####
####        the cycle between 21z (or -03z) and +03z used the single Analysis at the synoptic  ####
####        time of 00z.  In contrast, the 4D-EnVar system produces 7 hourly Analyses (-03z,   ####
####        -02z, -01z, 00z, +01z, +02z, +03z). The IAU sequence currently employed uses       ####
####        the 3 Analyses defined at -03z, 00z, +03z for its IAU forcing.  Both systems       ####
####        may be described using the following parameters:                                   ####
####                                                                                           ####
####        CORRECTOR_DURATION          nnnnnn   (Duration -in seconds- of Corrector step)     ####
####        REPLAY_MODE                 Exact                                                  ####
####        REPLAY_FILE                 %s.agcm_import_rst.%y4%m2%d2_%h2z.bin                  ####
####        REPLAY_FILE_FREQUENCY       nnnnnn   (Default: CORRECTOR_DURATION)                 ####
####        REPLAY_FILE_REFERENCE_TIME  HHMMSS   (Default: 000000)                             ####
####                                                                                           ####
####        Thus, MERRA-2 => CORRECTOR_DURATION         =  21600                               ####
####                         REPLAY_FILE_FREQUENCY      =  21600                               ####
####                         REPLAY_FILE_REFERENCE_TIME = 000000                               ####
####                                                                                           ####
####             4D_EnVar => CORRECTOR_DURATION         =  21600                               ####
####                         REPLAY_FILE_FREQUENCY      =  10800                               ####
####                         REPLAY_FILE_REFERENCE_TIME = 000000                               ####
####                                                                                           ####
####        Note: the Digital Filter (if used) is configured to provide its maximum impact     ####
####        centered at the time(s) of the Analyses (00z for MERRA-2, and -03z, 00z, +03z      ####
####        for 4D-EnVar).                                                                     ####
####                                                                                           ####
####                                                                                           ####
####   Regular Replay Details:                                                                 ####
####   -----------------------                                                                 ####
####        Regular Replay involves both the PREDICTOR and the CORRECTOR steps.  If a single   ####
####        Analysis is used within the CORRECTOR window (e.g., as in MERRA-2), the PREDICTOR  ####
####        duration would be defined as the time from the beginning of the CORRECTOR step to  ####
####        the time of the Analysis (e.g., 3-hours for the MERRA-2 system).  However, if      ####
####        multiple Analyses are used within the CORRECTOR window, the PREDICTOR duration     ####
####        would be defined as the time from the beginning of the CORRECTOR step to the time  ####
####        of the Last Analysis.  Therefore, the length of the PREDICTOR step is computed     ####
####        based on the FREQUENCY and REFERENCE TIME of the REPLAYed Analysis/Assimilation    ####
####        files.  Once the Increment file(s) are created, the model rewinds to the beginning ####
####        of the CORRECTOR step and performs an EXACT Replay to the just-produced files.     ####
####                                                                                           ####
####                                                                                           ####
####   Replay09 File Details:                                                                  ####
####   ----------------------                                                                  ####
####        The current 4D-EnVar system, as previously noted, produces 7 hourly Analyses:      ####
####        (-03z, -02z, -01z, 00z, +01z, +02z, +03z) for each 6-hour assimilation window      ####
####        centered around the 4 synoptic times of 00z, 06z, 12z, and 18z.  We see that the   ####
####        last Analysis (+03z) associated with each synoptic time will be over-ridden by     ####
####        the first Analyiss (-03z) associated with synoptic time of the next assimilation   ####
####        window. To prevent these over-ridden files from being lost, the GEOS-5 DAS         ####
####        archives the (+03z) data with an appended "09" characterization (e.g., bkg09.eta,  ####
####        ana09.eta, agcm09_import).  Therefore, when running REPLAY, care must be given     ####
####        to identify the Replay09 files if needed.  A separate REPLAY_FILE09 key word is    ####
####        used for this purpose, and is only utilized if the REPLAY configuration warrants.  ####
####                                                                                           ####
####                                                                                           ####
####   Regular Replay Time Interpolation:                                                      ####
####   ----------------------------------                                                      ####
####        In some instances the USER might wish to create IAU Increments at a frequency      ####
####        greater than the frequency of the target analysis.  For those cases additional     ####
####        parameters are introduced and used in coordination with the standard REPLAY        ####
####        parameters:                                                                        ####
####                                                                                           ####
####            Standard:    REPLAY_FILE_FREQUENCY      =  nnnnn                               ####
####                         REPLAY_FILE_REFERENCE_TIME = HHMMSS                               ####
####          Additional:          MKIAU_FREQUENCY      =  nnnnn                               ####
####                               MKIAU_REFERENCE_TIME = HHMMSS                               ####
####                               REPLAY_TIME_INTERP   = LINEAR (Default) or CUBIC            ####
####                                                                                           ####
####        When the additional parameters are invoked, the system time-interpolates the       ####
####        REPLAY_FILE analyses to the times referenced by the MKIAU variables to create      ####
####        the associated increment files.  The time-interpolation is done via a LINEAR       ####
####        or CUBIC scheme.                                                                   ####
####                                                                                           ####
###################################################################################################

#   ASSIMILATION_CYCLE:  nnnnnn       #  (Default: 21600)
#   IAU_DIGITAL_FILTER:  YES or NO    #  (Default: YES  )
 
# Typical MERRA-2 Regular REPLAY Configuration
# --------------------------------------------
  REPLAY_ANA_EXPID:   MERRA-2
  REPLAY_ANA_LOCATION: /discover/nobackup/projects/gmao/share/gmao_ops/verification/MERRA-2
  REPLAY_MODE: Regular
  REPLAY_FILE: ana/Y%y4/M%m2/MERRA-2.ana.eta.%y4%m2%d2_%h2z.nc4
# -----------------------------------------------------------------

#   ANA EXPID and LOCATION used for REPLAY
#   --------------------------------------
#   REPLAY_ANA_EXPID:    x0039
#   REPLAY_ANA_LOCATION: /discover/nobackup/projects/gmao/g6dev/ltakacs/x0039

#   Typical Exact REPLAY Configuration
#   ----------------------------------
#   REPLAY_MODE: Exact
#   REPLAY_FILE:   rs/Y%y4/M%m2/x0039.agcm_import_rst.%y4%m2%d2_%h2z.bin
#   REPLAY_FILE09: rs/Y%y4/M%m2/x0039.agcm09_import_rst.%y4%m2%d2_%h2z.bin
#   REPLAY_FILE_FREQUENCY: 10800
#   REPLAY_FILE_REFERENCE_TIME: 000000

#   Typical Regular REPLAY Configuration
#   ------------------------------------
#   REPLAY_MODE: Regular
#   REPLAY_FILE:   ana/Y%y4/M%m2/x0039.ana.eta.%y4%m2%d2_%h2z.nc4
#   REPLAY_FILE09: ana/Y%y4/M%m2/x0039.ana09.eta.%y4%m2%d2_%h2z.nc4
#   REPLAY_FILE_FREQUENCY:       10800
#   REPLAY_FILE_REFERENCE_TIME: 000000


#   4DIAU (recreate analysis tendency on the fly)
#   ---------------------------------------------

#   Exact REPLAY Mode for 4D-IAU
#   ----------------------------


####################################################################################################
####                    Miscellaneous Exact/Regular REPLAY Parameters                           ####
####                    ---------------------------------------------                           ####
####                                                                                            ####
####   REPLAY FILE MUST be on an A-Grid!                                                        ####
####                                                                                            ####
####   REPLAY Variable Defaults: p,u,v,t,qv,o3                                                  ####
####   REPLAY Variables are set to either:  YES,  NO,  or a character_string NAME.              ####
####   The NAME is used as a means of creating an ALIAS for the REPLAY variable.                ####
####   An ALIAS is required when the REPLAY FILE contains a variable name NOT included          ####
####   in our standard list. (e.g.,  REPLAY_T: temperature)                                     ####
####                                                                                            ####
####   NOTE:  When using an ALIAS for REPLAY_T, you must also supply the REPLAY_T_TYPE          ####
####   -----  REPLAY_T_TYPE: T        # Options: T,TV,TH,THV                                    ####
####                                                                                            ####
####   REPLAY Variables may be disabled by setting resource parameter to: NO                    ####
####          (E.g., REPLAY_QV: NO to disable REPLAY of Moisture).                              ####
####                                                                                            ####
####                                                                                            ####
####################################################################################################
#
#   BKG2ANACNSRV: 0 or 1    # (Defaults to 0:BiLinear Interpolation.  Note: Conservative Transformation creates Non-Wavenumber 1 Winds at Poles)
#   ANA2BKGCNSRV: 0 or 1    # (Defaults to 0:BiLinear Interpolation.  Note: Conservative Transformation creates Non-Wavenumber 1 Winds at Poles)
#
#   Regular REPLAY Variables (Change only if desired REPLAY is different from Default)
#   ----------------------------------------------------------------------------------
    REPLAY_P:  YES     #  (Default: YES)
    REPLAY_U:  YES     #  (Default: YES)
    REPLAY_V:  YES     #  (Default: YES)
    REPLAY_T:  YES     #  (Default: YES)
    REPLAY_QV: YES     #  (Default: YES)
    REPLAY_O3: YES     #  (Default: YES)
    REPLAY_TS: NO      #  (Default:  NO)
#
#   Regular REPLAY Remapping and Blending Variables
#   -----------------------------------------------
#   REPLAY_REMAP:    YES    #  Default = YES,  Remap ANA Data to BKG Topography
#   REPLAY_DAMPBEG:  100.0  #  Default =  1,   Linearly Damp Increments between DAMPBEG & DAMPEND (Pascals)
#   REPLAY_DAMPEND: 5000.0  #  Default =  1,   Linearly Damp Increments between DAMPBEG & DAMPEND (Pascals)
#   REPLAY_SHUTOFF: 21600   #  ShutOff Replay after 6-hours of Integration
#   REPLAY_WINDFIX: YES     #  Apply windfix to force vertically-integrated analysis divergence increment to zero
#
#   REPLAY_BLEND_QV_AT_TP: .FALSE. #  Default = FALSE,  Blend QV to BKG upwards from tropopause
#
#
##############################################################################################
####                               Intermittent Replay Options                            ####
####                                                                                      ####
####     Intermittent:  Within this mode two possibilities are available:                 ####
####                 1) Replay to full field:                                             ####
####                    Replays to an existing Analysis by "Dump & Splash".               ####
####                    RePlay File:  %s.bkg.eta.%y4%m2%d2_%h2z.NCSUFFIX                  ####
####                    Note: BKG.ETA (hour-3) files are used since they                  ####
####                    contain the previous full analysis increment and are              ####
####                    well balanced.  Do not use DAMP parameters.                       ####
####                    RePlay Name Default: uwnd,vwnd,theta,sphu,ps,delp,ozone           ####
####                    REPLAY_GRID Options: D-GRID (Default), A-GRID                     ####
####                    REPLAY_TVAR Options: THETAV (Default), THETA, TV, T               ####
####                 2) Replay to an increment: (only cubed-dynamics for now)             ####
####                    Replay to an existing Analysis Increment as e.g,                  ####
####                    RePlay File:  %s.inc.eta.%y4%m2%d2_%h2z.NCSUFFIX                  ####
####                    You much as specify REPLAY_IM and REPLAY_JM as                    ####
####                    well as set REPLAY_TYPE: Incremental; this is                     ####
####                    in addition to the MODE Intermittent. In some cases               ####
####                    you might set the parameter REPLAY_REF_TGAP to be                 ####
####                    equal to RUN_DT (but in HHMMSS) to avoid increment                ####
####                    being taken one DT out of sync (this can also be used             ####
####                    in (1) above).                                                    ####
####                                                                                      ####
####                    Note: RePlay Blending Options Currently Pertain                   ####
####                    to Intermittent Mode  (see FVdycore_GridCompMod.F90)              ####
####                                                                                      ####
##############################################################################################

##REPLAY_TYPE: Incremental
##REPLAY_FILE: C590a.inc.eta.%y4%m2%d2_%h2z.nc4
##REPLAY_IM: 576
##REPLAY_JM: 361
##REPLAY_REF_DATE: >>>ANADATE<<<
##REPLAY_REF_TIME: >>>ANATIME<<<
##REPLAY_REF_TGAP: 001500

#REPLAY_MODE: Intermittent 
#REPLAY_FILE: /discover/nobackup/projects/gmao/iesa/aerosol/Data/MERRA/iReplay/576x361/Y%y4/M%m2/d5_merra_jan98.bkg.eta.%y4%m2%d2_%h2z.nc4
#REPLAY_IM:    576            # Required for Intermittent Replay on Cube
#REPLAY_JM:    361            # Required for Intermittent Replay on Cube

#REPLAY_GRID:  A-GRID      # (!! For Intermittent Replay Only !!) Standard Options: D-GRID (Default), A-GRID
#REPLAY_TSNAME: NULL
#REPLAY_UNAME: u
#REPLAY_VNAME: v
#REPLAY_TNAME: tv
#REPLAY_TVAR:  TV             # Standard Options: THETAV (Default), THETA, TV, T

#REPLAY_REMAP: NO             # Standard Options: NO  - Intermittent Replay (Cube Only)

#REPLAY_BLEND: 0              # Standard Option:   0    - no blending
#REPLAY_BLEND_P_ABOVE:  10.0  # Standard Option:  10 Pa - highest of the two blending pressure levels
#REPLAY_BLEND_P_BELOW: 100.0  # Standard Option: 100 Pa - lowest  of the two blending pressure levels
#REPLAY_BLEND_QV_AT_TP: .FALSE. # Default = .FALSE.  Blend QV to BKG upwards from tropopause


##############################################################################################
####                                   REPLAY PRECIPITATION                               ####
##############################################################################################
#
# REPLAY PRECIP Parameters
# ------------------------
# To REPLAY to CMAP-based precip files, you must symbolically link into your work area the datastreams from MERRA_LAND:
#
#    Option 1) CMAP-CPCU Corrected (Used for NCA Project)
#    ----------------------------------------------------
#    /bin/ln -s /gpfsm/dnb51/projects/p15/iau/merra_land/precip_CPCU-CMAP_corrected_MERRA/GEOSdas-2_1_4 ExtData/PCP
#
#         Then, you must replace the token after PRECIP_FILE with the proper datastream for the desired years:
#         ----------------------------------------------------------------------------------------------------
#         Years 1978-1993: d5_merra_jan79/diag/Y%y4/d5_merra_jan79.tavg1_2d_lfo_Nx_corr.%y4%m2%d2_%h230z.nc (Currently Not ONLINE)
#         Years 1988-2001: d5_merra_jan89/diag/Y%y4/d5_merra_jan89.tavg1_2d_lfo_Nx_corr.%y4%m2%d2_%h230z.nc (Currently Not ONLINE)
#         Years 1999-2014: d5_merra_jan98/diag/Y%y4/d5_merra_jan98.tavg1_2d_lfo_Nx_corr.%y4%m2%d2_%h230z.nc
#         ---------------
#
#    Option 2) CMAP-GPCP Corrected (from MERRA-Land)
#    -----------------------------------------------
#    /bin/ln -s /discover/nobackup/projects/gmao/share/gmao_ops/fvInput/merra_land/precip_CPCUexcludeAfrica-CMAP_corrected_MERRA/GEOSdas-2_1_4 ExtData/PCP
#
#         Then, you must replace the token after PRECIP_FILE with the proper datastream:
#         -----------------------------------------------------------------------------------------------------------
#         Years 1979-2014: d5_merra/Y%y4/M%m2/d5_merra.tavg1_2d_lfo_Nx_corr.%y4%m2%d2_%h230z.nc
#         ---------------
#
# Possible REPLAY PRECIP Files:
# -----------------------------
#PRECIP_FILE: ExtData/PCP/@PRECIP_FILE
#
# Latitudinal Tapering between 42.5 and 62.5 degrees mimics NCEP's approach of using GCM-based precip at high latitudes
# --------------------
#USE_PP_TAPER: 1

##############################################################################################
####    Land Surface Model                                                                ####
##############################################################################################

# Option to Diagnose Precipitation Types for Land Surface
# ------------------------------------------------------------
DIAGNOSE_PRECIP_TYPE: FALSE

# Choice for Land Surface Model
#      1 : Catchment 
#      2 : CatchmentCNCLM40 
#      3 : CatchmentCNCLM45 
# ------------------------------------------------------------
LSM_CHOICE: 1

# Apply increments from LDAS?
#      0 : no  (default)
#      1 : yes 
# ------------------------------------------------------------
#LDAS_INCR: 0

# Name of file containing Surface GridComp resource parameters 
# ------------------------------------------------------------
# SURFRC: GEOS_SurfaceGridComp.rc


# ****************************************************************
# ******* REQUIRES MAJOR CLEAN-UP ACROSS SEVERAL GRIDCOMPs *******
# ******* (retained to facilitate this cleanup in future)  *******
# ******* IMPORTANT: This is merely for future reference   *******
# *******   The model reads USE_CNNEE from CO2_GridComp.rc *******
# *******   not from this file.                            *******
# Atmosphere-Land CO2 coupling
# ----------------------------	
# USE_CNNEE: 0 #  options : 0 (default); 1 (Chem uses NNEE from CatchmentCN, NOTE you must add USE_CNNEE: 1 to CO2_GridComp.rc and AMIP/CO2_GridComp.rc,	
#                           in GOCART/ESMF/GOCART_GridComp/CO2_GridComp/ before you build the model.)
#
# ****************************************************************

##############################################################################################
##############################################################################################

# IAU and In-Line BIAS Correction Parameters
# ----------------------------------------------------------------------------------
# AGCM_IMPORT   = IAU  Analysis   Increment
# AGCM_INTERNAL = BIAS Correction Increment: BIAS(n+1) = ALPHA*IAU(n) + BETA*BIAS(n)
# ----------------------------------------------------------------------------------

#AGCM_IMPORT_RESTART_FILE:               agcm_import_rst

#AGCM_INTERNAL_RESTART_FILE:             agcm_internal_rst
#AGCM_INTERNAL_CHECKPOINT_FILE:          agcm_internal_checkpoint
#AGCM_INTERNAL_CHECKPOINT_TYPE:          default

#AGCM_ALPHA: 0.000
#AGCM_BETA:  1.000

MAPL_ENABLE_BOOTSTRAP: YES

# Required AGCM Model Restart Files
# ---------------------------------
DYN_INTERNAL_RESTART_FILE:              fvcore_internal_rst
DYN_INTERNAL_CHECKPOINT_FILE:           fvcore_internal_checkpoint
DYN_INTERNAL_CHECKPOINT_TYPE:           default
DYN_INTERNAL_HEADER:                    1

LAKE_INTERNAL_RESTART_FILE:             lake_internal_rst
LAKE_INTERNAL_CHECKPOINT_FILE:          lake_internal_checkpoint
LAKE_INTERNAL_CHECKPOINT_TYPE:          default

LANDICE_INTERNAL_RESTART_FILE:          landice_internal_rst
LANDICE_INTERNAL_CHECKPOINT_FILE:       landice_internal_checkpoint
LANDICE_INTERNAL_CHECKPOINT_TYPE:       default

CATCH_INTERNAL_RESTART_FILE:            catch_internal_rst
CATCH_INTERNAL_CHECKPOINT_FILE:         catch_internal_checkpoint
CATCH_INTERNAL_CHECKPOINT_TYPE:         default

CATCHCNCLM40_INTERNAL_RESTART_FILE:     catchcn_internal_rst
CATCHCNCLM40_INTERNAL_CHECKPOINT_FILE:  catchcn_internal_checkpoint
CATCHCNCLM40_INTERNAL_CHECKPOINT_TYPE:  default

CATCHCNCLM45_INTERNAL_RESTART_FILE:     catchcn_internal_rst
CATCHCNCLM45_INTERNAL_CHECKPOINT_FILE:  catchcn_internal_checkpoint
CATCHCNCLM45_INTERNAL_CHECKPOINT_TYPE:  default

MOIST_INTERNAL_RESTART_FILE:            moist_internal_rst
MOIST_INTERNAL_CHECKPOINT_FILE:         moist_internal_checkpoint
MOIST_INTERNAL_CHECKPOINT_TYPE:         default


# Boot-Strapable AGCM Model Restart Files
# ---------------------------------------
AIAU_IMPORT_RESTART_FILE:               aiau_import_rst
AIAU_IMPORT_CHECKPOINT_FILE:            aiau_import_checkpoint
AIAU_IMPORT_CHECKPOINT_TYPE:            default

GWD_IMPORT_RESTART_FILE:                gwd_import_rst
GWD_IMPORT_CHECKPOINT_FILE:             gwd_import_checkpoint
GWD_IMPORT_CHECKPOINT_TYPE:             default

MOIST_IMPORT_RESTART_FILE:              moist_import_rst
MOIST_IMPORT_CHECKPOINT_FILE:           moist_import_checkpoint
MOIST_IMPORT_CHECKPOINT_TYPE:           default

SURFACE_IMPORT_RESTART_FILE:            surf_import_rst
SURFACE_IMPORT_CHECKPOINT_FILE:         surf_import_checkpoint
SURFACE_IMPORT_CHECKPOINT_TYPE:         default

SOLAR_INTERNAL_RESTART_FILE:            solar_internal_rst
SOLAR_INTERNAL_CHECKPOINT_FILE:         solar_internal_checkpoint
SOLAR_INTERNAL_CHECKPOINT_TYPE:         default

IRRAD_INTERNAL_RESTART_FILE:            irrad_internal_rst
IRRAD_INTERNAL_CHECKPOINT_FILE:         irrad_internal_checkpoint
IRRAD_INTERNAL_CHECKPOINT_TYPE:         default

TURBULENCE_INTERNAL_RESTART_FILE:       turb_internal_rst
TURBULENCE_INTERNAL_CHECKPOINT_FILE:    turb_internal_checkpoint
TURBULENCE_INTERNAL_CHECKPOINT_TYPE:    default

TURBULENCE_IMPORT_RESTART_FILE:         turb_import_rst
TURBULENCE_IMPORT_CHECKPOINT_FILE:      turb_import_checkpoint
TURBULENCE_IMPORT_CHECKPOINT_TYPE:      default

PCHEM_INTERNAL_RESTART_FILE:            pchem_internal_rst
PCHEM_INTERNAL_CHECKPOINT_FILE:         pchem_internal_checkpoint
PCHEM_INTERNAL_CHECKPOINT_TYPE:         default

#H2O_INTERNAL_RESTART_FILE:              h2o_internal_rst
#H2O_INTERNAL_CHECKPOINT_FILE:           h2o_internal_checkpoint
#H2O_INTERNAL_CHECKPOINT_TYPE:           default

# Chemistry/AEROSOL Model Restart Files
# -------------------------------------
GOCART_IMPORT_RESTART_FILE:             gocart_import_rst
GOCART_IMPORT_CHECKPOINT_FILE:          gocart_import_checkpoint
GOCART_IMPORT_CHECKPOINT_TYPE:          default

GOCART_INTERNAL_RESTART_FILE:           gocart_internal_rst
GOCART_INTERNAL_CHECKPOINT_FILE:        gocart_internal_checkpoint
GOCART_INTERNAL_CHECKPOINT_TYPE:        default

GOCART.data_INTERNAL_RESTART_FILE:      gocartdata_internal_rst
GOCART.data_INTERNAL_CHECKPOINT_FILE:   gocartdata_internal_checkpoint
GOCART.data_INTERNAL_CHECKPOINT_TYPE:   default

DU_INTERNAL_RESTART_FILE:               du_internal_rst
DU_INTERNAL_CHECKPOINT_FILE:            du_internal_checkpoint
DU_INTERNAL_CHECKPOINT_TYPE:            default

SS_INTERNAL_RESTART_FILE:               ss_internal_rst
SS_INTERNAL_CHECKPOINT_FILE:            ss_internal_checkpoint
SS_INTERNAL_CHECKPOINT_TYPE:            default

CA.oc_INTERNAL_RESTART_FILE:            caoc_internal_rst
CA.oc_INTERNAL_CHECKPOINT_FILE:         caoc_internal_checkpoint
CA.oc_INTERNAL_CHECKPOINT_TYPE:         default

CA.bc_INTERNAL_RESTART_FILE:            cabc_internal_rst
CA.bc_INTERNAL_CHECKPOINT_FILE:         cabc_internal_checkpoint
CA.bc_INTERNAL_CHECKPOINT_TYPE:         default

CA.br_INTERNAL_RESTART_FILE:            cabr_internal_rst
CA.br_INTERNAL_CHECKPOINT_FILE:         cabr_internal_checkpoint
CA.br_INTERNAL_CHECKPOINT_TYPE:         default

NI_INTERNAL_RESTART_FILE:               ni_internal_rst
NI_INTERNAL_CHECKPOINT_FILE:            ni_internal_checkpoint
NI_INTERNAL_CHECKPOINT_TYPE:            default

SU_INTERNAL_RESTART_FILE:               su_internal_rst
SU_INTERNAL_CHECKPOINT_FILE:            su_internal_checkpoint
SU_INTERNAL_CHECKPOINT_TYPE:            default

#CARMA_INTERNAL_RESTART_FILE:            carma_internal_rst
#CARMA_INTERNAL_CHECKPOINT_FILE:         carma_internal_checkpoint
#CARMA_INTERNAL_CHECKPOINT_TYPE:         default

##STRATCHEM_INTERNAL_RESTART_FILE:        stratchem_internal_rst
##STRATCHEM_INTERNAL_CHECKPOINT_FILE:     stratchem_internal_checkpoint
##STRATCHEM_INTERNAL_CHECKPOINT_TYPE:     default

##STRATCHEM_IMPORT_RESTART_FILE:          stratchem_import_rst
##STRATCHEM_IMPORT_CHECKPOINT_FILE:       stratchem_import_checkpoint
##STRATCHEM_IMPORT_CHECKPOINT_TYPE:       default

##GMICHEM_INTERNAL_RESTART_FILE:          gmichem_internal_rst
##GMICHEM_INTERNAL_CHECKPOINT_FILE:       gmichem_internal_checkpoint
##GMICHEM_INTERNAL_CHECKPOINT_TYPE:       default

##GMICHEM_IMPORT_RESTART_FILE:            gmichem_import_rst
##GMICHEM_IMPORT_CHECKPOINT_FILE:         gmichem_import_checkpoint
##GMICHEM_IMPORT_CHECKPOINT_TYPE:         default

#GEOSCHEMCHEM_INTERNAL_RESTART_FILE:          geoschemchem_internal_rst
#GEOSCHEMCHEM_INTERNAL_CHECKPOINT_FILE:       geoschemchem_internal_checkpoint
#GEOSCHEMCHEM_INTERNAL_CHECKPOINT_TYPE:       default

#GEOSCHEMCHEM_IMPORT_RESTART_FILE:            geoschemchem_import_rst
#GEOSCHEMCHEM_IMPORT_CHECKPOINT_FILE:         geoschemchem_import_checkpoint
#GEOSCHEMCHEM_IMPORT_CHECKPOINT_TYPE:         default

#MAM_INTERNAL_RESTART_FILE:              mam_internal_rst
#MAM_INTERNAL_CHECKPOINT_FILE:           mam_internal_checkpoint
#MAM_INTERNAL_CHECKPOINT_TYPE:           default

ACHEM_INTERNAL_RESTART_FILE:            achem_internal_rst
ACHEM_INTERNAL_CHECKPOINT_FILE:         achem_internal_checkpoint
ACHEM_INTERNAL_CHECKPOINT_TYPE:         default

TR_INTERNAL_RESTART_FILE:               tr_internal_rst
TR_INTERNAL_CHECKPOINT_FILE:            tr_internal_checkpoint
TR_INTERNAL_CHECKPOINT_TYPE:            default

TR_IMPORT_RESTART_FILE:                 tr_import_rst
TR_IMPORT_CHECKPOINT_FILE:              tr_import_checkpoint
TR_IMPORT_CHECKPOINT_TYPE:              default

HEMCO_INTERNAL_RESTART_FILE:            hemco_internal_rst
HEMCO_INTERNAL_CHECKPOINT_FILE:         hemco_internal_checkpoint
HEMCO_INTERNAL_CHECKPOINT_TYPE:         default

HEMCO_IMPORT_RESTART_FILE:              hemco_import_rst
HEMCO_IMPORT_CHECKPOINT_FILE:           hemco_import_checkpoint
HEMCO_IMPORT_CHECKPOINT_TYPE:           default

#OH_INTERNAL_RESTART_FILE:               oh_internal_rst
#OH_INTERNAL_CHECKPOINT_FILE:            oh_internal_checkpoint
#OH_INTERNAL_CHECKPOINT_TYPE:            default

#OH_IMPORT_RESTART_FILE:                 oh_import_rst
#OH_IMPORT_CHECKPOINT_FILE:              oh_import_checkpoint
#OH_IMPORT_CHECKPOINT_TYPE:              default

# OCEAN Model Restart Files
# -------------------------
SALTWATER_IMPORT_RESTART_FILE:          saltwater_import_rst
SALTWATER_IMPORT_CHECKPOINT_FILE:       saltwater_import_checkpoint
SALTWATER_IMPORT_CHECKPOINT_TYPE:       default

OPENWATER_INTERNAL_RESTART_FILE:        openwater_internal_rst
OPENWATER_INTERNAL_CHECKPOINT_FILE:     openwater_internal_checkpoint
OPENWATER_INTERNAL_CHECKPOINT_TYPE:     default

SEAICETHERMO_INTERNAL_RESTART_FILE:     seaicethermo_internal_rst
SEAICETHERMO_INTERNAL_CHECKPOINT_FILE:  seaicethermo_internal_checkpoint
SEAICETHERMO_INTERNAL_CHECKPOINT_TYPE:  default

CICE4_IMPORT_RESTART_FILE:             seaice_import_rst
CICE4_IMPORT_CHECKPOINT_FILE:          seaice_import_checkpoint
CICE4_IMPORT_CHECKPOINT_TYPE:          default

CICE4_INTERNAL_RESTART_FILE:           seaice_internal_rst
CICE4_INTERNAL_CHECKPOINT_FILE:        seaice_internal_checkpoint
CICE4_INTERNAL_CHECKPOINT_TYPE:        default

OCEAN_INTERNAL_RESTART_FILE:               ocean_internal_rst
OCEAN_INTERNAL_CHECKPOINT_FILE:            ocean_internal_checkpoint
OCEAN_INTERNAL_CHECKPOINT_TYPE:            default

# Boundary Datasets
# -----------------
TOPO_MEAN_FILE:     topo_dynave.data
TOPO_GWDVAR_FILE:   topo_gwdvar.data
TOPO_TRBVAR_FILE:   topo_trbvar.data

LAI_FILE:                   lai.data
GREEN_FILE:               green.data
NDVI_FILE:                 ndvi.data
TILING_FILE:                tile.bin 
VISDF_FILE:                visdf.dat
NIRDF_FILE:                nirdf.dat
LNFM_FILE:                 lnfm.data
 ROUTING_FILE:             runoff.bin

VEGDYN_INTERNAL_RESTART_FILE:  vegdyn.data

KPAR_FILE: SEAWIFS_KPAR_mon_clim.data


# AeroChem Environment
# --------------------
     OX_RELAXTIME: 259200.    # Standard Options:  GCM: 259200., DAS: 0.000
    CH4_RELAXTIME: 259200.
    N2O_RELAXTIME: 259200.
  CFC11_RELAXTIME: 259200.
  CFC12_RELAXTIME: 259200.
 HCFC22_RELAXTIME: 259200.
    H2O_RELAXTIME: 259200.
    OX_FRIENDLIES: ANALYSIS:DYNAMICS:TURBULENCE:MOIST
   CH4_FRIENDLIES: DYNAMICS:TURBULENCE:MOIST
   N2O_FRIENDLIES: DYNAMICS:TURBULENCE:MOIST
 CFC11_FRIENDLIES: DYNAMICS:TURBULENCE:MOIST
 CFC12_FRIENDLIES: DYNAMICS:TURBULENCE:MOIST
   H2O_FRIENDLIES: DYNAMICS:TURBULENCE:MOIST
HCFC22_FRIENDLIES: DYNAMICS:TURBULENCE:MOIST
       pchem_clim: species.data
       pchem_clim_years: 39

# Age-of-Air Parameters
# ---------------------
#AOA_FRIENDLIES: DYNAMICS:TURBULENCE:MOIST

# Set RADIATION Parameterizations
# -------------------------------
USE_RRTMG_IRRAD: 1.0

USE_RRTMG_SORAD: 1.0
ISOLVAR: 2
USE_NRLSSI2: .TRUE.
SOLAR_CYCLE_FILE_NAME: ExtData/g5gcm/solar/NRLSSI2.v2020.txt

NUM_BANDS: 30

#USE_RRTMGP_IRRAD: 1.0
#USE_RRTMGP_SORAD: 1.0
#RRTMGP_DATA_LW: /discover/nobackup/pnorris/RRTMGP-data.v1.5/rrtmgp/data/rrtmgp-data-lw-g128-210809.nc
#RRTMGP_DATA_SW: /discover/nobackup/pnorris/RRTMGP-data.v1.5/rrtmgp/data/rrtmgp-data-sw-g112-210809.nc
#RRTMGP_CLOUD_OPTICS_COEFFS_LW: /discover/nobackup/pnorris/RRTMGP-data.v1.5/extensions/cloud_optics/rrtmgp-cloud-optics-coeffs-lw.nc
#RRTMGP_CLOUD_OPTICS_COEFFS_SW: /discover/nobackup/pnorris/RRTMGP-data.v1.5/extensions/cloud_optics/rrtmgp-cloud-optics-coeffs-sw.nc

DIURNAL_BIOMASS_BURNING: yes

       RATS_PROVIDER: PCHEM   # options: PCHEM, GMICHEM, STRATCHEM (Radiatively active tracers)
       AERO_PROVIDER: GOCART2G   # options: GOCART2G, MAM, none  (Radiatively active aerosols)
ANALYSIS_OX_PROVIDER: PCHEM   # options: PCHEM, GMICHEM, STRATCHEM, GOCART


# Flag for real-time forecasts (persisted SST) IS_FCST: 1 (AMIP-Style Default: 0)
# -------------------------------------------------------------------------------
    IS_FCST: 0


# Time step for aerosol assimilation (GAAS)
# -----------------------------------------
  GAAS_DT: 10800 # 3-hourly

# DATAOCEAN Parameters for AMIP-Style Run
# ----------------------------------------

# To compute skin SST over water (or to use SST Analysis Increment) set values to 1
# ---------------------------------------------------------------------------------
USE_SKIN_LAYER: 0
    ANALYZE_TS: 0

# Model Tuning Parameters (For CMIP5 recommended SOLAR_CONSTANT and CO2 values, use -1)
# -------------------------------------------------------------------------------------
SOLAR_CONSTANT: -1
CO2:            -1


# Flags for SATSIM Output
# -----------------------
USE_SATSIM:       0
USE_SATSIM_ISCCP: 1
USE_SATSIM_MODIS: 0
USE_SATSIM_RADAR: 0
USE_SATSIM_LIDAR: 0
USE_SATSIM_MISR:  0

 INTERPOLATE_ATMLM: 0
 INTERPOLATE_ATMTAU: 1
 INTERPOLATE_OCEAN_ICE_CURRENTS: 0

 # Section for ocean
 # ----------------
 USE_DATASEA:0
 OCEAN_NAME: MOM6
 USE_DATASEAICE:0
 steady_state_ocean: 0
 OCEAN_PICE_SCALING: 0.0

# For running MOM5 coupled model in dual ocean mode, uncomment three lines below, 
# make sure that regular replay is enabled, proper PRECIP_FILE is chosen,
# sst.data and fraci.data are pointing to read forcing files on tripolar grid,
# the run starts at 21z/03z/09z/15z, 
# HISTORY.rc collections have proper ref_time field
# ---------------------------------------------------------------------------

 
 # Section for CICE 
 # -----------------
 USE_CICE_Thermo: 1
 PRESCRIBED_ICE: 0
 CICE_DT: 450
 CICE_NDTE: 300
 CICE_GRID: grid_cice.bin
 CICE_KMT: kmt_cice.bin
 CICE_N_ICE_CATEGORIES:5
 CICE_N_ICE_LAYERS:4
 CICE_MU_RDG: 3.0
 CICE_AH_MAX: 0.3
 CICE_STRENGTH: 0
 ALBICEV: 0.78
 ALBICEI: 0.36
 ALBSNOWV: 0.98
 ALBSNOWI: 0.7 
 MIN_FREEZE_SALINITY: 5.0