(PID.TID 0000.0001) 
(PID.TID 0000.0001) // ======================================================
(PID.TID 0000.0001) //                      MITgcm UV
(PID.TID 0000.0001) //                      =========
(PID.TID 0000.0001) // ======================================================
(PID.TID 0000.0001) // execution environment starting up...
(PID.TID 0000.0001) 
(PID.TID 0000.0001) // MITgcmUV version:  checkpoint67c
(PID.TID 0000.0001) // Build user:        mlosch
(PID.TID 0000.0001) // Build host:        baudelaire
(PID.TID 0000.0001) // Build date:        Fri Aug 24 08:27:30 EDT 2018
(PID.TID 0000.0001) 
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // Execution Environment parameter file "eedata"
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) ># Example "eedata" file
(PID.TID 0000.0001) ># Lines beginning "#" are comments
(PID.TID 0000.0001) ># nTx - No. threads per process in X
(PID.TID 0000.0001) ># nTy - No. threads per process in Y
(PID.TID 0000.0001) > &EEPARMS
(PID.TID 0000.0001) > nTx=1,
(PID.TID 0000.0001) > nTy=1,
(PID.TID 0000.0001) > /
(PID.TID 0000.0001) ># Note: Some systems use & as the namelist terminator (as shown here).
(PID.TID 0000.0001) >#       Other systems use a / character.
(PID.TID 0000.0001) 
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // Computational Grid Specification ( see files "SIZE.h" )
(PID.TID 0000.0001) //                                  ( and "eedata"       )
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001)      nPx =    1 ; /* No. processes in X */
(PID.TID 0000.0001)      nPy =    1 ; /* No. processes in Y */
(PID.TID 0000.0001)      nSx =    2 ; /* No. tiles in X per process */
(PID.TID 0000.0001)      nSy =    2 ; /* No. tiles in Y per process */
(PID.TID 0000.0001)      sNx =   40 ; /* Tile size in X */
(PID.TID 0000.0001)      sNy =   21 ; /* Tile size in Y */
(PID.TID 0000.0001)      OLx =    3 ; /* Tile overlap distance in X */
(PID.TID 0000.0001)      OLy =    3 ; /* Tile overlap distance in Y */
(PID.TID 0000.0001)      nTx =    1 ; /* No. threads in X per process */
(PID.TID 0000.0001)      nTy =    1 ; /* No. threads in Y per process */
(PID.TID 0000.0001)       Nr =    1 ; /* No. levels in the vertical   */
(PID.TID 0000.0001)       Nx =   80 ; /* Total domain size in X ( = nPx*nSx*sNx ) */
(PID.TID 0000.0001)       Ny =   42 ; /* Total domain size in Y ( = nPy*nSy*sNy ) */
(PID.TID 0000.0001)   nTiles =    4 ; /* Total no. tiles per process ( = nSx*nSy ) */
(PID.TID 0000.0001)   nProcs =    1 ; /* Total no. processes ( = nPx*nPy ) */
(PID.TID 0000.0001) nThreads =    1 ; /* Total no. threads per process ( = nTx*nTy ) */
(PID.TID 0000.0001) usingMPI =    F ; /* Flag used to control whether MPI is in use */
(PID.TID 0000.0001)                   /*  note: To execute a program with MPI calls */
(PID.TID 0000.0001)                   /*  it must be launched appropriately e.g     */
(PID.TID 0000.0001)                   /*  "mpirun -np 64 ......"                    */
(PID.TID 0000.0001) useCoupler=    F ;/* Flag used to control communications with   */
(PID.TID 0000.0001)                   /*  other model components, through a coupler */
(PID.TID 0000.0001) debugMode =    F ; /* print debug msg. (sequence of S/R calls)  */
(PID.TID 0000.0001) printMapIncludesZeros=    F ; /* print zeros in Std.Output maps */
(PID.TID 0000.0001) maxLengthPrt1D=   65 /* maxLength of 1D array printed to StdOut */
(PID.TID 0000.0001) 
(PID.TID 0000.0001) // ======================================================
(PID.TID 0000.0001) // Mapping of tiles to threads
(PID.TID 0000.0001) // ======================================================
(PID.TID 0000.0001) // -o- Thread   1, tiles (   1:   2,   1:   2)
(PID.TID 0000.0001) 
(PID.TID 0000.0001) // ======================================================
(PID.TID 0000.0001) // Tile <-> Tile connectvity table
(PID.TID 0000.0001) // ======================================================
(PID.TID 0000.0001) // Tile number: 000001 (process no. = 000000)
(PID.TID 0000.0001) //        WEST: Tile = 000002, Process = 000000, Comm = put
(PID.TID 0000.0001) //                bi = 000002, bj = 000001
(PID.TID 0000.0001) //        EAST: Tile = 000002, Process = 000000, Comm = put
(PID.TID 0000.0001) //                bi = 000002, bj = 000001
(PID.TID 0000.0001) //       SOUTH: Tile = 000003, Process = 000000, Comm = put
(PID.TID 0000.0001) //                bi = 000001, bj = 000002
(PID.TID 0000.0001) //       NORTH: Tile = 000003, Process = 000000, Comm = put
(PID.TID 0000.0001) //                bi = 000001, bj = 000002
(PID.TID 0000.0001) // Tile number: 000002 (process no. = 000000)
(PID.TID 0000.0001) //        WEST: Tile = 000001, Process = 000000, Comm = put
(PID.TID 0000.0001) //                bi = 000001, bj = 000001
(PID.TID 0000.0001) //        EAST: Tile = 000001, Process = 000000, Comm = put
(PID.TID 0000.0001) //                bi = 000001, bj = 000001
(PID.TID 0000.0001) //       SOUTH: Tile = 000004, Process = 000000, Comm = put
(PID.TID 0000.0001) //                bi = 000002, bj = 000002
(PID.TID 0000.0001) //       NORTH: Tile = 000004, Process = 000000, Comm = put
(PID.TID 0000.0001) //                bi = 000002, bj = 000002
(PID.TID 0000.0001) // Tile number: 000003 (process no. = 000000)
(PID.TID 0000.0001) //        WEST: Tile = 000004, Process = 000000, Comm = put
(PID.TID 0000.0001) //                bi = 000002, bj = 000002
(PID.TID 0000.0001) //        EAST: Tile = 000004, Process = 000000, Comm = put
(PID.TID 0000.0001) //                bi = 000002, bj = 000002
(PID.TID 0000.0001) //       SOUTH: Tile = 000001, Process = 000000, Comm = put
(PID.TID 0000.0001) //                bi = 000001, bj = 000001
(PID.TID 0000.0001) //       NORTH: Tile = 000001, Process = 000000, Comm = put
(PID.TID 0000.0001) //                bi = 000001, bj = 000001
(PID.TID 0000.0001) // Tile number: 000004 (process no. = 000000)
(PID.TID 0000.0001) //        WEST: Tile = 000003, Process = 000000, Comm = put
(PID.TID 0000.0001) //                bi = 000001, bj = 000002
(PID.TID 0000.0001) //        EAST: Tile = 000003, Process = 000000, Comm = put
(PID.TID 0000.0001) //                bi = 000001, bj = 000002
(PID.TID 0000.0001) //       SOUTH: Tile = 000002, Process = 000000, Comm = put
(PID.TID 0000.0001) //                bi = 000002, bj = 000001
(PID.TID 0000.0001) //       NORTH: Tile = 000002, Process = 000000, Comm = put
(PID.TID 0000.0001) //                bi = 000002, bj = 000001
(PID.TID 0000.0001) 
(PID.TID 0000.0001)  INI_PARMS: opening model parameter file "data"
(PID.TID 0000.0001)  OPEN_COPY_DATA_FILE: opening file data
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // Parameter file "data"
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) ># ====================
(PID.TID 0000.0001) ># | Model parameters |
(PID.TID 0000.0001) ># ====================
(PID.TID 0000.0001) >#
(PID.TID 0000.0001) > &PARM01
(PID.TID 0000.0001) > tRef= -1.62,
(PID.TID 0000.0001) > sRef= 30.,
(PID.TID 0000.0001) > no_slip_sides=.FALSE.,
(PID.TID 0000.0001) > no_slip_bottom=.TRUE.,
(PID.TID 0000.0001) >#bottomDragLinear=1.E-3,
(PID.TID 0000.0001) > bottomDragQuadratic=5.E-3,
(PID.TID 0000.0001) > viscAr=3.E-2,
(PID.TID 0000.0001) > viscAh=3.E+2,
(PID.TID 0000.0001) > HeatCapacity_Cp = 3986.,
(PID.TID 0000.0001) > rhoNil          = 1030.,
(PID.TID 0000.0001) > rhoConstFresh   = 1000.,
(PID.TID 0000.0001) > eosType='LINEAR',
(PID.TID 0000.0001) > tAlpha=2.E-4,
(PID.TID 0000.0001) > sBeta= 0.,
(PID.TID 0000.0001) > staggerTimeStep=.TRUE.,
(PID.TID 0000.0001) > saltStepping=.FALSE.,
(PID.TID 0000.0001) > tempStepping=.FALSE.,
(PID.TID 0000.0001) >#tempAdvection=.FALSE.,
(PID.TID 0000.0001) > momStepping=.FALSE.,
(PID.TID 0000.0001) > f0=0.e-4,
(PID.TID 0000.0001) > beta=0.,
(PID.TID 0000.0001) > useJamartWetPoints=.TRUE.,
(PID.TID 0000.0001) > rigidLid=.FALSE.,
(PID.TID 0000.0001) > implicitFreeSurface=.TRUE.,
(PID.TID 0000.0001) >#exactConserv=.TRUE.,
(PID.TID 0000.0001) > convertFW2Salt=-1,
(PID.TID 0000.0001) > readBinaryPrec=64,
(PID.TID 0000.0001) > writeBinaryPrec=64,
(PID.TID 0000.0001) >#globalFiles=.TRUE.,
(PID.TID 0000.0001) > useSingleCpuIO=.TRUE.,
(PID.TID 0000.0001) >#debugLevel=4,
(PID.TID 0000.0001) > /
(PID.TID 0000.0001) >
(PID.TID 0000.0001) ># Elliptic solver parameters
(PID.TID 0000.0001) > &PARM02
(PID.TID 0000.0001) > cg2dMaxIters=500,
(PID.TID 0000.0001) > cg2dTargetResidual=1.E-12,
(PID.TID 0000.0001) > /
(PID.TID 0000.0001) >
(PID.TID 0000.0001) ># Time stepping parameters
(PID.TID 0000.0001) > &PARM03
(PID.TID 0000.0001) > startTime=0.0,
(PID.TID 0000.0001) >#endTime=432000.,
(PID.TID 0000.0001) > deltaT=1800.0,
(PID.TID 0000.0001) > abEps=0.1,
(PID.TID 0000.0001) > forcing_In_AB = .FALSE.,
(PID.TID 0000.0001) > pChkptFreq=3600000.,
(PID.TID 0000.0001) > dumpFreq  = 432000.,
(PID.TID 0000.0001) > monitorFreq=864000.,
(PID.TID 0000.0001) > monitorSelect=2,
(PID.TID 0000.0001) > nTimeSteps=12,
(PID.TID 0000.0001) > /
(PID.TID 0000.0001) >
(PID.TID 0000.0001) ># Gridding parameters
(PID.TID 0000.0001) > &PARM04
(PID.TID 0000.0001) > usingCartesianGrid=.TRUE.,
(PID.TID 0000.0001) > delX=80*5.E3,
(PID.TID 0000.0001) > delY=42*5.E3,
(PID.TID 0000.0001) > ygOrigin=-110.E3,
(PID.TID 0000.0001) >#delR= 20., 30., 50.,
(PID.TID 0000.0001) > delR= 10.,
(PID.TID 0000.0001) > /
(PID.TID 0000.0001) >
(PID.TID 0000.0001) ># Input datasets
(PID.TID 0000.0001) > &PARM05
(PID.TID 0000.0001) > bathyFile       = 'bathy_3c.bin',
(PID.TID 0000.0001) > uVelInitFile    = 'uVel_3c0.bin',
(PID.TID 0000.0001) > vVelInitFile    = 'vVel_3c0.bin',
(PID.TID 0000.0001) > pSurfInitFile   = 'eta_3c0.bin',
(PID.TID 0000.0001) >#uVelInitFile    = 'uVel_3c1.bin',
(PID.TID 0000.0001) >#vVelInitFile    = 'vVel_3c1.bin',
(PID.TID 0000.0001) >#pSurfInitFile   = 'eta_3c1.bin',
(PID.TID 0000.0001) >#bathyFile       = 'channel.bin',
(PID.TID 0000.0001) >#uVelInitFile    = 'const+40.bin',
(PID.TID 0000.0001) >#vVelInitFile    = 'const-10.bin',
(PID.TID 0000.0001) > /
(PID.TID 0000.0001) 
(PID.TID 0000.0001)  INI_PARMS ; starts to read PARM01
(PID.TID 0000.0001)  INI_PARMS ; read PARM01 : OK
(PID.TID 0000.0001)  INI_PARMS ; starts to read PARM02
(PID.TID 0000.0001)  INI_PARMS ; read PARM02 : OK
(PID.TID 0000.0001)  INI_PARMS ; starts to read PARM03
(PID.TID 0000.0001)  INI_PARMS ; read PARM03 : OK
(PID.TID 0000.0001)  INI_PARMS ; starts to read PARM04
(PID.TID 0000.0001)  INI_PARMS ; read PARM04 : OK
(PID.TID 0000.0001)  INI_PARMS ; starts to read PARM05
(PID.TID 0000.0001)  INI_PARMS ; read PARM05 : OK
(PID.TID 0000.0001)  INI_PARMS: finished reading file "data"
(PID.TID 0000.0001)  PACKAGES_BOOT: opening data.pkg
(PID.TID 0000.0001)  OPEN_COPY_DATA_FILE: opening file data.pkg
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // Parameter file "data.pkg"
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) ># Packages
(PID.TID 0000.0001) > &PACKAGES
(PID.TID 0000.0001) >  useEXF    = .TRUE.,
(PID.TID 0000.0001) >  useSEAICE = .TRUE.,
(PID.TID 0000.0001) >  useThSIce = .TRUE.,
(PID.TID 0000.0001) >  useDiagnostics=.TRUE.,
(PID.TID 0000.0001) > /
(PID.TID 0000.0001) 
(PID.TID 0000.0001)  PACKAGES_BOOT: finished reading data.pkg
(PID.TID 0000.0001)  PACKAGES_BOOT: On/Off package Summary
 --------  pkgs with a standard "usePKG" On/Off switch in "data.pkg":  --------
 pkg/exf                  compiled   and   used ( useEXF                   = T )
 pkg/seaice               compiled   and   used ( useSEAICE                = T )
 pkg/thsice               compiled   and   used ( useThSIce                = T )
 pkg/diagnostics          compiled   and   used ( useDiagnostics           = T )
 -------- pkgs without standard "usePKG" On/Off switch in "data.pkg":  --------
 pkg/generic_advdiff      compiled but not used ( useGAD                   = F )
 pkg/mom_common           compiled but not used ( momStepping              = F )
 pkg/mom_vecinv           compiled but not used ( +vectorInvariantMomentum = F )
 pkg/mom_fluxform         compiled but not used ( & not vectorInvariantMom = F )
 pkg/monitor              compiled   and   used ( monitorFreq > 0.         = T )
 pkg/debug                compiled but not used ( debugMode                = F )
 pkg/rw                   compiled   and   used
 pkg/mdsio                compiled   and   used
(PID.TID 0000.0001)  PACKAGES_BOOT: End of package Summary
(PID.TID 0000.0001) 
(PID.TID 0000.0001) EXF_READPARMS: opening data.exf
(PID.TID 0000.0001)  OPEN_COPY_DATA_FILE: opening file data.exf
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // Parameter file "data.exf"
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) >#
(PID.TID 0000.0001) ># *********************
(PID.TID 0000.0001) ># External Forcing Data
(PID.TID 0000.0001) ># *********************
(PID.TID 0000.0001) > &EXF_NML_01
(PID.TID 0000.0001) >#
(PID.TID 0000.0001) > useExfCheckRange  = .TRUE.,
(PID.TID 0000.0001) >#repeatPeriod      = 2635200.0,
(PID.TID 0000.0001) > exf_iprec         = 64,
(PID.TID 0000.0001) > exf_monFreq       = 86400000.,
(PID.TID 0000.0001) >#useRelativeWind = .TRUE.,
(PID.TID 0000.0001) >#
(PID.TID 0000.0001) > /
(PID.TID 0000.0001) >
(PID.TID 0000.0001) ># *********************
(PID.TID 0000.0001) > &EXF_NML_02
(PID.TID 0000.0001) >#
(PID.TID 0000.0001) > atempperiod       = 0.0,
(PID.TID 0000.0001) > aqhperiod         = 0.0,
(PID.TID 0000.0001) >#
(PID.TID 0000.0001) > uwindperiod       = 0.0,
(PID.TID 0000.0001) > vwindperiod       = 0.0,
(PID.TID 0000.0001) >#
(PID.TID 0000.0001) > precipperiod      = 0.0,
(PID.TID 0000.0001) > swdownperiod      = 0.0,
(PID.TID 0000.0001) > lwdownperiod      = 0.0,
(PID.TID 0000.0001) >#
(PID.TID 0000.0001) > climsstperiod      = 0.0,
(PID.TID 0000.0001) >#climsstTauRelax    = 2592000.,
(PID.TID 0000.0001) > climsssperiod      = 0.0,
(PID.TID 0000.0001) >#climsssTauRelax    = 2592000.,
(PID.TID 0000.0001) >#
(PID.TID 0000.0001) >#atempfile         = 'tair_4x.bin',
(PID.TID 0000.0001) >#aqhfile           = 'qa70_4x.bin',
(PID.TID 0000.0001) > uwindfile         = 'windx.bin',
(PID.TID 0000.0001) >#vwindfile         = 'windy.bin',
(PID.TID 0000.0001) >#precipfile        = 'const_00.bin',
(PID.TID 0000.0001) >#lwdownfile        = 'dlw_250.bin',
(PID.TID 0000.0001) >#swdownfile        = 'dsw_100.bin',
(PID.TID 0000.0001) >#runoffFile        = ' '
(PID.TID 0000.0001) >#climsstfile       = 'tocn.bin',
(PID.TID 0000.0001) >#climsssfile       = 'socn.bin',
(PID.TID 0000.0001) > /
(PID.TID 0000.0001) >
(PID.TID 0000.0001) ># *********************
(PID.TID 0000.0001) > &EXF_NML_03
(PID.TID 0000.0001) >#exf_offset_atemp=5;
(PID.TID 0000.0001) > /
(PID.TID 0000.0001) >
(PID.TID 0000.0001) ># *********************
(PID.TID 0000.0001) ># old open64 compiler (4.2.1) cannot skip this namelist to read in the next one;
(PID.TID 0000.0001) ># comment out this namelist (not read).
(PID.TID 0000.0001) >#&EXF_NML_04
(PID.TID 0000.0001) >#&
(PID.TID 0000.0001) >
(PID.TID 0000.0001) ># *********************
(PID.TID 0000.0001) > &EXF_NML_OBCS
(PID.TID 0000.0001) > /
(PID.TID 0000.0001) 
(PID.TID 0000.0001) EXF_READPARMS: reading EXF_NML_01
(PID.TID 0000.0001) EXF_READPARMS: reading EXF_NML_02
(PID.TID 0000.0001) EXF_READPARMS: reading EXF_NML_03
(PID.TID 0000.0001) EXF_READPARMS: finished reading data.exf
(PID.TID 0000.0001) 
(PID.TID 0000.0001)  SEAICE_READPARMS: opening data.seaice
(PID.TID 0000.0001)  OPEN_COPY_DATA_FILE: opening file data.seaice
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // Parameter file "data.seaice"
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) ># SEAICE parameters
(PID.TID 0000.0001) > &SEAICE_PARM01
(PID.TID 0000.0001) > usePW79thermodynamics=.FALSE.,
(PID.TID 0000.0001) > SEAICE_strength    = 2.6780e+04,
(PID.TID 0000.0001) ># JFNK-convergence is better with this old default value (2 times the new
(PID.TID 0000.0001) ># default) probably because the ice starts to move earlier
(PID.TID 0000.0001) > SEAICE_drag = 0.002,
(PID.TID 0000.0001) >#
(PID.TID 0000.0001) > OCEAN_drag         = 8.1541e-04,
(PID.TID 0000.0001) > SEAICE_no_Slip     = .FALSE.,
(PID.TID 0000.0001) ># JFNK solver parameters
(PID.TID 0000.0001) > SEAICEetaZmethod    = 3,
(PID.TID 0000.0001) > SEAICEuseJFNK       = .TRUE.,
(PID.TID 0000.0001) > SEAICEpreconLinIter = 10,
(PID.TID 0000.0001) > SEAICEnonLinIterMax = 200,
(PID.TID 0000.0001) > SEAICElinearIterMax = 50,
(PID.TID 0000.0001) > SEAICEnonLinTol     = 1.e-09,
(PID.TID 0000.0001) > SEAICE_JFNK_lsIter  = 0,
(PID.TID 0000.0001) > JFNKres_tFac        = 0.5,
(PID.TID 0000.0001) > SEAICE_JFNKalpha    = 1.5,
(PID.TID 0000.0001) ># end of JFNK solver parameters
(PID.TID 0000.0001) >#- to use seaice-advection from pkg/seaice, uncomment following 4 lines:
(PID.TID 0000.0001) >#SEAICEadvScheme    = 77, # this is the new default
(PID.TID 0000.0001) >#AreaFile  = 'const100.bin',
(PID.TID 0000.0001) >#HeffFile  = 'const+20.bin',
(PID.TID 0000.0001) >#HsnowFile = 'const_00.bin',
(PID.TID 0000.0001) > SEAICEwriteState   = .TRUE.,
(PID.TID 0000.0001) > SEAICE_monFreq = 1800.,
(PID.TID 0000.0001) > /
(PID.TID 0000.0001) >
(PID.TID 0000.0001) > &SEAICE_PARM03
(PID.TID 0000.0001) > /
(PID.TID 0000.0001) 
(PID.TID 0000.0001)  SEAICE_READPARMS: finished reading data.seaice
(PID.TID 0000.0001)  THSICE_READPARMS: opening data.ice
(PID.TID 0000.0001)  OPEN_COPY_DATA_FILE: opening file data.ice
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // Parameter file "data.ice"
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) > &THSICE_CONST
(PID.TID 0000.0001) >#- with fractional ice:
(PID.TID 0000.0001) > iceMaskMin = 0.001,
(PID.TID 0000.0001) > hiMax      = 10.,
(PID.TID 0000.0001) > hsMax      = 10.,
(PID.TID 0000.0001) > dhSnowLin  = 0.1,
(PID.TID 0000.0001) > fracEnFreez= 0.4,
(PID.TID 0000.0001) > hNewIceMax = 1.,
(PID.TID 0000.0001) > albIceMax  = 0.6,
(PID.TID 0000.0001) > albIceMin  = 0.6,
(PID.TID 0000.0001) >#albColdSnow= 0.85,
(PID.TID 0000.0001) >#albWarmSnow= 0.60,
(PID.TID 0000.0001) >#tempSnowAlb= -5.,
(PID.TID 0000.0001) >#albOldSnow = 0.60,
(PID.TID 0000.0001) >#hNewSnowAge= 2.e-3,
(PID.TID 0000.0001) >#snowAgTime = 4320000.,
(PID.TID 0000.0001) >#hAlbIce    = 0.44,
(PID.TID 0000.0001) >#hAlbSnow   = 0.15,
(PID.TID 0000.0001) > /
(PID.TID 0000.0001) >
(PID.TID 0000.0001) > &THSICE_PARM01
(PID.TID 0000.0001) >#StartIceModel=1,
(PID.TID 0000.0001) > thSIce_skipThermo=.TRUE.,
(PID.TID 0000.0001) > thSIceAdvScheme=77,
(PID.TID 0000.0001) >#thSIce_diffK   =800.,
(PID.TID 0000.0001) > stressReduction=0.,
(PID.TID 0000.0001) > thSIceFract_InitFile='const100.bin',
(PID.TID 0000.0001) > thSIceThick_InitFile='const+20.bin',
(PID.TID 0000.0001) >#thSIce_diagFreq=2592000.,
(PID.TID 0000.0001) > thSIce_monFreq =21600.,
(PID.TID 0000.0001) > thSIce_monFreq =1800.,
(PID.TID 0000.0001) > /
(PID.TID 0000.0001) >
(PID.TID 0000.0001) 
(PID.TID 0000.0001)  THSICE_READPARMS: read THSICE_CONST
(PID.TID 0000.0001)  THSICE_READPARMS: read THSICE_PARM01
 ThSI:       rhos        =  3.3000000000000E+02
 ThSI:       rhoi        =  9.0000000000000E+02
 ThSI:       rhosw       =  1.0300000000000E+03
 ThSI:       rhofw       =  1.0000000000000E+03
 ThSI:       floodFac    =  3.9393939393939E-01
 ThSI:       cpIce       =  2.1060000000000E+03
 ThSI:       cpWater     =  3.9860000000000E+03
 ThSI:       kIce        =  2.0300000000000E+00
 ThSI:       kSnow       =  3.0000000000000E-01
 ThSI:       bMeltCoef   =  6.0000000000000E-03
 ThSI:       Lfresh      =  3.3400000000000E+05
 ThSI:       qsnow       =  3.3400000000000E+05
 ThSI:       albColdSnow =  8.5000000000000E-01
 ThSI:       albWarmSnow =  7.0000000000000E-01
 ThSI:       tempSnowAlb = -1.0000000000000E+01
 ThSI:       albOldSnow  =  5.5000000000000E-01
 ThSI:       hNewSnowAge =  2.0000000000000E-03
 ThSI:       snowAgTime  =  4.3200000000000E+06
 ThSI:       albIceMax   =  6.0000000000000E-01
 ThSI:       albIceMin   =  6.0000000000000E-01
 ThSI:       hAlbIce     =  5.0000000000000E-01
 ThSI:       hAlbSnow    =  3.0000000000000E-01
 ThSI:       i0swFrac    =  3.0000000000000E-01
 ThSI:       ksolar      =  1.5000000000000E+00
 ThSI:       dhSnowLin   =  1.0000000000000E-01
 ThSI:       saltIce     =  4.0000000000000E+00
 ThSI:       S_winton    =  1.0000000000000E+00
 ThSI:       mu_Tf       =  5.4000000000000E-02
 ThSI:       Tf0kel      =  2.7315000000000E+02
 ThSI:       Tmlt1       = -5.4000000000000E-02
 ThSI:       Terrmax     =  5.0000000000000E-01
 ThSI:       nitMaxTsf   =        20
 ThSI:       hIceMin     =  1.0000000000000E-02
 ThSI:       hiMax       =  1.0000000000000E+01
 ThSI:       hsMax       =  1.0000000000000E+01
 ThSI:       iceMaskMax  =  1.0000000000000E+00
 ThSI:       iceMaskMin  =  1.0000000000000E-03
 ThSI:       fracEnMelt  =  4.0000000000000E-01
 ThSI:       fracEnFreez =  4.0000000000000E-01
 ThSI:       hThinIce    =  2.0000000000000E-01
 ThSI:       hThickIce   =  2.5000000000000E+00
 ThSI:       hNewIceMax  =  1.0000000000000E+00
 ThSI: stressReduction   =  0.0000000000000E+00
 ThSI: thSIce_skipThermo =         T
 ThSI: thSIceAdvScheme   =        77
 ThSI: thSIceBalanceAtmFW=         0
 ThSI: thSIce_diffK      =  0.0000000000000E+00
 ThSI: thSIce_deltaT     =  1.8000000000000E+03
 ThSI: ocean_deltaT      =  1.8000000000000E+03
 ThSI: stepFwd_oceMxL    =         F
 ThSI: tauRelax_MxL      =  0.0000000000000E+00
 ThSI: tauRelax_MxL_salt =  0.0000000000000E+00
 ThSI: hMxL_default      =  5.0000000000000E+01
 ThSI: sMxL_default      =  3.5000000000000E+01
 ThSI: vMxL_default      =  5.0000000000000E-02
 ThSI: thSIce_taveFreq   =  0.0000000000000E+00
 ThSI: thSIce_diagFreq   =  4.3200000000000E+05
 ThSI: thSIce_monFreq    =  1.8000000000000E+03
 ThSI: startIceModel     =         0
(PID.TID 0000.0001)  DIAGNOSTICS_READPARMS: opening data.diagnostics
(PID.TID 0000.0001)  OPEN_COPY_DATA_FILE: opening file data.diagnostics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // Parameter file "data.diagnostics"
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) ># Diagnostic Package Choices
(PID.TID 0000.0001) >#--------------------
(PID.TID 0000.0001) >#  dumpAtLast (logical): always write output at the end of simulation (default=F)
(PID.TID 0000.0001) >#  diag_mnc   (logical): write to NetCDF files (default=useMNC)
(PID.TID 0000.0001) >#--for each output-stream:
(PID.TID 0000.0001) >#  fileName(n) : prefix of the output file name (max 80c long) for outp.stream n
(PID.TID 0000.0001) >#  frequency(n):< 0 : write snap-shot output every |frequency| seconds
(PID.TID 0000.0001) >#               > 0 : write time-average output every frequency seconds
(PID.TID 0000.0001) >#  timePhase(n)     : write at time = timePhase + multiple of |frequency|
(PID.TID 0000.0001) >#    averagingFreq  : frequency (in s) for periodic averaging interval
(PID.TID 0000.0001) >#    averagingPhase : phase     (in s) for periodic averaging interval
(PID.TID 0000.0001) >#    repeatCycle    : number of averaging intervals in 1 cycle
(PID.TID 0000.0001) >#  levels(:,n) : list of levels to write to file (Notes: declared as REAL)
(PID.TID 0000.0001) >#                when this entry is missing, select all common levels of this list
(PID.TID 0000.0001) >#  fields(:,n) : list of selected diagnostics fields (8.c) in outp.stream n
(PID.TID 0000.0001) >#                (see "available_diagnostics.log" file for the full list of diags)
(PID.TID 0000.0001) >#  missing_value(n) : missing value for real-type fields in output file "n"
(PID.TID 0000.0001) >#  fileFlags(n)     : specific code (8c string) for output file "n"
(PID.TID 0000.0001) >#--------------------
(PID.TID 0000.0001) ># This example dumps EXF diagnostics as snapshot after 10 time-steps
(PID.TID 0000.0001) ># Note: EXF air-sea fluxes over Sea-Ice are wrong
(PID.TID 0000.0001) > &DIAGNOSTICS_LIST
(PID.TID 0000.0001) >   dumpAtLast  = .TRUE.,
(PID.TID 0000.0001) >#--
(PID.TID 0000.0001) >  fields(1:11,1) = 'EXFtaux ','EXFtauy ','EXFqnet ','EXFempmr',
(PID.TID 0000.0001) >                   'EXFhl   ','EXFhs   ','EXFswnet','EXFlwnet',
(PID.TID 0000.0001) >                   'EXFuwind','EXFvwind','EXFatemp',
(PID.TID 0000.0001) >#  fileName(1) = 'exfDiag',
(PID.TID 0000.0001) >  frequency(1) = 86400.,
(PID.TID 0000.0001) >
(PID.TID 0000.0001) >  fields(1:5,2)  = 'SIuice  ','SIvice  ','SIheff  ',
(PID.TID 0000.0001) >                   'SI_Fract','SI_Thick',
(PID.TID 0000.0001) >#  fileName(2) = 'iceDiag',
(PID.TID 0000.0001) >  frequency(2) =  86400.,
(PID.TID 0000.0001) >  missing_value(2) = -999.,
(PID.TID 0000.0001) >
(PID.TID 0000.0001) >  fields(1:5,3)  = 'SIuice  ','SIvice  ','SIheff  ',
(PID.TID 0000.0001) >                   'SI_Fract','SI_Thick',
(PID.TID 0000.0001) >   fileName(3) = 'snapshot',
(PID.TID 0000.0001) >  frequency(3) = -86400.,
(PID.TID 0000.0001) >  timePhase(3) =  3600.,
(PID.TID 0000.0001) >  missing_value(3) = -999.,
(PID.TID 0000.0001) > /
(PID.TID 0000.0001) >
(PID.TID 0000.0001) >#--------------------
(PID.TID 0000.0001) ># Parameter for Diagnostics of per level statistics:
(PID.TID 0000.0001) >#--------------------
(PID.TID 0000.0001) >#  diagSt_mnc (logical): write stat-diags to NetCDF files (default=diag_mnc)
(PID.TID 0000.0001) >#  diagSt_regMaskFile : file containing the region-mask to read-in
(PID.TID 0000.0001) >#  nSetRegMskFile   : number of region-mask sets within the region-mask file
(PID.TID 0000.0001) >#  set_regMask(i)   : region-mask set-index that identifies the region "i"
(PID.TID 0000.0001) >#  val_regMask(i)   : region "i" identifier value in the region mask
(PID.TID 0000.0001) >#--for each output-stream:
(PID.TID 0000.0001) >#  stat_fName(n) : prefix of the output file name (max 80c long) for outp.stream n
(PID.TID 0000.0001) >#  stat_freq(n):< 0 : write snap-shot output every |stat_freq| seconds
(PID.TID 0000.0001) >#               > 0 : write time-average output every stat_freq seconds
(PID.TID 0000.0001) >#  stat_phase(n)    : write at time = stat_phase + multiple of |stat_freq|
(PID.TID 0000.0001) >#  stat_region(:,n) : list of "regions" (default: 1 region only=global)
(PID.TID 0000.0001) >#  stat_fields(:,n) : list of selected diagnostics fields (8.c) in outp.stream n
(PID.TID 0000.0001) >#                (see "available_diagnostics.log" file for the full list of diags)
(PID.TID 0000.0001) >#--------------------
(PID.TID 0000.0001) > &DIAG_STATIS_PARMS
(PID.TID 0000.0001) >#stat_fields(1:5,1)  = 'SI_Fract','SI_Thick','SI_SnowH',
(PID.TID 0000.0001) >#stat_fields(1:5,1)  = 'SIarea  ','SIheff  ','SIhsnow ',
(PID.TID 0000.0001) > stat_fields(1:6,1)  = 'SI_Fract','SI_Thick',
(PID.TID 0000.0001) >                       'SIarea  ','SIheff  ',
(PID.TID 0000.0001) >                       'SIuice  ','SIvice  ',
(PID.TID 0000.0001) >  stat_fName(1) = 'iceStDiag',
(PID.TID 0000.0001) >   stat_freq(1) = 7200.,
(PID.TID 0000.0001) >  stat_phase(1) = 1800.,
(PID.TID 0000.0001) > /
(PID.TID 0000.0001) 
(PID.TID 0000.0001) S/R DIAGNOSTICS_READPARMS, read namelist "diagnostics_list": start
(PID.TID 0000.0001) S/R DIAGNOSTICS_READPARMS, read namelist "diagnostics_list": OK
(PID.TID 0000.0001) S/R DIAGNOSTICS_READPARMS, read namelist "DIAG_STATIS_PARMS": start
(PID.TID 0000.0001) S/R DIAGNOSTICS_READPARMS, read namelist "DIAG_STATIS_PARMS": OK
(PID.TID 0000.0001)  DIAGNOSTICS_READPARMS: global parameter summary:
(PID.TID 0000.0001)  dumpAtLast = /* always write time-ave diags at the end */
(PID.TID 0000.0001)                   T
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001)  diag_mnc =   /* write NetCDF output files */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001)  useMissingValue = /* put MissingValue where mask = 0 */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001)  diagCG_maxIters = /* max number of iters in diag_cg2d */
(PID.TID 0000.0001)                     500
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001)  diagCG_resTarget = /* residual target for diag_cg2d */
(PID.TID 0000.0001)                 1.000000000000000E-12
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001)  diagCG_pcOffDFac = /* preconditioner off-diagonal factor */
(PID.TID 0000.0001)                 9.611687812379854E-01
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) -----------------------------------------------------
(PID.TID 0000.0001)  DIAGNOSTICS_READPARMS: active diagnostics summary:
(PID.TID 0000.0001) -----------------------------------------------------
(PID.TID 0000.0001) Creating Output Stream: snapshot
(PID.TID 0000.0001) Output Frequency:     -86400.000000 ; Phase:        3600.000000
(PID.TID 0000.0001)  Averaging Freq.:          0.000000 , Phase:           0.000000 , Cycle:   1
(PID.TID 0000.0001)  missing value: -9.990000000000E+02
(PID.TID 0000.0001)  Levels:    will be set later
(PID.TID 0000.0001)  Fields:    SIuice   SIvice   SIheff   SI_Fract SI_Thick
(PID.TID 0000.0001) -----------------------------------------------------
(PID.TID 0000.0001)  DIAGNOSTICS_READPARMS: statistics diags. summary:
(PID.TID 0000.0001) Creating Stats. Output Stream: iceStDiag
(PID.TID 0000.0001) Output Frequency:       7200.000000 ; Phase:        1800.000000
(PID.TID 0000.0001)  Regions:   0
(PID.TID 0000.0001)  Fields:    SI_Fract SI_Thick SIarea   SIheff   SIuice   SIvice
(PID.TID 0000.0001) -----------------------------------------------------
(PID.TID 0000.0001) 
(PID.TID 0000.0001) SET_PARMS: done
(PID.TID 0000.0001) Enter INI_VERTICAL_GRID: setInterFDr=    T ; setCenterDr=    F
(PID.TID 0000.0001) %MON XC_max                       =   3.9750000000000E+05
(PID.TID 0000.0001) %MON XC_min                       =   2.5000000000000E+03
(PID.TID 0000.0001) %MON XC_mean                      =   2.0000000000000E+05
(PID.TID 0000.0001) %MON XC_sd                        =   1.1546103238755E+05
(PID.TID 0000.0001) %MON XG_max                       =   3.9500000000000E+05
(PID.TID 0000.0001) %MON XG_min                       =   0.0000000000000E+00
(PID.TID 0000.0001) %MON XG_mean                      =   1.9750000000000E+05
(PID.TID 0000.0001) %MON XG_sd                        =   1.1546103238755E+05
(PID.TID 0000.0001) %MON DXC_max                      =   5.0000000000000E+03
(PID.TID 0000.0001) %MON DXC_min                      =   5.0000000000000E+03
(PID.TID 0000.0001) %MON DXC_mean                     =   5.0000000000000E+03
(PID.TID 0000.0001) %MON DXC_sd                       =   0.0000000000000E+00
(PID.TID 0000.0001) %MON DXF_max                      =   5.0000000000000E+03
(PID.TID 0000.0001) %MON DXF_min                      =   5.0000000000000E+03
(PID.TID 0000.0001) %MON DXF_mean                     =   5.0000000000000E+03
(PID.TID 0000.0001) %MON DXF_sd                       =   0.0000000000000E+00
(PID.TID 0000.0001) %MON DXG_max                      =   5.0000000000000E+03
(PID.TID 0000.0001) %MON DXG_min                      =   5.0000000000000E+03
(PID.TID 0000.0001) %MON DXG_mean                     =   5.0000000000000E+03
(PID.TID 0000.0001) %MON DXG_sd                       =   0.0000000000000E+00
(PID.TID 0000.0001) %MON DXV_max                      =   5.0000000000000E+03
(PID.TID 0000.0001) %MON DXV_min                      =   5.0000000000000E+03
(PID.TID 0000.0001) %MON DXV_mean                     =   5.0000000000000E+03
(PID.TID 0000.0001) %MON DXV_sd                       =   0.0000000000000E+00
(PID.TID 0000.0001) %MON YC_max                       =   9.7500000000000E+04
(PID.TID 0000.0001) %MON YC_min                       =  -1.0750000000000E+05
(PID.TID 0000.0001) %MON YC_mean                      =  -5.0000000000000E+03
(PID.TID 0000.0001) %MON YC_sd                        =   6.0604592785256E+04
(PID.TID 0000.0001) %MON YG_max                       =   9.5000000000000E+04
(PID.TID 0000.0001) %MON YG_min                       =  -1.1000000000000E+05
(PID.TID 0000.0001) %MON YG_mean                      =  -7.5000000000000E+03
(PID.TID 0000.0001) %MON YG_sd                        =   6.0604592785256E+04
(PID.TID 0000.0001) %MON DYC_max                      =   5.0000000000000E+03
(PID.TID 0000.0001) %MON DYC_min                      =   5.0000000000000E+03
(PID.TID 0000.0001) %MON DYC_mean                     =   5.0000000000000E+03
(PID.TID 0000.0001) %MON DYC_sd                       =   0.0000000000000E+00
(PID.TID 0000.0001) %MON DYF_max                      =   5.0000000000000E+03
(PID.TID 0000.0001) %MON DYF_min                      =   5.0000000000000E+03
(PID.TID 0000.0001) %MON DYF_mean                     =   5.0000000000000E+03
(PID.TID 0000.0001) %MON DYF_sd                       =   0.0000000000000E+00
(PID.TID 0000.0001) %MON DYG_max                      =   5.0000000000000E+03
(PID.TID 0000.0001) %MON DYG_min                      =   5.0000000000000E+03
(PID.TID 0000.0001) %MON DYG_mean                     =   5.0000000000000E+03
(PID.TID 0000.0001) %MON DYG_sd                       =   0.0000000000000E+00
(PID.TID 0000.0001) %MON DYU_max                      =   5.0000000000000E+03
(PID.TID 0000.0001) %MON DYU_min                      =   5.0000000000000E+03
(PID.TID 0000.0001) %MON DYU_mean                     =   5.0000000000000E+03
(PID.TID 0000.0001) %MON DYU_sd                       =   0.0000000000000E+00
(PID.TID 0000.0001) %MON RA_max                       =   2.5000000000000E+07
(PID.TID 0000.0001) %MON RA_min                       =   2.5000000000000E+07
(PID.TID 0000.0001) %MON RA_mean                      =   2.5000000000000E+07
(PID.TID 0000.0001) %MON RA_sd                        =   3.7252902984619E-09
(PID.TID 0000.0001) %MON RAW_max                      =   2.5000000000000E+07
(PID.TID 0000.0001) %MON RAW_min                      =   2.5000000000000E+07
(PID.TID 0000.0001) %MON RAW_mean                     =   2.5000000000000E+07
(PID.TID 0000.0001) %MON RAW_sd                       =   3.7252902984619E-09
(PID.TID 0000.0001) %MON RAS_max                      =   2.5000000000000E+07
(PID.TID 0000.0001) %MON RAS_min                      =   2.5000000000000E+07
(PID.TID 0000.0001) %MON RAS_mean                     =   2.5000000000000E+07
(PID.TID 0000.0001) %MON RAS_sd                       =   3.7252902984619E-09
(PID.TID 0000.0001) %MON RAZ_max                      =   2.5000000000000E+07
(PID.TID 0000.0001) %MON RAZ_min                      =   2.5000000000000E+07
(PID.TID 0000.0001) %MON RAZ_mean                     =   2.5000000000000E+07
(PID.TID 0000.0001) %MON RAZ_sd                       =   3.7252902984619E-09
(PID.TID 0000.0001) %MON AngleCS_max                  =   1.0000000000000E+00
(PID.TID 0000.0001) %MON AngleCS_min                  =   1.0000000000000E+00
(PID.TID 0000.0001) %MON AngleCS_mean                 =   1.0000000000000E+00
(PID.TID 0000.0001) %MON AngleCS_sd                   =   0.0000000000000E+00
(PID.TID 0000.0001) %MON AngleSN_max                  =   0.0000000000000E+00
(PID.TID 0000.0001) %MON AngleSN_min                  =   0.0000000000000E+00
(PID.TID 0000.0001) %MON AngleSN_mean                 =   0.0000000000000E+00
(PID.TID 0000.0001) %MON AngleSN_sd                   =   0.0000000000000E+00
(PID.TID 0000.0001)  MDS_READ_FIELD: opening global file: bathy_3c.bin
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // Field Model R_low (ini_masks_etc)
(PID.TID 0000.0001) // CMIN =         -1.000000000000000E+01
(PID.TID 0000.0001) // CMAX =         -1.000000000000000E+01
(PID.TID 0000.0001) // CINT =          0.000000000000000E+00
(PID.TID 0000.0001) // SYMBOLS (CMIN->CMAX): -abcdefghijklmnopqrstuvwxyz+
(PID.TID 0000.0001) //                  0.0: .
(PID.TID 0000.0001) // RANGE I (Lo:Hi:Step):(    -2:    83:     1)
(PID.TID 0000.0001) // RANGE J (Lo:Hi:Step):(    45:    -2:    -1)
(PID.TID 0000.0001) // RANGE K (Lo:Hi:Step):(   1:   1:   1)
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // END OF FIELD                                          =
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) 
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // Field Model Ro_surf (ini_masks_etc)
(PID.TID 0000.0001) // CMIN =          1.000000000000000E+32
(PID.TID 0000.0001) // CMAX =         -1.000000000000000E+32
(PID.TID 0000.0001) // CINT =          0.000000000000000E+00
(PID.TID 0000.0001) // SYMBOLS (CMIN->CMAX): -abcdefghijklmnopqrstuvwxyz+
(PID.TID 0000.0001) //                  0.0: .
(PID.TID 0000.0001) // RANGE I (Lo:Hi:Step):(    -2:    83:     1)
(PID.TID 0000.0001) // RANGE J (Lo:Hi:Step):(    45:    -2:    -1)
(PID.TID 0000.0001) // RANGE K (Lo:Hi:Step):(   1:   1:   1)
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // END OF FIELD                                          =
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) 
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // Field hFacC at iteration          0
(PID.TID 0000.0001) // CMIN =          1.000000000000000E+00
(PID.TID 0000.0001) // CMAX =          1.000000000000000E+00
(PID.TID 0000.0001) // CINT =          0.000000000000000E+00
(PID.TID 0000.0001) // SYMBOLS (CMIN->CMAX): -abcdefghijklmnopqrstuvwxyz+
(PID.TID 0000.0001) //                  0.0: .
(PID.TID 0000.0001) // RANGE I (Lo:Hi:Step):(    -2:    83:     1)
(PID.TID 0000.0001) // RANGE J (Lo:Hi:Step):(    45:    -2:    -1)
(PID.TID 0000.0001) // RANGE K (Lo:Hi:Step):(   1:   1:   1)
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // END OF FIELD                                          =
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) 
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // Field hFacW at iteration          0
(PID.TID 0000.0001) // CMIN =          1.000000000000000E+00
(PID.TID 0000.0001) // CMAX =          1.000000000000000E+00
(PID.TID 0000.0001) // CINT =          0.000000000000000E+00
(PID.TID 0000.0001) // SYMBOLS (CMIN->CMAX): -abcdefghijklmnopqrstuvwxyz+
(PID.TID 0000.0001) //                  0.0: .
(PID.TID 0000.0001) // RANGE I (Lo:Hi:Step):(    -2:    83:     1)
(PID.TID 0000.0001) // RANGE J (Lo:Hi:Step):(    45:    -2:    -1)
(PID.TID 0000.0001) // RANGE K (Lo:Hi:Step):(   1:   1:   1)
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // END OF FIELD                                          =
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) 
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // Field hFacS at iteration          0
(PID.TID 0000.0001) // CMIN =          1.000000000000000E+00
(PID.TID 0000.0001) // CMAX =          1.000000000000000E+00
(PID.TID 0000.0001) // CINT =          0.000000000000000E+00
(PID.TID 0000.0001) // SYMBOLS (CMIN->CMAX): -abcdefghijklmnopqrstuvwxyz+
(PID.TID 0000.0001) //                  0.0: .
(PID.TID 0000.0001) // RANGE I (Lo:Hi:Step):(    -2:    83:     1)
(PID.TID 0000.0001) // RANGE J (Lo:Hi:Step):(    45:    -2:    -1)
(PID.TID 0000.0001) // RANGE K (Lo:Hi:Step):(   1:   1:   1)
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // END OF FIELD                                          =
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) 
(PID.TID 0000.0001) GAD_INIT_FIXED: GAD_OlMinSize=  0  0  1
(PID.TID 0000.0001) 
(PID.TID 0000.0001) // ===================================
(PID.TID 0000.0001) // GAD parameters :
(PID.TID 0000.0001) // ===================================
(PID.TID 0000.0001) tempAdvScheme =   /* Temp. Horiz.Advection scheme selector */
(PID.TID 0000.0001)                       2
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) tempVertAdvScheme =   /* Temp. Vert. Advection scheme selector */
(PID.TID 0000.0001)                       2
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) tempMultiDimAdvec =   /* use Muti-Dim Advec method for Temp */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) tempSOM_Advection = /* use 2nd Order Moment Advection for Temp */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) AdamsBashforthGt = /* apply Adams-Bashforth extrapolation on Gt */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) AdamsBashforth_T = /* apply Adams-Bashforth extrapolation on Temp */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) saltAdvScheme =   /* Salt. Horiz.advection scheme selector */
(PID.TID 0000.0001)                       2
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) saltVertAdvScheme =   /* Salt. Vert. Advection scheme selector */
(PID.TID 0000.0001)                       2
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) saltMultiDimAdvec =   /* use Muti-Dim Advec method for Salt */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) saltSOM_Advection = /* use 2nd Order Moment Advection for Salt */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) AdamsBashforthGs = /* apply Adams-Bashforth extrapolation on Gs */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) AdamsBashforth_S = /* apply Adams-Bashforth extrapolation on Salt */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) // ===================================
(PID.TID 0000.0001) 
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // External forcing (EXF) configuration >>> START <<<
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) 
(PID.TID 0000.0001)  EXF general parameters:
(PID.TID 0000.0001) 
(PID.TID 0000.0001) exf_iprec = /* exf file precision */
(PID.TID 0000.0001)                      64
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) useExfYearlyFields = /* add extension _YEAR to input file names */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) twoDigitYear = /* use 2-digit year extension */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) useExfCheckRange = /* check for fields range */
(PID.TID 0000.0001)                   T
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) exf_debugLev = /* select EXF-debug printing level */
(PID.TID 0000.0001)                       2
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) exf_monFreq  = /* EXF monitor frequency [ s ] */
(PID.TID 0000.0001)                 8.640000000000000E+07
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) repeatPeriod = /* period for cycling forcing dataset [ s ] */
(PID.TID 0000.0001)                 0.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) climTempFreeze= /* Minimum climatological temperature [deg.C] */
(PID.TID 0000.0001)                -1.900000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) windStressMax = /* Maximum absolute windstress [ Pa ] */
(PID.TID 0000.0001)                 2.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) stressIsOnCgrid = /* set u,v_stress on Arakawa C-grid */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) rotateStressOnAgrid = /* rotate u,v_stress on Arakawa A-grid */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) cen2kel = /* conversion of deg. Centigrade to Kelvin [K] */
(PID.TID 0000.0001)                 2.731500000000000E+02
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) gravity_mks= /* gravitational acceleration [m/s^2] */
(PID.TID 0000.0001)                 9.810000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) atmrho =  /* mean atmospheric density [kg/m^3] */
(PID.TID 0000.0001)                 1.200000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) atmcp =  /* mean atmospheric specific heat [J/kg/K] */
(PID.TID 0000.0001)                 1.005000000000000E+03
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) flamb =  /* latent heat of evaporation [J/kg] */
(PID.TID 0000.0001)                 2.500000000000000E+06
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) flami =  /* latent heat of pure-ice melting [J/kg] */
(PID.TID 0000.0001)                 3.340000000000000E+05
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) cvapor_fac = /* const. for Saturation calculation [?] */
(PID.TID 0000.0001)                 6.403800000000000E+05
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) cvapor_exp = /* const. for Saturation calculation [?] */
(PID.TID 0000.0001)                 5.107400000000000E+03
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) cvapor_fac_ice= /* const. for Saturation calculation [?] */
(PID.TID 0000.0001)                 1.163780000000000E+07
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) cvapor_exp_ice= /* const. for Saturation calculation [?] */
(PID.TID 0000.0001)                 5.897800000000000E+03
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) humid_fac = /* humidity coef. in virtual temp. [(kg/kg)^-1] */
(PID.TID 0000.0001)                 6.060000000000000E-01
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) gamma_blk = /* adiabatic lapse rate [?] */
(PID.TID 0000.0001)                 1.000000000000000E-02
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) saltsat = /* reduction of Qsat over salty water [-] */
(PID.TID 0000.0001)                 9.800000000000000E-01
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) noNegativeEvap = /* prevent negative Evaporation */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) sstExtrapol = /* extrapolation coeff from lev. 1 & 2 to surf [-] */
(PID.TID 0000.0001)                 0.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) cDrag_1 = /* coef used in drag calculation [?] */
(PID.TID 0000.0001)                 2.700000000000000E-03
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) cDrag_2 = /* coef used in drag calculation [?] */
(PID.TID 0000.0001)                 1.420000000000000E-04
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) cDrag_3 = /* coef used in drag calculation [?] */
(PID.TID 0000.0001)                 7.640000000000000E-05
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) cStanton_1 = /* coef used in Stanton number calculation [?] */
(PID.TID 0000.0001)                 3.270000000000000E-02
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) cStanton_2 = /* coef used in Stanton number calculation [?] */
(PID.TID 0000.0001)                 1.800000000000000E-02
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) cDalton = /* coef used in Dalton number calculation [?] */
(PID.TID 0000.0001)                 3.460000000000000E-02
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) exf_scal_BulkCdn= /* Drag coefficient scaling factor [-] */
(PID.TID 0000.0001)                 1.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) zolmin = /* minimum stability parameter [?] */
(PID.TID 0000.0001)                -1.000000000000000E+02
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) psim_fac = /* coef used in turbulent fluxes calculation [-] */
(PID.TID 0000.0001)                 5.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) zref =  /* reference height [ m ] */
(PID.TID 0000.0001)                 1.000000000000000E+01
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) hu =  /* height of mean wind [ m ] */
(PID.TID 0000.0001)                 1.000000000000000E+01
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) ht =  /* height of mean temperature [ m ] */
(PID.TID 0000.0001)                 2.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) hq =  /* height of mean spec.humidity [ m ] */
(PID.TID 0000.0001)                 2.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) uMin = /* minimum wind speed [m/s] */
(PID.TID 0000.0001)                 5.000000000000000E-01
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) useStabilityFct_overIce= /* transfert Coeffs over sea-ice depend on stability */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) exf_iceCd = /* drag coefficient over sea-ice (fixed) [-] */
(PID.TID 0000.0001)                 1.630000000000000E-03
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) exf_iceCe = /* transfert coeff. over sea-ice, for Evap (fixed) [-] */
(PID.TID 0000.0001)                 1.630000000000000E-03
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) exf_iceCh = /* transfert coeff. over sea-ice, Sens.Heat.(fixed)[-] */
(PID.TID 0000.0001)                 1.630000000000000E-03
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) exf_albedo =  /* Sea-water albedo [-] */
(PID.TID 0000.0001)                 1.000000000000000E-01
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) useExfZenAlbedo = /* Sea-water albedo varies with zenith angle */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) select_ZenAlbedo = /* Sea-water albedo computation method */
(PID.TID 0000.0001)                       0
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) useExfZenIncoming = /* compute incoming solar radiation */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) ocean_emissivity = /* longwave ocean-surface emissivity [-] */
(PID.TID 0000.0001)                 9.700176366843034E-01
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) ice_emissivity = /* longwave seaice emissivity [-] */
(PID.TID 0000.0001)                 9.500000000000000E-01
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) snow_emissivity = /* longwave snow  emissivity [-] */
(PID.TID 0000.0001)                 9.500000000000000E-01
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) 
(PID.TID 0000.0001)  EXF main CPP flags:
(PID.TID 0000.0001) 
(PID.TID 0000.0001) // USE_EXF_INTERPOLATION:          NOT defined
(PID.TID 0000.0001) // ALLOW_ATM_TEMP:                     defined
(PID.TID 0000.0001) // ALLOW_ATM_WIND (useAtmWind):        defined
(PID.TID 0000.0001) // ALLOW_DOWNWARD_RADIATION:           defined
(PID.TID 0000.0001) // ALLOW_BULKFORMULAE:                 defined
(PID.TID 0000.0001) 
(PID.TID 0000.0001)    Zonal wind forcing period is                          0.
(PID.TID 0000.0001)    Zonal wind forcing is read from file:
(PID.TID 0000.0001)    >> windx.bin <<
(PID.TID 0000.0001) 
(PID.TID 0000.0001) // ALLOW_READ_TURBFLUXES:          NOT defined
(PID.TID 0000.0001) // EXF_READ_EVAP:                  NOT defined
(PID.TID 0000.0001) // ALLOW_RUNOFF:                       defined
(PID.TID 0000.0001) // ALLOW_RUNOFTEMP:                NOT defined
(PID.TID 0000.0001) // ALLOW_SALTFLX:                      defined
(PID.TID 0000.0001) 
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // External forcing (EXF) climatology configuration :
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) 
(PID.TID 0000.0001) // ALLOW_CLIMSST_RELAXATION:           defined
(PID.TID 0000.0001)    climsst relaxation is NOT used
(PID.TID 0000.0001) 
(PID.TID 0000.0001) // ALLOW_CLIMSSS_RELAXATION:           defined
(PID.TID 0000.0001)    climsss relaxation is NOT used
(PID.TID 0000.0001) 
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // External forcing (EXF) configuration  >>> END <<<
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) 
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // Seaice configuration (SEAICE_PARM01) >>> START <<<
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) 
(PID.TID 0000.0001)    Seaice time stepping configuration   > START <
(PID.TID 0000.0001)    ----------------------------------------------
(PID.TID 0000.0001) SEAICE_deltaTtherm= /* thermodynamic timestep */
(PID.TID 0000.0001)                 1.800000000000000E+03
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICE_deltaTdyn  = /* dynamic timestep */
(PID.TID 0000.0001)                 1.800000000000000E+03
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICE_deltaTevp  = /* EVP timestep */
(PID.TID 0000.0001)                 1.234567000000000E+05
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICEuseBDF2  = /* use backw. differencing for mom. eq. */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICEupdateOceanStress= /* update Ocean surf. stress */
(PID.TID 0000.0001)                   T
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICErestoreUnderIce  = /* restore T and S under ice */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) 
(PID.TID 0000.0001)    Seaice dynamics configuration   > START <
(PID.TID 0000.0001)    ------------------------------------------
(PID.TID 0000.0001) SEAICEuseDYNAMICS = /* use dynamics */
(PID.TID 0000.0001)                   T
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) model grid type   = /* type of sea ice model grid */
(PID.TID 0000.0001)               'C-GRID'
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICEuseStrImpCpl = /* use strongly implicit coupling */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICEusePicardAsPrecon = /* Picard as preconditioner */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICEuseLSR      = /* use default Picard-LSR solver */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICEuseKrylov   = /* use Picard-Krylov solver */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICEuseEVP      = /* use EVP solver rather than LSR */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICEuseJFNK     = /* use JFNK solver */
(PID.TID 0000.0001)                   T
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICEuseFREEDRIFT = /* use free drift solution */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) OCEAN_drag        = /* air-ocean drag coefficient */
(PID.TID 0000.0001)                 8.154100000000000E-04
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICE_drag       = /* air-ice drag coefficient */
(PID.TID 0000.0001)                 2.000000000000000E-03
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICE_drag_south      = /* Southern Ocean SEAICE_drag */
(PID.TID 0000.0001)                 2.000000000000000E-03
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICE_waterDrag  = /* water-ice drag */
(PID.TID 0000.0001)                 5.500000000000000E-03
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICE_waterDrag_south = /* Southern Ocean waterDrag */
(PID.TID 0000.0001)                 5.500000000000000E-03
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICEuseTilt     = /* include surface tilt in dyna. */
(PID.TID 0000.0001)                   T
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICEuseTEM      = /* use truncated ellipse rheology */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICE_strength   = /* sea-ice strength Pstar */
(PID.TID 0000.0001)                 2.678000000000000E+04
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICE_cStar      = /* sea-ice strength parameter cStar */
(PID.TID 0000.0001)                 2.000000000000000E+01
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICEpressReplFac= /* press. replacement method factor */
(PID.TID 0000.0001)                 1.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICE_tensilFac  = /* sea-ice tensile strength factor */
(PID.TID 0000.0001)                 0.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICE_tensilDepth= /* crit. depth for tensile strength */
(PID.TID 0000.0001)                 0.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICEpresH0   = /* sea-ice strength Heff threshold */
(PID.TID 0000.0001)                 1.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICEpresPow0 = /* exponent for Heff<SEAICEpresH0 */
(PID.TID 0000.0001)                       1
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICEpresPow1 = /* exponent for Heff>SEAICEpresH0 */
(PID.TID 0000.0001)                       1
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICEetaZmethod = /* method computing eta at Z-point */
(PID.TID 0000.0001)                       3
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICE_zetaMin    = /* lower bound for viscosity */
(PID.TID 0000.0001)                 0.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICE_eccen    = /* elliptical yield curve eccent */
(PID.TID 0000.0001)                 2.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICEstressFactor    = /* wind stress scaling factor */
(PID.TID 0000.0001)                 1.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICE_airTurnAngle    = /* air-ice turning angle */
(PID.TID 0000.0001)                 0.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICE_waterTurnAngle  = /* ice-water turning angle */
(PID.TID 0000.0001)                 0.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICEuseMetricTerms = /* use metric terms */
(PID.TID 0000.0001)                   T
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICE_no_slip    = /* no slip boundary conditions */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICE_2ndOrderBC = /* 2nd order no slip boundary conditions */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICE_clipVeloctities = /* impose max. vels. */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) useHB87stressCoupling  = /* altern. ice-ocean stress */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICEscaleSurfStress  = /* scale atm. and ocean-surface stress with AREA */
(PID.TID 0000.0001)                   T
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICE_maskRHS    = /* mask RHS of solver */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICEaddSnowMass = /* add snow mass to seaiceMassC/U/V */
(PID.TID 0000.0001)                   T
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) LSR_mixIniGuess = /* mix free-drift sol. into LSR initial Guess */
(PID.TID 0000.0001)                       0
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICE_LSRrelaxU  = /* LSR solver: relaxation parameter */
(PID.TID 0000.0001)                 9.500000000000000E-01
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICE_LSRrelaxV  = /* LSR solver: relaxation parameter */
(PID.TID 0000.0001)                 9.500000000000000E-01
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) LSR_ERROR         = /* sets accuracy of LSR solver */
(PID.TID 0000.0001)                 1.000000000000000E-04
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SOLV_NCHECK       = /* test interval for LSR solver */
(PID.TID 0000.0001)                       2
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICEuseMultiTileSolver = /* use full domain tri-diag solver */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICE_OLx = /* overlap for LSR/preconditioner */
(PID.TID 0000.0001)                       1
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICE_OLy = /* overlap for LSR/preconditioner */
(PID.TID 0000.0001)                       1
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICEnonLinIterMax = /* max. number of nonlinear solver steps */
(PID.TID 0000.0001)                     200
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICElinearIterMax = /* max. number of linear solver steps */
(PID.TID 0000.0001)                      50
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICEnonLinTol     = /* non-linear solver tolerance */
(PID.TID 0000.0001)                 1.000000000000000E-09
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICEpreconLinIter = /* number of linear preconditioner steps */
(PID.TID 0000.0001)                      10
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICEpreconNL_Iter = /* number of non-linear preconditioner steps */
(PID.TID 0000.0001)                       0
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICEuseIMEX  = /* IMEX scheme with JFNK-solver */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICE_JFNK_lsIter = /* start of line search */
(PID.TID 0000.0001)                       0
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICE_JFNK_tolIter = /* tol. is relaxed after this */
(PID.TID 0000.0001)                     100
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) JFNKres_t= /* JFNK parameter */
(PID.TID 0000.0001)                 1.234567000000000E+05
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) JFNKres_tFac= /* JFNK parameter */
(PID.TID 0000.0001)                 5.000000000000000E-01
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICE_JFNKepsilon= /* JFNK: FD-gradient step size */
(PID.TID 0000.0001)                 1.000000000000000E-06
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICE_JFNKphi = /* JFNK: inexact Newtow parameter */
(PID.TID 0000.0001)                 1.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICE_JFNKalpha = /* JFNK: inexact Newtow parameter */
(PID.TID 0000.0001)                 1.500000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) 
(PID.TID 0000.0001)    Seaice advection diffusion config,   > START <
(PID.TID 0000.0001)    -----------------------------------------------
(PID.TID 0000.0001)    ==> advection diffusion done in pkg ThSIce
(PID.TID 0000.0001) 
(PID.TID 0000.0001)    Seaice thermodynamics configuration   > START <
(PID.TID 0000.0001)    -----------------------------------------------
(PID.TID 0000.0001) SEAICE_rhoIce     = /* density of sea ice (kg/m3) */
(PID.TID 0000.0001)                 9.100000000000000E+02
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICE_rhoSnow    = /* density of snow (kg/m3) */
(PID.TID 0000.0001)                 3.300000000000000E+02
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICE_rhoAir     = /* density of air (kg/m3) */
(PID.TID 0000.0001)                 1.200000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) usePW79thermodynamics  = /* default 0-layer TD */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001)    pkg/seaice thermodynamics is OFF
(PID.TID 0000.0001) 
(PID.TID 0000.0001)    Seaice initialization and IO config.,   > START <
(PID.TID 0000.0001)    -------------------------------------------------
(PID.TID 0000.0001) SEAICE_initialHEFF= /* initial sea-ice thickness */
(PID.TID 0000.0001)                 0.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) AreaFile = /* Initial ice concentration File */
(PID.TID 0000.0001)               ''
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) HeffFile = /* Initial effective ice thickness File */
(PID.TID 0000.0001)               ''
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) HsnowFile = /* Initial snow thickness File */
(PID.TID 0000.0001)               ''
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) uIceFile = /* Initial U-ice velocity File */
(PID.TID 0000.0001)               ''
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) vIceFile = /* Initial V-ice velocity File */
(PID.TID 0000.0001)               ''
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICEwriteState  = /* write sea ice state to file */
(PID.TID 0000.0001)                   T
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICE_monFreq  = /* monitor frequency */
(PID.TID 0000.0001)                 1.800000000000000E+03
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICE_dumpFreq   = /* dump frequency */
(PID.TID 0000.0001)                 4.320000000000000E+05
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICE_taveFreq   = /* time-averaging frequency */
(PID.TID 0000.0001)                 0.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICE_mon_stdio  = /* write monitor to std-outp */
(PID.TID 0000.0001)                   T
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICE_dump_mdsio = /* write snap-shot   using MDSIO */
(PID.TID 0000.0001)                   T
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICE_tave_mdsio = /* write TimeAverage using MDSIO */
(PID.TID 0000.0001)                   T
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) 
(PID.TID 0000.0001)    Seaice regularization numbers,   > START <
(PID.TID 0000.0001)    -----------------------------------------------
(PID.TID 0000.0001) SEAICE_deltaMin   = /* reduce singularities in Delta */
(PID.TID 0000.0001)                 1.000000000000000E-10
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICE_EPS        = /* small number */
(PID.TID 0000.0001)                 1.000000000000000E-10
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICE_EPS_SQ     = /* small number squared */
(PID.TID 0000.0001)                 1.000000000000000E-20
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICE_area_reg   = /* reduce derivative singularities */
(PID.TID 0000.0001)                 1.000000000000000E-05
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICE_hice_reg   = /* reduce derivative singularities */
(PID.TID 0000.0001)                 5.000000000000000E-02
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) SEAICE_area_floor = /* reduce derivative singularities */
(PID.TID 0000.0001)                 1.000000000000000E-05
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) 
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // Seaice configuration (SEAICE_PARM01) >>> END <<<
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) 
(PID.TID 0000.0001) ------------------------------------------------------------
(PID.TID 0000.0001) DIAGNOSTICS_SET_LEVELS: done
(PID.TID 0000.0001)  Total Nb of available Diagnostics: ndiagt=   248
(PID.TID 0000.0001)  write list of available Diagnostics to file: available_diagnostics.log
(PID.TID 0000.0001) SETDIAG: Allocate  1 x  1 Levels for Diagnostic #   155 SIuice
(PID.TID 0000.0001) SETDIAG: Allocate  1 x  1 Levels for Diagnostic #   156 SIvice
(PID.TID 0000.0001) SETDIAG: Allocate  1 x  1 Levels for Diagnostic #   149 SIheff
(PID.TID 0000.0001) SETDIAG: Allocate  1 x  1 Levels for Diagnostic #   216 SI_Fract
(PID.TID 0000.0001) SETDIAG: Allocate  1 x  1 Levels for Diagnostic #   217 SI_Thick
(PID.TID 0000.0001) - NOTE - SETDIAG: Counter-mate #   216 SI_Fract is already set
(PID.TID 0000.0001)   space allocated for all diagnostics:       5 levels
(PID.TID 0000.0001)   set mate pointer for diag #   155  SIuice   , Parms: UU      M1 , mate:   156
(PID.TID 0000.0001)   set mate pointer for diag #   156  SIvice   , Parms: VV      M1 , mate:   155
(PID.TID 0000.0001) DIAGNOSTICS_SET_POINTERS: Set levels for Outp.Stream: snapshot
(PID.TID 0000.0001)  Levels:       1.
(PID.TID 0000.0001) DIAGNOSTICS_SET_POINTERS: done
(PID.TID 0000.0001) ------------------------------------------------------------
(PID.TID 0000.0001) DIAGSTATS_SET_REGIONS: define no region
(PID.TID 0000.0001) ------------------------------------------------------------
(PID.TID 0000.0001) SETDIAG: Allocate  1 Levels for Stats-Diag #   216 SI_Fract
(PID.TID 0000.0001) SETDIAG: Allocate  1 Levels for Stats-Diag #   217 SI_Thick
(PID.TID 0000.0001) - NOTE - SETDIAG: Counter Diagnostic #   216 SI_Fract has already been set
(PID.TID 0000.0001) SETDIAG: Allocate  1 Levels for Stats-Diag #   146 SIarea
(PID.TID 0000.0001) SETDIAG: Allocate  1 Levels for Stats-Diag #   149 SIheff
(PID.TID 0000.0001) SETDIAG: Allocate  1 Levels for Stats-Diag #   155 SIuice
(PID.TID 0000.0001) SETDIAG: Allocate  1 Levels for Stats-Diag #   156 SIvice
(PID.TID 0000.0001)   space allocated for all stats-diags:       6 levels
(PID.TID 0000.0001) DIAGSTATS_SET_POINTERS: done
(PID.TID 0000.0001) ------------------------------------------------------------
(PID.TID 0000.0001) DIAGSTATS_INI_IO: open file: iceStDiag.0000000000.txt , unit=     9
(PID.TID 0000.0001) %MON fCori_max                    =   0.0000000000000E+00
(PID.TID 0000.0001) %MON fCori_min                    =   0.0000000000000E+00
(PID.TID 0000.0001) %MON fCori_mean                   =   0.0000000000000E+00
(PID.TID 0000.0001) %MON fCori_sd                     =   0.0000000000000E+00
(PID.TID 0000.0001) %MON fCoriG_max                   =   0.0000000000000E+00
(PID.TID 0000.0001) %MON fCoriG_min                   =   0.0000000000000E+00
(PID.TID 0000.0001) %MON fCoriG_mean                  =   0.0000000000000E+00
(PID.TID 0000.0001) %MON fCoriG_sd                    =   0.0000000000000E+00
(PID.TID 0000.0001) %MON fCoriCos_max                 =   0.0000000000000E+00
(PID.TID 0000.0001) %MON fCoriCos_min                 =   0.0000000000000E+00
(PID.TID 0000.0001) %MON fCoriCos_mean                =   0.0000000000000E+00
(PID.TID 0000.0001) %MON fCoriCos_sd                  =   0.0000000000000E+00
(PID.TID 0000.0001) INI_CG2D: CG2D normalisation factor =  1.0000000000000001E-01
(PID.TID 0000.0001) 
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // Model configuration
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) //
(PID.TID 0000.0001) // "Physical" paramters ( PARM01 in namelist )
(PID.TID 0000.0001) //
(PID.TID 0000.0001) buoyancyRelation = /* Type of relation to get Buoyancy */
(PID.TID 0000.0001)               'OCEANIC'
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) fluidIsAir   =  /* fluid major constituent is Air */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) fluidIsWater =  /* fluid major constituent is Water */
(PID.TID 0000.0001)                   T
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) usingPCoords =  /* use p (or p*) vertical coordinate */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) usingZCoords =  /* use z (or z*) vertical coordinate */
(PID.TID 0000.0001)                   T
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) tRef =   /* Reference temperature profile ( oC or K ) */
(PID.TID 0000.0001)                -1.620000000000000E+00       /* K =  1 */
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) sRef =   /* Reference salinity profile ( psu ) */
(PID.TID 0000.0001)                 3.000000000000000E+01       /* K =  1 */
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) useStrainTensionVisc= /* Use StrainTension Form of Viscous Operator */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) useVariableVisc = /* Use variable horizontal viscosity */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) useHarmonicVisc = /* Use harmonic horizontal viscosity */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) useBiharmonicVisc= /* Use biharmonic horiz.  viscosity */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) useSmag3D = /* Use isotropic 3-D Smagorinsky viscosity */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) viscAh  =   /* Lateral harmonic viscosity ( m^2/s ) */
(PID.TID 0000.0001)                 3.000000000000000E+02
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) viscA4  =   /* Lateral biharmonic viscosity ( m^4/s ) */
(PID.TID 0000.0001)                 0.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) no_slip_sides =  /* Viscous BCs: No-slip sides */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) sideDragFactor = /* side-drag scaling factor (non-dim) */
(PID.TID 0000.0001)                 2.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) viscArNr = /* vertical profile of vertical viscosity ( m^2/s )*/
(PID.TID 0000.0001)                 3.000000000000000E-02       /* K =  1 */
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) no_slip_bottom =  /* Viscous BCs: No-slip bottom */
(PID.TID 0000.0001)                   T
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) bottomVisc_pCell = /* Partial-cell in bottom Visc. BC */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) bottomDragLinear = /* linear bottom-drag coefficient ( m/s ) */
(PID.TID 0000.0001)                 0.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) bottomDragQuadratic = /* quadratic bottom-drag coefficient (-) */
(PID.TID 0000.0001)                 5.000000000000000E-03
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) selectBotDragQuadr = /* select quadratic bottom drag options */
(PID.TID 0000.0001)                      -1
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) diffKhT =   /* Laplacian diffusion of heat laterally ( m^2/s ) */
(PID.TID 0000.0001)                 0.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) diffK4T =   /* Biharmonic diffusion of heat laterally ( m^4/s ) */
(PID.TID 0000.0001)                 0.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) diffKhS =   /* Laplacian diffusion of salt laterally ( m^2/s ) */
(PID.TID 0000.0001)                 0.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) diffK4S =   /* Biharmonic diffusion of salt laterally ( m^4/s ) */
(PID.TID 0000.0001)                 0.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) diffKrNrT = /* vertical profile of vertical diffusion of Temp ( m^2/s )*/
(PID.TID 0000.0001)                 0.000000000000000E+00       /* K =  1 */
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) diffKrNrS = /* vertical profile of vertical diffusion of Salt ( m^2/s )*/
(PID.TID 0000.0001)                 0.000000000000000E+00       /* K =  1 */
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) diffKrBL79surf = /* Surface diffusion for Bryan and Lewis 79 ( m^2/s ) */
(PID.TID 0000.0001)                 0.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) diffKrBL79deep = /* Deep diffusion for Bryan and Lewis 1979 ( m^2/s ) */
(PID.TID 0000.0001)                 0.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) diffKrBL79scl = /* Depth scale for Bryan and Lewis 1979 ( m ) */
(PID.TID 0000.0001)                 2.000000000000000E+02
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) diffKrBL79Ho = /* Turning depth for Bryan and Lewis 1979 ( m ) */
(PID.TID 0000.0001)                -2.000000000000000E+03
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) ivdc_kappa = /* Implicit Vertical Diffusivity for Convection ( m^2/s) */
(PID.TID 0000.0001)                 0.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) hMixCriteria=  /* Criteria for mixed-layer diagnostic */
(PID.TID 0000.0001)                -8.000000000000000E-01
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) dRhoSmall =  /* Parameter for mixed-layer diagnostic */
(PID.TID 0000.0001)                 1.000000000000000E-06
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) hMixSmooth=  /* Smoothing parameter for mixed-layer diagnostic */
(PID.TID 0000.0001)                 0.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) eosType =  /* Type of Equation of State */
(PID.TID 0000.0001)               'LINEAR'
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) tAlpha = /* Linear EOS thermal expansion coefficient ( 1/oC ) */
(PID.TID 0000.0001)                 2.000000000000000E-04
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) sBeta  = /* Linear EOS haline contraction coefficient ( 1/psu ) */
(PID.TID 0000.0001)                 0.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) rhoNil    = /* Reference density for Linear EOS ( kg/m^3 ) */
(PID.TID 0000.0001)                 1.030000000000000E+03
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) selectP_inEOS_Zc = /* select pressure to use in EOS (0,1,2,3) */
(PID.TID 0000.0001)                       0
(PID.TID 0000.0001)     0= -g*rhoConst*z ; 1= pRef (from tRef,sRef); 2= Hyd P ; 3= Hyd+NH P
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) HeatCapacity_Cp =  /* Specific heat capacity ( J/kg/K ) */
(PID.TID 0000.0001)                 3.986000000000000E+03
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) celsius2K = /* 0 degree Celsius converted to Kelvin ( K ) */
(PID.TID 0000.0001)                 2.731500000000000E+02
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) rhoConst  = /* Reference density (Boussinesq)  ( kg/m^3 ) */
(PID.TID 0000.0001)                 1.030000000000000E+03
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) rhoFacC = /* normalized Reference density @ cell-Center (-) */
(PID.TID 0000.0001)                 1.000000000000000E+00       /* K =  1 */
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) rhoFacF = /* normalized Reference density @ W-Interface (-) */
(PID.TID 0000.0001)     2 @  1.000000000000000E+00              /* K =  1:  2 */
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) rhoConstFresh = /* Fresh-water reference density ( kg/m^3 ) */
(PID.TID 0000.0001)                 1.000000000000000E+03
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) gravity =   /* Gravitational acceleration ( m/s^2 ) */
(PID.TID 0000.0001)                 9.810000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) gBaro =   /* Barotropic gravity ( m/s^2 ) */
(PID.TID 0000.0001)                 9.810000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) gravFacC = /* gravity factor (vs surf.) @ cell-Center (-) */
(PID.TID 0000.0001)                 1.000000000000000E+00       /* K =  1 */
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) gravFacF = /* gravity factor (vs surf.) @ W-Interface (-) */
(PID.TID 0000.0001)     2 @  1.000000000000000E+00              /* K =  1:  2 */
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) rotationPeriod =   /* Rotation Period ( s ) */
(PID.TID 0000.0001)                 8.616400000000000E+04
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) omega =   /* Angular velocity ( rad/s ) */
(PID.TID 0000.0001)                 7.292123516990375E-05
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) f0 =   /* Reference coriolis parameter ( 1/s ) */
(PID.TID 0000.0001)                 0.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) beta =   /* Beta ( 1/(m.s) ) */
(PID.TID 0000.0001)                 0.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) fPrime =   /* Second coriolis parameter ( 1/s ) */
(PID.TID 0000.0001)                 0.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) rigidLid =   /* Rigid lid on/off flag */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) implicitFreeSurface =   /* Implicit free surface on/off flag */
(PID.TID 0000.0001)                   T
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) freeSurfFac =   /* Implicit free surface factor */
(PID.TID 0000.0001)                 1.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) implicSurfPress =  /* Surface Pressure implicit factor (0-1)*/
(PID.TID 0000.0001)                 1.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) implicDiv2DFlow =  /* Barot. Flow Div. implicit factor (0-1)*/
(PID.TID 0000.0001)                 1.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) uniformLin_PhiSurf = /* use uniform Bo_surf on/off flag*/
(PID.TID 0000.0001)                   T
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) uniformFreeSurfLev = /* free-surface level-index is uniform */
(PID.TID 0000.0001)                   T
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) hFacMin =   /* minimum partial cell factor (hFac) */
(PID.TID 0000.0001)                 1.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) hFacMinDr = /* minimum partial cell thickness ( m) */
(PID.TID 0000.0001)                 0.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) exactConserv =  /* Exact Volume Conservation on/off flag*/
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) linFSConserveTr = /* Tracer correction for Lin Free Surface on/off flag*/
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) nonlinFreeSurf = /* Non-linear Free Surf. options (-1,0,1,2,3)*/
(PID.TID 0000.0001)                       0
(PID.TID 0000.0001)      -1,0= Off ; 1,2,3= On, 2=+rescale gU,gV, 3=+update cg2d solv.
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) hFacInf =   /* lower threshold for hFac (nonlinFreeSurf only)*/
(PID.TID 0000.0001)                 2.000000000000000E-01
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) hFacSup =   /* upper threshold for hFac (nonlinFreeSurf only)*/
(PID.TID 0000.0001)                 2.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) select_rStar = /* r* Vertical coord. options (=0 r coord.; >0 uses r*)*/
(PID.TID 0000.0001)                       0
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) useRealFreshWaterFlux = /* Real Fresh Water Flux on/off flag*/
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) temp_EvPrRn = /* Temp. of Evap/Prec/R (UNSET=use local T)(oC)*/
(PID.TID 0000.0001)                 1.234567000000000E+05
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) salt_EvPrRn = /* Salin. of Evap/Prec/R (UNSET=use local S)(psu)*/
(PID.TID 0000.0001)                 0.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) selectAddFluid = /* option for mass source/sink of fluid (=0: off) */
(PID.TID 0000.0001)                       0
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) temp_addMass = /* Temp. of addMass array (UNSET=use local T)(oC)*/
(PID.TID 0000.0001)                 1.234567000000000E+05
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) salt_addMass = /* Salin. of addMass array (UNSET=use local S)(psu)*/
(PID.TID 0000.0001)                 0.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) convertFW2Salt = /* convert F.W. Flux to Salt Flux (-1=use local S)(psu)*/
(PID.TID 0000.0001)                -1.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) use3Dsolver = /* use 3-D pressure solver on/off flag */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) nonHydrostatic =  /* Non-Hydrostatic on/off flag */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) nh_Am2 = /* Non-Hydrostatic terms scaling factor */
(PID.TID 0000.0001)                 1.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) implicitNHPress = /* Non-Hyd Pressure implicit factor (0-1)*/
(PID.TID 0000.0001)                 1.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) selectNHfreeSurf = /* Non-Hyd (free-)Surface option */
(PID.TID 0000.0001)                       0
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) quasiHydrostatic = /* Quasi-Hydrostatic on/off flag */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) calc_wVelocity = /* vertical velocity calculation on/off flag */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) momStepping =  /* Momentum equation on/off flag */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) vectorInvariantMomentum= /* Vector-Invariant Momentum on/off */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) momAdvection =  /* Momentum advection on/off flag */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) momViscosity =  /* Momentum viscosity on/off flag */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) momImplVertAdv= /* Momentum implicit vert. advection on/off*/
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) implicitViscosity = /* Implicit viscosity on/off flag */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) selectImplicitDrag= /* Implicit bot Drag options (0,1,2)*/
(PID.TID 0000.0001)                       0
(PID.TID 0000.0001)     0= Expl. ; 1= Impl. on provis. Vel ; 2= Fully Impl (with surf.P)
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) metricTerms =  /* metric-Terms on/off flag */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) useNHMTerms = /* Non-Hydrostatic Metric-Terms on/off */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) selectCoriMap = /* Coriolis Map options (0,1,2,3)*/
(PID.TID 0000.0001)                       1
(PID.TID 0000.0001)     0= f-Plane ; 1= Beta-Plane ; 2= Spherical ; 3= read from file
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) use3dCoriolis = /* 3-D Coriolis on/off flag */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) useCoriolis =  /* Coriolis on/off flag */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) useCDscheme =  /* CD scheme on/off flag */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) useEnergyConservingCoriolis= /* Flx-Form Coriolis scheme flag */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) useJamartWetPoints= /* Coriolis WetPoints method flag */
(PID.TID 0000.0001)                   T
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) useJamartMomAdv= /* V.I Non-linear terms Jamart flag */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) useAbsVorticity= /* V.I Works with f+zeta in Coriolis */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) selectVortScheme= /* V.I Scheme selector for Vorticity-Term */
(PID.TID 0000.0001)               123456789
(PID.TID 0000.0001)    = 0 : enstrophy (Shallow-Water Eq.) conserving scheme by Sadourny, JAS 75
(PID.TID 0000.0001)    = 1 : same as 0 with modified hFac
(PID.TID 0000.0001)    = 2 : energy conserving scheme (used by Sadourny in JAS 75 paper)
(PID.TID 0000.0001)    = 3 : energy (general) and enstrophy (2D, nonDiv.) conserving scheme
(PID.TID 0000.0001)          from Sadourny (Burridge & Haseler, ECMWF Rep.4, 1977)
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) upwindVorticity= /* V.I Upwind bias vorticity flag */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) highOrderVorticity= /* V.I High order vort. advect. flag */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) upwindShear= /* V.I Upwind vertical Shear advection flag */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) selectKEscheme= /* V.I Kinetic Energy scheme selector */
(PID.TID 0000.0001)                       0
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) momForcing =  /* Momentum forcing on/off flag */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) momPressureForcing =  /* Momentum pressure term on/off flag */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) implicitIntGravWave= /* Implicit Internal Gravity Wave flag */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) staggerTimeStep =    /* Stagger time stepping on/off flag */
(PID.TID 0000.0001)                   T
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) doResetHFactors = /* reset thickness factors @ each time-step */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) multiDimAdvection =  /* enable/disable Multi-Dim Advection */
(PID.TID 0000.0001)                   T
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) useMultiDimAdvec =   /* Multi-Dim Advection is/is-not used */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) implicitDiffusion = /* Implicit Diffusion on/off flag */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) tempStepping =  /* Temperature equation on/off flag */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) tempAdvection = /* Temperature advection on/off flag */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) tempImplVertAdv = /* Temp. implicit vert. advection on/off */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) tempForcing  =  /* Temperature forcing on/off flag */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) doThetaClimRelax = /* apply SST relaxation on/off flag */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) tempIsActiveTr = /* Temp. is a dynamically Active Tracer */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) saltStepping =  /* Salinity equation on/off flag */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) saltAdvection = /* Salinity advection on/off flag */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) saltImplVertAdv = /* Sali. implicit vert. advection on/off */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) saltForcing  =  /* Salinity forcing on/off flag */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) doSaltClimRelax = /* apply SSS relaxation on/off flag */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) saltIsActiveTr = /* Salt  is a dynamically Active Tracer */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001)  readBinaryPrec = /* Precision used for reading binary files */
(PID.TID 0000.0001)                      64
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) writeBinaryPrec = /* Precision used for writing binary files */
(PID.TID 0000.0001)                      64
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001)  rwSuffixType =   /* select format of mds file suffix */
(PID.TID 0000.0001)                       0
(PID.TID 0000.0001)    = 0 : myIter (I10.10) ;   = 1 : 100*myTime (100th sec) ;
(PID.TID 0000.0001)    = 2 : myTime (seconds);   = 3 : myTime/360 (10th of hr);
(PID.TID 0000.0001)    = 4 : myTime/3600 (hours)
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001)  globalFiles = /* write "global" (=not per tile) files */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001)  useSingleCpuIO = /* only master MPI process does I/O */
(PID.TID 0000.0001)                   T
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001)  useSingleCpuInput = /* only master process reads input */
(PID.TID 0000.0001)                   T
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) /* debLev[*]  : level of debug & auxiliary message printing */
(PID.TID 0000.0001) debLevZero =  0 ; /* level of disabled aux. msg printing */
(PID.TID 0000.0001)    debLevA =  1 ; /* level of minimum  aux. msg printing */
(PID.TID 0000.0001)    debLevB =  2 ; /* level of low aux. print (report read-file opening)*/
(PID.TID 0000.0001)    debLevC =  3 ; /* level of moderate debug prt (most pkgs debug msg) */
(PID.TID 0000.0001)    debLevD =  4 ; /* level of enhanced debug prt (add DEBUG_STATS prt) */
(PID.TID 0000.0001)    debLevE =  5 ; /* level of extensive debug printing */
(PID.TID 0000.0001) debugLevel =  /* select debug printing level */
(PID.TID 0000.0001)                       2
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001)  plotLevel =  /* select PLOT_FIELD printing level */
(PID.TID 0000.0001)                       2
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) //
(PID.TID 0000.0001) // Elliptic solver(s) paramters ( PARM02 in namelist )
(PID.TID 0000.0001) //
(PID.TID 0000.0001) cg2dMaxIters =   /* Upper limit on 2d con. grad iterations  */
(PID.TID 0000.0001)                     500
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) cg2dChkResFreq =   /* 2d con. grad convergence test frequency */
(PID.TID 0000.0001)                       1
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) cg2dUseMinResSol= /* use cg2d last-iter(=0) / min-resid.(=1) solution */
(PID.TID 0000.0001)                       0
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) cg2dTargetResidual =   /* 2d con. grad target residual  */
(PID.TID 0000.0001)                 1.000000000000000E-12
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) cg2dTargetResWunit =   /* CG2d target residual [W units] */
(PID.TID 0000.0001)                -1.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) cg2dPreCondFreq =   /* Freq. for updating cg2d preconditioner */
(PID.TID 0000.0001)                       1
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) useSRCGSolver =  /* use single reduction CG solver(s) */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) printResidualFreq = /* Freq. for printing CG residual */
(PID.TID 0000.0001)                       0
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) //
(PID.TID 0000.0001) // Time stepping paramters ( PARM03 in namelist )
(PID.TID 0000.0001) //
(PID.TID 0000.0001) deltaTMom =   /* Momentum equation timestep ( s ) */
(PID.TID 0000.0001)                 1.800000000000000E+03
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) deltaTFreeSurf = /* FreeSurface equation timestep ( s ) */
(PID.TID 0000.0001)                 1.800000000000000E+03
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) dTtracerLev =  /* Tracer equation timestep ( s ) */
(PID.TID 0000.0001)                 1.800000000000000E+03       /* K =  1 */
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) deltaTClock  =   /* Model clock timestep ( s ) */
(PID.TID 0000.0001)                 1.800000000000000E+03
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) cAdjFreq =   /* Convective adjustment interval ( s ) */
(PID.TID 0000.0001)                 0.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) momForcingOutAB = /* =1: take Momentum Forcing out of Adams-Bash. stepping */
(PID.TID 0000.0001)                       1
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) tracForcingOutAB = /* =1: take T,S,pTr Forcing out of Adams-Bash. stepping */
(PID.TID 0000.0001)                       1
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) momDissip_In_AB = /* put Dissipation Tendency in Adams-Bash. stepping */
(PID.TID 0000.0001)                   T
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) doAB_onGtGs = /* apply AB on Tendencies (rather than on T,S)*/
(PID.TID 0000.0001)                   T
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) abEps =   /* Adams-Bashforth-2 stabilizing weight */
(PID.TID 0000.0001)                 1.000000000000000E-01
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) applyExchUV_early = /* Apply EXCH to U,V earlier in time-step */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) pickupStrictlyMatch= /* stop if pickup do not strictly match */
(PID.TID 0000.0001)                   T
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) nIter0   =   /* Run starting timestep number */
(PID.TID 0000.0001)                       0
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) nTimeSteps = /* Number of timesteps */
(PID.TID 0000.0001)                      12
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) nEndIter =   /* Run ending timestep number */
(PID.TID 0000.0001)                      12
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) baseTime =   /* Model base time ( s ) */
(PID.TID 0000.0001)                 0.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) startTime =  /* Run start time ( s ) */
(PID.TID 0000.0001)                 0.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) endTime  =   /* Integration ending time ( s ) */
(PID.TID 0000.0001)                 2.160000000000000E+04
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) pChkPtFreq = /* Permanent restart/pickup file interval ( s ) */
(PID.TID 0000.0001)                 3.600000000000000E+06
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) chkPtFreq  = /* Rolling restart/pickup file interval ( s ) */
(PID.TID 0000.0001)                 0.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) pickup_write_mdsio =   /* Model IO flag. */
(PID.TID 0000.0001)                   T
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) pickup_read_mdsio =   /* Model IO flag. */
(PID.TID 0000.0001)                   T
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) writePickupAtEnd =   /* Model IO flag. */
(PID.TID 0000.0001)                   T
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) dumpFreq =   /* Model state write out interval ( s ). */
(PID.TID 0000.0001)                 4.320000000000000E+05
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) dumpInitAndLast= /* write out Initial & Last iter. model state */
(PID.TID 0000.0001)                   T
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) snapshot_mdsio =   /* Model IO flag. */
(PID.TID 0000.0001)                   T
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) monitorFreq =   /* Monitor output interval ( s ). */
(PID.TID 0000.0001)                 8.640000000000000E+05
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) monitorSelect = /* select group of variables to monitor */
(PID.TID 0000.0001)                       2
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) monitor_stdio =   /* Model IO flag. */
(PID.TID 0000.0001)                   T
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) externForcingPeriod =   /* forcing period (s) */
(PID.TID 0000.0001)                 0.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) externForcingCycle =   /* period of the cyle (s). */
(PID.TID 0000.0001)                 0.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) tauThetaClimRelax =   /* relaxation time scale (s) */
(PID.TID 0000.0001)                 0.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) tauSaltClimRelax =   /* relaxation time scale (s) */
(PID.TID 0000.0001)                 0.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) latBandClimRelax =   /* max. Lat. where relaxation */
(PID.TID 0000.0001)                 6.300000000000000E+05
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) //
(PID.TID 0000.0001) // Gridding paramters ( PARM04 in namelist )
(PID.TID 0000.0001) //
(PID.TID 0000.0001) usingCartesianGrid = /* Cartesian coordinates flag ( True/False ) */
(PID.TID 0000.0001)                   T
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) usingCylindricalGrid = /* Cylindrical coordinates flag ( True/False ) */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) usingSphericalPolarGrid = /* Spherical coordinates flag ( True/False ) */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) usingCurvilinearGrid = /* Curvilinear coordinates flag ( True/False ) */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) useMin4hFacEdges = /* set hFacW,S as minimum of adjacent hFacC factor */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) interViscAr_pCell = /* account for partial-cell in interior vert. viscosity */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) interDiffKr_pCell = /* account for partial-cell in interior vert. diffusion */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) pCellMix_select = /* option to enhance mixing near surface & bottom */
(PID.TID 0000.0001)                       0
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) selectSigmaCoord = /* Hybrid-Sigma Vert. Coordinate option */
(PID.TID 0000.0001)                       0
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) rSigmaBnd = /* r/sigma transition ( units of r ==  m ) */
(PID.TID 0000.0001)                 1.234567000000000E+05
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) rkSign =   /* index orientation relative to vertical coordinate */
(PID.TID 0000.0001)                -1.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) gravitySign = /* gravity orientation relative to vertical coordinate */
(PID.TID 0000.0001)                -1.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) seaLev_Z =  /* reference height of sea-level [m] */
(PID.TID 0000.0001)                 0.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) top_Pres =  /* reference pressure at the top [Pa] */
(PID.TID 0000.0001)                 0.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) mass2rUnit = /* convert mass per unit area [kg/m2] to r-units [m] */
(PID.TID 0000.0001)                 9.708737864077669E-04
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) rUnit2mass = /* convert r-units [m] to mass per unit area [kg/m2] */
(PID.TID 0000.0001)                 1.030000000000000E+03
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) drC =   /* C spacing ( units of r ) */
(PID.TID 0000.0001)     2 @  5.000000000000000E+00              /* K =  1:  2 */
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) drF =   /* W spacing ( units of r ) */
(PID.TID 0000.0001)                 1.000000000000000E+01       /* K =  1 */
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) delX = /* U spacing ( m - cartesian, degrees - spherical ) */
(PID.TID 0000.0001)    80 @  5.000000000000000E+03              /* I =  1: 80 */
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) delY = /* V spacing ( m - cartesian, degrees - spherical ) */
(PID.TID 0000.0001)    42 @  5.000000000000000E+03              /* J =  1: 42 */
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) xgOrigin = /* X-axis origin of West  edge (cartesian: m, lat-lon: deg) */
(PID.TID 0000.0001)                 0.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) ygOrigin = /* Y-axis origin of South edge (cartesian: m, lat-lon: deg) */
(PID.TID 0000.0001)                -1.100000000000000E+05
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) rSphere =  /* Radius ( ignored - cartesian, m - spherical ) */
(PID.TID 0000.0001)                 6.370000000000000E+06
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) deepAtmosphere = /* Deep/Shallow Atmosphere flag (True/False) */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) xC =  /* xC(:,1,:,1) : P-point X coord ( deg. or m if cartesian) */
(PID.TID 0000.0001)                 2.500000000000000E+03,      /* I =  1 */
(PID.TID 0000.0001)                 7.500000000000000E+03,      /* I =  2 */
(PID.TID 0000.0001)                 1.250000000000000E+04,      /* I =  3 */
(PID.TID 0000.0001)      . . .
(PID.TID 0000.0001)                 8.750000000000000E+04,      /* I = 18 */
(PID.TID 0000.0001)                 9.250000000000000E+04,      /* I = 19 */
(PID.TID 0000.0001)                 9.750000000000000E+04,      /* I = 20 */
(PID.TID 0000.0001)                 1.025000000000000E+05,      /* I = 21 */
(PID.TID 0000.0001)                 1.075000000000000E+05,      /* I = 22 */
(PID.TID 0000.0001)                 1.125000000000000E+05,      /* I = 23 */
(PID.TID 0000.0001)      . . .
(PID.TID 0000.0001)                 1.875000000000000E+05,      /* I = 38 */
(PID.TID 0000.0001)                 1.925000000000000E+05,      /* I = 39 */
(PID.TID 0000.0001)                 1.975000000000000E+05,      /* I = 40 */
(PID.TID 0000.0001)                 2.025000000000000E+05,      /* I = 41 */
(PID.TID 0000.0001)                 2.075000000000000E+05,      /* I = 42 */
(PID.TID 0000.0001)                 2.125000000000000E+05,      /* I = 43 */
(PID.TID 0000.0001)      . . .
(PID.TID 0000.0001)                 2.875000000000000E+05,      /* I = 58 */
(PID.TID 0000.0001)                 2.925000000000000E+05,      /* I = 59 */
(PID.TID 0000.0001)                 2.975000000000000E+05,      /* I = 60 */
(PID.TID 0000.0001)                 3.025000000000000E+05,      /* I = 61 */
(PID.TID 0000.0001)                 3.075000000000000E+05,      /* I = 62 */
(PID.TID 0000.0001)                 3.125000000000000E+05,      /* I = 63 */
(PID.TID 0000.0001)      . . .
(PID.TID 0000.0001)                 3.875000000000000E+05,      /* I = 78 */
(PID.TID 0000.0001)                 3.925000000000000E+05,      /* I = 79 */
(PID.TID 0000.0001)                 3.975000000000000E+05       /* I = 80 */
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) yC =  /* yC(1,:,1,:) : P-point Y coord ( deg. or m if cartesian) */
(PID.TID 0000.0001)                -1.075000000000000E+05,      /* J =  1 */
(PID.TID 0000.0001)                -1.025000000000000E+05,      /* J =  2 */
(PID.TID 0000.0001)                -9.750000000000000E+04,      /* J =  3 */
(PID.TID 0000.0001)                -9.250000000000000E+04,      /* J =  4 */
(PID.TID 0000.0001)                -8.750000000000000E+04,      /* J =  5 */
(PID.TID 0000.0001)                -8.250000000000000E+04,      /* J =  6 */
(PID.TID 0000.0001)                -7.750000000000000E+04,      /* J =  7 */
(PID.TID 0000.0001)                -7.250000000000000E+04,      /* J =  8 */
(PID.TID 0000.0001)                -6.750000000000000E+04,      /* J =  9 */
(PID.TID 0000.0001)                -6.250000000000000E+04,      /* J = 10 */
(PID.TID 0000.0001)                -5.750000000000000E+04,      /* J = 11 */
(PID.TID 0000.0001)                -5.250000000000000E+04,      /* J = 12 */
(PID.TID 0000.0001)                -4.750000000000000E+04,      /* J = 13 */
(PID.TID 0000.0001)                -4.250000000000000E+04,      /* J = 14 */
(PID.TID 0000.0001)                -3.750000000000000E+04,      /* J = 15 */
(PID.TID 0000.0001)                -3.250000000000000E+04,      /* J = 16 */
(PID.TID 0000.0001)                -2.750000000000000E+04,      /* J = 17 */
(PID.TID 0000.0001)                -2.250000000000000E+04,      /* J = 18 */
(PID.TID 0000.0001)                -1.750000000000000E+04,      /* J = 19 */
(PID.TID 0000.0001)                -1.250000000000000E+04,      /* J = 20 */
(PID.TID 0000.0001)                -7.500000000000000E+03,      /* J = 21 */
(PID.TID 0000.0001)                -2.500000000000000E+03,      /* J = 22 */
(PID.TID 0000.0001)                 2.500000000000000E+03,      /* J = 23 */
(PID.TID 0000.0001)                 7.500000000000000E+03,      /* J = 24 */
(PID.TID 0000.0001)                 1.250000000000000E+04,      /* J = 25 */
(PID.TID 0000.0001)                 1.750000000000000E+04,      /* J = 26 */
(PID.TID 0000.0001)                 2.250000000000000E+04,      /* J = 27 */
(PID.TID 0000.0001)                 2.750000000000000E+04,      /* J = 28 */
(PID.TID 0000.0001)                 3.250000000000000E+04,      /* J = 29 */
(PID.TID 0000.0001)                 3.750000000000000E+04,      /* J = 30 */
(PID.TID 0000.0001)                 4.250000000000000E+04,      /* J = 31 */
(PID.TID 0000.0001)                 4.750000000000000E+04,      /* J = 32 */
(PID.TID 0000.0001)                 5.250000000000000E+04,      /* J = 33 */
(PID.TID 0000.0001)                 5.750000000000000E+04,      /* J = 34 */
(PID.TID 0000.0001)                 6.250000000000000E+04,      /* J = 35 */
(PID.TID 0000.0001)                 6.750000000000000E+04,      /* J = 36 */
(PID.TID 0000.0001)                 7.250000000000000E+04,      /* J = 37 */
(PID.TID 0000.0001)                 7.750000000000000E+04,      /* J = 38 */
(PID.TID 0000.0001)                 8.250000000000000E+04,      /* J = 39 */
(PID.TID 0000.0001)                 8.750000000000000E+04,      /* J = 40 */
(PID.TID 0000.0001)                 9.250000000000000E+04,      /* J = 41 */
(PID.TID 0000.0001)                 9.750000000000000E+04       /* J = 42 */
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) rcoord = /* P-point R coordinate (  units of r ) */
(PID.TID 0000.0001)                -5.000000000000000E+00       /* K =  1 */
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) rF =   /* W-Interf. R coordinate (  units of r ) */
(PID.TID 0000.0001)                 0.000000000000000E+00,      /* K =  1 */
(PID.TID 0000.0001)                -1.000000000000000E+01       /* K =  2 */
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) deepFacC = /* deep-model grid factor @ cell-Center (-) */
(PID.TID 0000.0001)                 1.000000000000000E+00       /* K =  1 */
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) deepFacF = /* deep-model grid factor @ W-Interface (-) */
(PID.TID 0000.0001)     2 @  1.000000000000000E+00              /* K =  1:  2 */
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) rVel2wUnit = /* convert units: rVel -> wSpeed (=1 if z-coord)*/
(PID.TID 0000.0001)     2 @  1.000000000000000E+00              /* K =  1:  2 */
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) wUnit2rVel = /* convert units: wSpeed -> rVel (=1 if z-coord)*/
(PID.TID 0000.0001)     2 @  1.000000000000000E+00              /* K =  1:  2 */
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) dBdrRef = /* Vertical grad. of reference buoyancy [(m/s/r)^2] */
(PID.TID 0000.0001)                 0.000000000000000E+00       /* K =  1 */
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) rotateGrid = /* use rotated grid ( True/False ) */
(PID.TID 0000.0001)                   F
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) phiEuler = /* Euler angle, rotation about original z-coordinate [rad] */
(PID.TID 0000.0001)                 0.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) thetaEuler = /* Euler angle, rotation about new x-coordinate [rad] */
(PID.TID 0000.0001)                 0.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) psiEuler = /* Euler angle, rotation about new z-coordinate [rad] */
(PID.TID 0000.0001)                 0.000000000000000E+00
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) dxF =  /* dxF(:,1,:,1) ( units: m ) */
(PID.TID 0000.0001)    80 @  5.000000000000000E+03              /* I =  1: 80 */
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) dxF =  /* dxF(1,:,1,:) ( units: m ) */
(PID.TID 0000.0001)    42 @  5.000000000000000E+03              /* J =  1: 42 */
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) dyF =  /* dyF(:,1,:,1) ( units: m ) */
(PID.TID 0000.0001)    80 @  5.000000000000000E+03              /* I =  1: 80 */
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) dyF =  /* dyF(1,:,1,:) ( units: m ) */
(PID.TID 0000.0001)    42 @  5.000000000000000E+03              /* J =  1: 42 */
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) dxG =  /* dxG(:,1,:,1) ( units: m ) */
(PID.TID 0000.0001)    80 @  5.000000000000000E+03              /* I =  1: 80 */
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) dxG =  /* dxG(1,:,1,:) ( units: m ) */
(PID.TID 0000.0001)    42 @  5.000000000000000E+03              /* J =  1: 42 */
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) dyG =  /* dyG(:,1,:,1) ( units: m ) */
(PID.TID 0000.0001)    80 @  5.000000000000000E+03              /* I =  1: 80 */
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) dyG =  /* dyG(1,:,1,:) ( units: m ) */
(PID.TID 0000.0001)    42 @  5.000000000000000E+03              /* J =  1: 42 */
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) dxC =  /* dxC(:,1,:,1) ( units: m ) */
(PID.TID 0000.0001)    80 @  5.000000000000000E+03              /* I =  1: 80 */
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) dxC =  /* dxC(1,:,1,:) ( units: m ) */
(PID.TID 0000.0001)    42 @  5.000000000000000E+03              /* J =  1: 42 */
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) dyC =  /* dyC(:,1,:,1) ( units: m ) */
(PID.TID 0000.0001)    80 @  5.000000000000000E+03              /* I =  1: 80 */
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) dyC =  /* dyC(1,:,1,:) ( units: m ) */
(PID.TID 0000.0001)    42 @  5.000000000000000E+03              /* J =  1: 42 */
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) dxV =  /* dxV(:,1,:,1) ( units: m ) */
(PID.TID 0000.0001)    80 @  5.000000000000000E+03              /* I =  1: 80 */
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) dxV =  /* dxV(1,:,1,:) ( units: m ) */
(PID.TID 0000.0001)    42 @  5.000000000000000E+03              /* J =  1: 42 */
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) dyU =  /* dyU(:,1,:,1) ( units: m ) */
(PID.TID 0000.0001)    80 @  5.000000000000000E+03              /* I =  1: 80 */
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) dyU =  /* dyU(1,:,1,:) ( units: m ) */
(PID.TID 0000.0001)    42 @  5.000000000000000E+03              /* J =  1: 42 */
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) rA  =  /* rA (:,1,:,1) ( units: m^2 ) */
(PID.TID 0000.0001)    80 @  2.500000000000000E+07              /* I =  1: 80 */
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) rA  =  /* rA (1,:,1,:) ( units: m^2 ) */
(PID.TID 0000.0001)    42 @  2.500000000000000E+07              /* J =  1: 42 */
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) rAw =  /* rAw(:,1,:,1) ( units: m^2 ) */
(PID.TID 0000.0001)    80 @  2.500000000000000E+07              /* I =  1: 80 */
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) rAw =  /* rAw(1,:,1,:) ( units: m^2 ) */
(PID.TID 0000.0001)    42 @  2.500000000000000E+07              /* J =  1: 42 */
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) rAs =  /* rAs(:,1,:,1) ( units: m^2 ) */
(PID.TID 0000.0001)    80 @  2.500000000000000E+07              /* I =  1: 80 */
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) rAs =  /* rAs(1,:,1,:) ( units: m^2 ) */
(PID.TID 0000.0001)    42 @  2.500000000000000E+07              /* J =  1: 42 */
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) globalArea = /* Integrated horizontal Area (m^2) */
(PID.TID 0000.0001)                 6.950000000000000E+10
(PID.TID 0000.0001)     ;
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // End of Model config. summary
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) 
(PID.TID 0000.0001) == Packages configuration : Check & print summary ==
(PID.TID 0000.0001) 
(PID.TID 0000.0001) EXF_CHECK: #define ALLOW_EXF
(PID.TID 0000.0001) SEAICE_CHECK: #define ALLOW_SEAICE
(PID.TID 0000.0001) THSICE_CHECK: #define THSICE
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // Check Model config. (CONFIG_CHECK):
(PID.TID 0000.0001) // CONFIG_CHECK : Normal End
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) 
(PID.TID 0000.0001)  MDS_READ_FIELD: opening global file: uVel_3c0.bin
(PID.TID 0000.0001)  MDS_READ_FIELD: opening global file: vVel_3c0.bin
(PID.TID 0000.0001)  MDS_READ_FIELD: opening global file: eta_3c0.bin
(PID.TID 0000.0001) Start initial hydrostatic pressure computation
(PID.TID 0000.0001) Pressure is predetermined for buoyancyRelation OCEANIC
(PID.TID 0000.0001) 
(PID.TID 0000.0001)  write diagnostics summary to file ioUnit:      6
Iter.Nb:         0 ; Time(s):  0.0000000000000E+00
------------------------------------------------------------------------
2D/3D diagnostics: Number of lists:     1
------------------------------------------------------------------------
listId=    1 ; file name: snapshot
 nFlds, nActive,       freq     &     phase        , nLev               
    5  |    5  |    -86400.000000      3600.000000 |   1
 levels:   1
 diag# | name   |   ipt  |  iMate | kLev|   count |   mate.C|           
   155 |SIuice  |      1 |      2 |   1 |       0 |       0 |
   156 |SIvice  |      2 |      1 |   1 |       0 |       0 |
   149 |SIheff  |      3 |      0 |   1 |       0 |
   216 |SI_Fract|      4 |      0 |   1 |       0 |
   217 |SI_Thick|      5 |      4 |   1 |       0 |       0 |
------------------------------------------------------------------------
Global & Regional Statistics diagnostics: Number of lists:     1
------------------------------------------------------------------------
listId=   1 ; file name: iceStDiag
 nFlds, nActive,       freq     &     phase        |                    
    6  |    6  |      7200.000000      1800.000000 |
 Regions:   0
 diag# | name   |   ipt  |  iMate |    Volume   |   mate-Vol. |         
   216 |SI_Fract|      1 |      0 | 0.00000E+00 |
   217 |SI_Thick|      2 |      1 | 0.00000E+00 | 0.00000E+00 |
   146 |SIarea  |      3 |      0 | 0.00000E+00 |
   149 |SIheff  |      4 |      0 | 0.00000E+00 |
   155 |SIuice  |      5 |      0 | 0.00000E+00 |
   156 |SIvice  |      6 |      0 | 0.00000E+00 |
------------------------------------------------------------------------
(PID.TID 0000.0001)  MDS_READ_FIELD: opening global file: windx.bin
(PID.TID 0000.0001)  MDS_READ_FIELD: opening global file: const100.bin
(PID.TID 0000.0001)  MDS_READ_FIELD: opening global file: const+20.bin
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // Model current state
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) 
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // Begin MONITOR dynamic field statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) %MON time_tsnumber                =                     0
(PID.TID 0000.0001) %MON time_secondsf                =   0.0000000000000E+00
(PID.TID 0000.0001) %MON dynstat_eta_max              =   1.4855271423662E-02
(PID.TID 0000.0001) %MON dynstat_eta_min              =  -1.5547625271979E-02
(PID.TID 0000.0001) %MON dynstat_eta_mean             =  -6.8609663050809E-19
(PID.TID 0000.0001) %MON dynstat_eta_sd               =   5.6185276903544E-03
(PID.TID 0000.0001) %MON dynstat_eta_del2             =   3.4210904025025E-06
(PID.TID 0000.0001) %MON dynstat_uvel_max             =   5.4694595665363E-01
(PID.TID 0000.0001) %MON dynstat_uvel_min             =   8.1797628424127E-02
(PID.TID 0000.0001) %MON dynstat_uvel_mean            =   3.2603530929361E-01
(PID.TID 0000.0001) %MON dynstat_uvel_sd              =   8.4661197148990E-02
(PID.TID 0000.0001) %MON dynstat_uvel_del2            =   1.3392731599312E-04
(PID.TID 0000.0001) %MON dynstat_vvel_max             =   2.2780617104059E-01
(PID.TID 0000.0001) %MON dynstat_vvel_min             =  -1.4793000868950E-01
(PID.TID 0000.0001) %MON dynstat_vvel_mean            =  -3.2450632095700E-04
(PID.TID 0000.0001) %MON dynstat_vvel_sd              =   6.0970835295293E-02
(PID.TID 0000.0001) %MON dynstat_vvel_del2            =   8.1836652323282E-05
(PID.TID 0000.0001) %MON dynstat_wvel_max             =   1.6555698845343E-04
(PID.TID 0000.0001) %MON dynstat_wvel_min             =  -2.4393468746960E-04
(PID.TID 0000.0001) %MON dynstat_wvel_mean            =  -1.8006686469634E-21
(PID.TID 0000.0001) %MON dynstat_wvel_sd              =   1.8006622332191E-05
(PID.TID 0000.0001) %MON dynstat_wvel_del2            =   3.4047422448573E-07
(PID.TID 0000.0001) %MON dynstat_theta_max            =  -1.6200000000000E+00
(PID.TID 0000.0001) %MON dynstat_theta_min            =  -1.6200000000000E+00
(PID.TID 0000.0001) %MON dynstat_theta_mean           =  -1.6200000000000E+00
(PID.TID 0000.0001) %MON dynstat_theta_sd             =   0.0000000000000E+00
(PID.TID 0000.0001) %MON dynstat_theta_del2           =   0.0000000000000E+00
(PID.TID 0000.0001) %MON dynstat_salt_max             =   3.0000000000000E+01
(PID.TID 0000.0001) %MON dynstat_salt_min             =   3.0000000000000E+01
(PID.TID 0000.0001) %MON dynstat_salt_mean            =   3.0000000000000E+01
(PID.TID 0000.0001) %MON dynstat_salt_sd              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON dynstat_salt_del2            =   0.0000000000000E+00
(PID.TID 0000.0001) %MON trAdv_CFL_u_max              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON trAdv_CFL_v_max              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON trAdv_CFL_w_max              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON advcfl_uvel_max              =   1.9690054439531E-01
(PID.TID 0000.0001) %MON advcfl_vvel_max              =   8.2010221574612E-02
(PID.TID 0000.0001) %MON advcfl_wvel_max              =   8.7816487489057E-02
(PID.TID 0000.0001) %MON advcfl_W_hf_max              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON pe_b_mean                    =   1.5484032096270E-05
(PID.TID 0000.0001) %MON ke_max                       =   1.4564487757410E-01
(PID.TID 0000.0001) %MON ke_mean                      =   5.8130401708830E-02
(PID.TID 0000.0001) %MON ke_vol                       =   6.9500000000000E+11
(PID.TID 0000.0001) %MON vort_r_min                   =  -1.4191202448594E-04
(PID.TID 0000.0001) %MON vort_r_max                   =   8.9657385579761E-05
(PID.TID 0000.0001) %MON vort_a_mean                  =  -6.5586096803907E-22
(PID.TID 0000.0001) %MON vort_a_sd                    =   1.5889649807104E-05
(PID.TID 0000.0001) %MON vort_p_mean                  =  -6.8228760045090E-22
(PID.TID 0000.0001) %MON vort_p_sd                    =   3.0669223294758E-05
(PID.TID 0000.0001) %MON surfExpan_theta_mean         =  -1.4394880171946E-21
(PID.TID 0000.0001) %MON surfExpan_salt_mean          =   1.6750406018264E-20
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // End MONITOR dynamic field statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // Begin MONITOR SEAICE statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) %MON seaice_tsnumber              =                     0
(PID.TID 0000.0001) %MON seaice_time_sec              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON seaice_uice_max              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON seaice_uice_min              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON seaice_uice_mean             =   0.0000000000000E+00
(PID.TID 0000.0001) %MON seaice_uice_sd               =   0.0000000000000E+00
(PID.TID 0000.0001) %MON seaice_uice_del2             =   0.0000000000000E+00
(PID.TID 0000.0001) %MON seaice_vice_max              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON seaice_vice_min              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON seaice_vice_mean             =   0.0000000000000E+00
(PID.TID 0000.0001) %MON seaice_vice_sd               =   0.0000000000000E+00
(PID.TID 0000.0001) %MON seaice_vice_del2             =   0.0000000000000E+00
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // End MONITOR SEAICE statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // Begin MONITOR Therm.SeaIce statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) %MON thSI_time_sec                =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Ice_Area_G              =   6.9500000000000E+10
(PID.TID 0000.0001) %MON thSI_Ice_Area_S              =   2.9500000000000E+10
(PID.TID 0000.0001) %MON thSI_Ice_Area_N              =   4.0000000000000E+10
(PID.TID 0000.0001) %MON thSI_IceH_ave_G              =   2.0000000000000E-01
(PID.TID 0000.0001) %MON thSI_IceH_ave_S              =   2.0000000000000E-01
(PID.TID 0000.0001) %MON thSI_IceH_ave_N              =   2.0000000000000E-01
(PID.TID 0000.0001) %MON thSI_IceH_max_S              =   2.0000000000000E-01
(PID.TID 0000.0001) %MON thSI_IceH_max_N              =   2.0000000000000E-01
(PID.TID 0000.0001) %MON thSI_SnwH_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_min_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_min_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_min_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_min_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_min_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_min_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_TotEnerg_G              =  -4.1574014390118E+18
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // End MONITOR Therm.SeaIce statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // Begin MONITOR EXF statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) %MON exf_tsnumber                 =                     0
(PID.TID 0000.0001) %MON exf_time_sec                 =   0.0000000000000E+00
(PID.TID 0000.0001) %MON exf_ustress_max              =   1.3964039188763E-01
(PID.TID 0000.0001) %MON exf_ustress_min              =   1.3964039188763E-01
(PID.TID 0000.0001) %MON exf_ustress_mean             =   1.3964039188763E-01
(PID.TID 0000.0001) %MON exf_ustress_sd               =   5.5511151231258E-17
(PID.TID 0000.0001) %MON exf_ustress_del2             =   0.0000000000000E+00
(PID.TID 0000.0001) %MON exf_vstress_max              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON exf_vstress_min              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON exf_vstress_mean             =   0.0000000000000E+00
(PID.TID 0000.0001) %MON exf_vstress_sd               =   0.0000000000000E+00
(PID.TID 0000.0001) %MON exf_vstress_del2             =   0.0000000000000E+00
(PID.TID 0000.0001) %MON exf_hflux_max                =   1.3256147102117E+02
(PID.TID 0000.0001) %MON exf_hflux_min                =   1.3256147102117E+02
(PID.TID 0000.0001) %MON exf_hflux_mean               =   1.3256147102117E+02
(PID.TID 0000.0001) %MON exf_hflux_sd                 =   9.6633812063374E-13
(PID.TID 0000.0001) %MON exf_hflux_del2               =   7.8352778346434E-01
(PID.TID 0000.0001) %MON exf_sflux_max                =   5.8259080752307E-08
(PID.TID 0000.0001) %MON exf_sflux_min                =   5.8259080752307E-08
(PID.TID 0000.0001) %MON exf_sflux_mean               =   5.8259080752308E-08
(PID.TID 0000.0001) %MON exf_sflux_sd                 =   8.7350272685600E-22
(PID.TID 0000.0001) %MON exf_sflux_del2               =   3.4435049684410E-10
(PID.TID 0000.0001) %MON exf_uwind_max                =   1.0000000000000E+01
(PID.TID 0000.0001) %MON exf_uwind_min                =   1.0000000000000E+01
(PID.TID 0000.0001) %MON exf_uwind_mean               =   1.0000000000000E+01
(PID.TID 0000.0001) %MON exf_uwind_sd                 =   0.0000000000000E+00
(PID.TID 0000.0001) %MON exf_uwind_del2               =   5.9106750809910E-02
(PID.TID 0000.0001) %MON exf_vwind_max                =   0.0000000000000E+00
(PID.TID 0000.0001) %MON exf_vwind_min                =   0.0000000000000E+00
(PID.TID 0000.0001) %MON exf_vwind_mean               =   0.0000000000000E+00
(PID.TID 0000.0001) %MON exf_vwind_sd                 =   0.0000000000000E+00
(PID.TID 0000.0001) %MON exf_vwind_del2               =   0.0000000000000E+00
(PID.TID 0000.0001) %MON exf_wspeed_max               =   1.0000000000000E+01
(PID.TID 0000.0001) %MON exf_wspeed_min               =   1.0000000000000E+01
(PID.TID 0000.0001) %MON exf_wspeed_mean              =   1.0000000000000E+01
(PID.TID 0000.0001) %MON exf_wspeed_sd                =   0.0000000000000E+00
(PID.TID 0000.0001) %MON exf_wspeed_del2              =   5.9106750809910E-02
(PID.TID 0000.0001) %MON exf_evap_max                 =   5.8259080752307E-08
(PID.TID 0000.0001) %MON exf_evap_min                 =   5.8259080752307E-08
(PID.TID 0000.0001) %MON exf_evap_mean                =   5.8259080752308E-08
(PID.TID 0000.0001) %MON exf_evap_sd                  =   8.7350272685600E-22
(PID.TID 0000.0001) %MON exf_evap_del2                =   3.4435049684410E-10
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // End MONITOR EXF statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       1      1 0.99000E+00 0.95257E+00
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      1 /      1, Nb. of FGMRES iterations =      2
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       2      2 0.99000E+00 0.94494E+00
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      2 /      2, Nb. of FGMRES iterations =      4
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       3      3 0.99000E+00 0.92786E+00
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      3 /      3, Nb. of FGMRES iterations =      3
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       4      4 0.99000E+00 0.88282E+00
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      4 /      4, Nb. of FGMRES iterations =      1
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       5      5 0.99000E+00 0.85280E+00
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      5 /      5, Nb. of FGMRES iterations =      1
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       6      6 0.99000E+00 0.80647E+00
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      6 /      6, Nb. of FGMRES iterations =      1
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       7      7 0.99000E+00 0.66263E+00
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      7 /      7, Nb. of FGMRES iterations =      1
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       8      8 0.56408E+00 0.45238E+00
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      8 /      8, Nb. of FGMRES iterations =      2
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       9      9 0.53059E+00 0.29649E+00
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      9 /      9, Nb. of FGMRES iterations =      4
(PID.TID 0000.0001)  S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc =       9      1 0.10000E+01 0.29649E+00 0.79581E+00
(PID.TID 0000.0001)  S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc =       9      2-0.50000E+00 0.29649E+00 0.32588E+00
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      10     10 0.92759E+00 0.28199E+00
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     10 /     10, Nb. of FGMRES iterations =      1
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      11     11 0.63270E+00 0.20783E+00
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     11 /     11, Nb. of FGMRES iterations =      4
(PID.TID 0000.0001)  S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc =      11      1 0.10000E+01 0.20783E+00 0.33865E+00
(PID.TID 0000.0001)  S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc =      11      2-0.50000E+00 0.20783E+00 0.23346E+00
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      12     12 0.97211E+00 0.20395E+00
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     12 /     12, Nb. of FGMRES iterations =      1
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      13     13 0.49074E+00 0.12689E+00
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     13 /     13, Nb. of FGMRES iterations =      3
(PID.TID 0000.0001)  S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc =      13      1 0.10000E+01 0.12689E+00 0.17531E+00
(PID.TID 0000.0001)  S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc =      13      2-0.50000E+00 0.12689E+00 0.13504E+00
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      14     14 0.89031E+00 0.11743E+00
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     14 /     14, Nb. of FGMRES iterations =      1
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      15     15 0.53957E+00 0.77829E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     15 /     15, Nb. of FGMRES iterations =      4
(PID.TID 0000.0001)  S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc =      15      1 0.10000E+01 0.77829E-01 0.12587E+00
(PID.TID 0000.0001)  S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc =      15      2-0.50000E+00 0.77829E-01 0.10609E+00
(PID.TID 0000.0001)  S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc =      15      3-0.25000E+00 0.77829E-01 0.83296E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      16     16 0.95694E+00 0.75578E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     16 /     16, Nb. of FGMRES iterations =      1
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      17     17 0.67109E+00 0.57932E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     17 /     17, Nb. of FGMRES iterations =      4
(PID.TID 0000.0001)  S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc =      17      1 0.10000E+01 0.57932E-01 0.10549E+00
(PID.TID 0000.0001)  S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc =      17      2-0.50000E+00 0.57932E-01 0.78424E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      18     18 0.83612E+00 0.51416E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     18 /     18, Nb. of FGMRES iterations =      3
(PID.TID 0000.0001)  S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc =      18      1 0.10000E+01 0.51416E-01 0.83723E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      19     19 0.99000E+00 0.51384E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     19 /     19, Nb. of FGMRES iterations =      1
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      20     20 0.93637E+00 0.49181E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     20 /     20, Nb. of FGMRES iterations =      3
(PID.TID 0000.0001)  S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc =      20      1 0.10000E+01 0.49181E-01 0.57984E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc =      20      2-0.50000E+00 0.49181E-01 0.52909E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc =      20      3-0.25000E+00 0.49181E-01 0.49655E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      21     21 0.92326E+00 0.46631E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     21 /     21, Nb. of FGMRES iterations =      3
(PID.TID 0000.0001)  S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc =      21      1 0.10000E+01 0.46631E-01 0.50808E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      22     22 0.92518E+00 0.44275E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     22 /     22, Nb. of FGMRES iterations =      4
(PID.TID 0000.0001)  S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc =      22      1 0.10000E+01 0.44275E-01 0.62667E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc =      22      2-0.50000E+00 0.44275E-01 0.45681E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      23     23 0.88631E+00 0.40853E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     23 /     23, Nb. of FGMRES iterations =      5
(PID.TID 0000.0001)  S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc =      23      1 0.10000E+01 0.40853E-01 0.90477E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc =      23      2-0.50000E+00 0.40853E-01 0.47358E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      24     24 0.86224E+00 0.37009E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     24 /     24, Nb. of FGMRES iterations =      3
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      25     25 0.86842E+00 0.33687E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     25 /     25, Nb. of FGMRES iterations =      2
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      26     26 0.83905E+00 0.29968E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     26 /     26, Nb. of FGMRES iterations =      3
(PID.TID 0000.0001)  S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc =      26      1 0.10000E+01 0.29968E-01 0.82032E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc =      26      2-0.50000E+00 0.29968E-01 0.53596E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      27     27 0.84970E+00 0.26884E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     27 /     27, Nb. of FGMRES iterations =      3
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      28     28 0.78970E+00 0.22969E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     28 /     28, Nb. of FGMRES iterations =      4
(PID.TID 0000.0001)  S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc =      28      1 0.10000E+01 0.22969E-01 0.78705E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc =      28      2-0.50000E+00 0.22969E-01 0.44619E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      29     29 0.75454E+00 0.19037E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     29 /     29, Nb. of FGMRES iterations =      4
(PID.TID 0000.0001)  S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc =      29      1 0.10000E+01 0.19037E-01 0.30469E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      30     30 0.77822E+00 0.16106E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     30 /     30, Nb. of FGMRES iterations =      4
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      31     31 0.95161E+00 0.15583E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     31 /     31, Nb. of FGMRES iterations =      1
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      32     32 0.63189E+00 0.11474E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     32 /     32, Nb. of FGMRES iterations =      6
(PID.TID 0000.0001)  S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc =      32      1 0.10000E+01 0.11474E-01 0.19611E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      33     33 0.57649E+00 0.79480E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     33 /     33, Nb. of FGMRES iterations =      6
(PID.TID 0000.0001)  S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc =      33      1 0.10000E+01 0.79480E-02 0.25390E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      34     34 0.63815E+00 0.58913E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     34 /     34, Nb. of FGMRES iterations =      6
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      35     35 0.54517E+00 0.39316E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     35 /     35, Nb. of FGMRES iterations =      7
(PID.TID 0000.0001)  S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc =      35      1 0.10000E+01 0.39316E-02 0.17029E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      36     36 0.60244E+00 0.28044E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     36 /     36, Nb. of FGMRES iterations =      6
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      37     37 0.47472E+00 0.17066E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     37 /     37, Nb. of FGMRES iterations =      9
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      38     38 0.61312E+00 0.12317E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     38 /     38, Nb. of FGMRES iterations =      2
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      39     39 0.37625E+00 0.64192E-03
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     39 /     39, Nb. of FGMRES iterations =     10
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      40     40 0.18525E+00 0.20860E-03
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     40 /     40, Nb. of FGMRES iterations =     16
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      41     41 0.10000E+00 0.37929E-04
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     41 /     41, Nb. of FGMRES iterations =     21
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      42     42 0.10000E+00 0.34630E-05
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     42 /     42, Nb. of FGMRES iterations =     20
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      43     43 0.10000E+00 0.30511E-06
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     43 /     43, Nb. of FGMRES iterations =     21
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      44     44 0.10000E+00 0.29498E-07
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     44 /     44, Nb. of FGMRES iterations =     20
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      45     45 0.10000E+00 0.27135E-08
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     45 /     45, Nb. of FGMRES iterations =     21
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  // Begin JFNK statistics
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  %JFNK_MON: time step              =          1
(PID.TID 0000.0001)  %JFNK_MON: Nb. of time steps      =          1
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Newton steps    =         46
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Krylov steps    =        252
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Newton failures =          0
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Krylov failures =          0
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  // End JFNK statistics
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Total number FGMRES iterations =    252 in timestep          1
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // Begin MONITOR SEAICE statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) %MON seaice_tsnumber              =                     1
(PID.TID 0000.0001) %MON seaice_time_sec              =   1.8000000000000E+03
(PID.TID 0000.0001) %MON seaice_uice_max              =   6.4469148712937E-01
(PID.TID 0000.0001) %MON seaice_uice_min              =   2.9707526058168E-01
(PID.TID 0000.0001) %MON seaice_uice_mean             =   5.0383761741364E-01
(PID.TID 0000.0001) %MON seaice_uice_sd               =   7.3544520414918E-02
(PID.TID 0000.0001) %MON seaice_uice_del2             =   6.3785121229547E-05
(PID.TID 0000.0001) %MON seaice_vice_max              =   1.2260045119874E-01
(PID.TID 0000.0001) %MON seaice_vice_min              =  -1.0442956369857E-01
(PID.TID 0000.0001) %MON seaice_vice_mean             =  -7.0041174816866E-04
(PID.TID 0000.0001) %MON seaice_vice_sd               =   4.4864795328084E-02
(PID.TID 0000.0001) %MON seaice_vice_del2             =   3.5138378984371E-05
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // End MONITOR SEAICE statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // Begin MONITOR Therm.SeaIce statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) %MON thSI_time_sec                =   1.8000000000000E+03
(PID.TID 0000.0001) %MON thSI_Ice_Area_G              =   6.9436214346382E+10
(PID.TID 0000.0001) %MON thSI_Ice_Area_S              =   2.9439572384162E+10
(PID.TID 0000.0001) %MON thSI_Ice_Area_N              =   3.9996641962221E+10
(PID.TID 0000.0001) %MON thSI_IceH_ave_G              =   2.0018372445623E-01
(PID.TID 0000.0001) %MON thSI_IceH_ave_S              =   2.0040922445323E-01
(PID.TID 0000.0001) %MON thSI_IceH_ave_N              =   2.0001774493498E-01
(PID.TID 0000.0001) %MON thSI_IceH_max_S              =   2.2747719811368E-01
(PID.TID 0000.0001) %MON thSI_IceH_max_N              =   2.0012174310763E-01
(PID.TID 0000.0001) %MON thSI_SnwH_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_min_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_min_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_min_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_min_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_min_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_min_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_TotEnerg_G              =  -4.1574014390118E+18
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // End MONITOR Therm.SeaIce statistics
(PID.TID 0000.0001) // =======================================================
 Compute Stats, Diag. #    216  SI_Fract  vol(   0 ): 6.950E+10  Parms: SM P    M1      
 Compute Stats, Diag. #    217  SI_Thick  vol(   0 ): 6.950E+10  Parms: SM PC   M1      
    use Counter Mate  #    216  SI_Fract  vol(   0 ): 6.950E+10 integral 6.950E+10
 Compute Stats, Diag. #    146  SIarea    vol(   0 ): 6.950E+10  Parms: SM      M1      
 Compute Stats, Diag. #    149  SIheff    vol(   0 ): 6.950E+10  Parms: SM      M1      
 Compute Stats, Diag. #    155  SIuice    vol(   0 ): 6.900E+10  Parms: UU      M1      
 Compute Stats, Diag. #    156  SIvice    vol(   0 ): 6.750E+10  Parms: VV      M1      
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       1    201 0.99000E+00 0.55659E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      1 /    201, Nb. of FGMRES iterations =      1
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       2    202 0.99000E+00 0.52861E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      2 /    202, Nb. of FGMRES iterations =      2
(PID.TID 0000.0001)  S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc =       2      1 0.10000E+01 0.52861E-01 0.52945E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       3    203 0.99000E+00 0.51272E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      3 /    203, Nb. of FGMRES iterations =      2
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       4    204 0.99000E+00 0.50767E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      4 /    204, Nb. of FGMRES iterations =      3
(PID.TID 0000.0001)  S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc =       4      1 0.10000E+01 0.50767E-01 0.55278E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       5    205 0.99000E+00 0.50031E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      5 /    205, Nb. of FGMRES iterations =      2
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       6    206 0.99000E+00 0.49437E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      6 /    206, Nb. of FGMRES iterations =      3
(PID.TID 0000.0001)  S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc =       6      1 0.10000E+01 0.49437E-01 0.54225E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       7    207 0.99000E+00 0.48944E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      7 /    207, Nb. of FGMRES iterations =      3
(PID.TID 0000.0001)  S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc =       7      1 0.10000E+01 0.48944E-01 0.53504E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       8    208 0.99000E+00 0.47759E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      8 /    208, Nb. of FGMRES iterations =      3
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       9    209 0.99000E+00 0.46773E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      9 /    209, Nb. of FGMRES iterations =      3
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      10    210 0.99000E+00 0.46154E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     10 /    210, Nb. of FGMRES iterations =      4
(PID.TID 0000.0001)  S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc =      10      1 0.10000E+01 0.46154E-01 0.57641E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      11    211 0.99000E+00 0.43320E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     11 /    211, Nb. of FGMRES iterations =      4
(PID.TID 0000.0001)  S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc =      11      1 0.10000E+01 0.43320E-01 0.44029E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      12    212 0.99000E+00 0.41375E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     12 /    212, Nb. of FGMRES iterations =      4
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      13    213 0.99000E+00 0.39767E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     13 /    213, Nb. of FGMRES iterations =      3
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      14    214 0.99000E+00 0.39269E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     14 /    214, Nb. of FGMRES iterations =      3
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      15    215 0.99000E+00 0.38815E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     15 /    215, Nb. of FGMRES iterations =      4
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      16    216 0.99000E+00 0.35831E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     16 /    216, Nb. of FGMRES iterations =      1
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      17    217 0.99000E+00 0.35170E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     17 /    217, Nb. of FGMRES iterations =      3
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      18    218 0.99000E+00 0.32615E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     18 /    218, Nb. of FGMRES iterations =      1
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      19    219 0.99000E+00 0.32091E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     19 /    219, Nb. of FGMRES iterations =      1
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      20    220 0.99000E+00 0.30099E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     20 /    220, Nb. of FGMRES iterations =      4
(PID.TID 0000.0001)  S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc =      20      1 0.10000E+01 0.30099E-01 0.56155E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      21    221 0.99000E+00 0.28621E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     21 /    221, Nb. of FGMRES iterations =      1
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      22    222 0.99000E+00 0.27878E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     22 /    222, Nb. of FGMRES iterations =      2
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      23    223 0.90337E+00 0.26051E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     23 /    223, Nb. of FGMRES iterations =      4
(PID.TID 0000.0001)  S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc =      23      1 0.10000E+01 0.26051E-01 0.46706E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc =      23      2-0.50000E+00 0.26051E-01 0.26141E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      24    224 0.84175E+00 0.23225E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     24 /    224, Nb. of FGMRES iterations =      4
(PID.TID 0000.0001)  S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc =      24      1 0.10000E+01 0.23225E-01 0.69838E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc =      24      2-0.50000E+00 0.23225E-01 0.30371E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      25    225 0.83969E+00 0.20671E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     25 /    225, Nb. of FGMRES iterations =      4
(PID.TID 0000.0001)  S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc =      25      1 0.10000E+01 0.20671E-01 0.65908E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc =      25      2-0.50000E+00 0.20671E-01 0.41894E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      26    226 0.82316E+00 0.18156E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     26 /    226, Nb. of FGMRES iterations =      4
(PID.TID 0000.0001)  S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc =      26      1 0.10000E+01 0.18156E-01 0.59193E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc =      26      2-0.50000E+00 0.18156E-01 0.32825E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      27    227 0.82842E+00 0.16015E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     27 /    227, Nb. of FGMRES iterations =      4
(PID.TID 0000.0001)  S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc =      27      1 0.10000E+01 0.16015E-01 0.50116E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      28    228 0.78806E+00 0.13664E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     28 /    228, Nb. of FGMRES iterations =      4
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      29    229 0.68543E+00 0.10622E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     29 /    229, Nb. of FGMRES iterations =      4
(PID.TID 0000.0001)  S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc =      29      1 0.10000E+01 0.10622E-01 0.50737E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      30    230 0.67124E+00 0.81431E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     30 /    230, Nb. of FGMRES iterations =      6
(PID.TID 0000.0001)  S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc =      30      1 0.10000E+01 0.81431E-02 0.83614E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      31    231 0.64610E+00 0.60858E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     31 /    231, Nb. of FGMRES iterations =      6
(PID.TID 0000.0001)  S/R SEAICE_JFNK_UPDATE: Newton iter, LSiter, facLS, JFNKresidual, resLoc =      31      1 0.10000E+01 0.60858E-02 0.19039E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      32    232 0.60667E+00 0.43614E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     32 /    232, Nb. of FGMRES iterations =      6
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      33    233 0.56878E+00 0.29940E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     33 /    233, Nb. of FGMRES iterations =      7
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      34    234 0.60569E+00 0.21433E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     34 /    234, Nb. of FGMRES iterations =      3
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      35    235 0.44617E+00 0.12515E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     35 /    235, Nb. of FGMRES iterations =      8
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      36    236 0.31672E+00 0.58148E-03
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     36 /    236, Nb. of FGMRES iterations =     13
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      37    237 0.20500E+00 0.20216E-03
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     37 /    237, Nb. of FGMRES iterations =     11
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      38    238 0.10000E+00 0.31361E-04
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     38 /    238, Nb. of FGMRES iterations =     17
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      39    239 0.10000E+00 0.29676E-05
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     39 /    239, Nb. of FGMRES iterations =     18
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      40    240 0.10000E+00 0.21988E-06
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     40 /    240, Nb. of FGMRES iterations =     19
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      41    241 0.10000E+00 0.13926E-07
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     41 /    241, Nb. of FGMRES iterations =     19
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      42    242 0.10000E+00 0.11606E-08
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     42 /    242, Nb. of FGMRES iterations =     20
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      43    243 0.10000E+00 0.96750E-10
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     43 /    243, Nb. of FGMRES iterations =     20
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  // Begin JFNK statistics
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  %JFNK_MON: time step              =          2
(PID.TID 0000.0001)  %JFNK_MON: Nb. of time steps      =          1
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Newton steps    =         44
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Krylov steps    =        258
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Newton failures =          0
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Krylov failures =          0
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  // End JFNK statistics
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Total number FGMRES iterations =    258 in timestep          2
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // Begin MONITOR SEAICE statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) %MON seaice_tsnumber              =                     2
(PID.TID 0000.0001) %MON seaice_time_sec              =   3.6000000000000E+03
(PID.TID 0000.0001) %MON seaice_uice_max              =   6.8743384244851E-01
(PID.TID 0000.0001) %MON seaice_uice_min              =   3.1434267282459E-01
(PID.TID 0000.0001) %MON seaice_uice_mean             =   5.2685365267315E-01
(PID.TID 0000.0001) %MON seaice_uice_sd               =   7.8572479021879E-02
(PID.TID 0000.0001) %MON seaice_uice_del2             =   7.5718108922017E-05
(PID.TID 0000.0001) %MON seaice_vice_max              =   1.4597935059468E-01
(PID.TID 0000.0001) %MON seaice_vice_min              =  -1.2518453930568E-01
(PID.TID 0000.0001) %MON seaice_vice_mean             =  -1.5081255659693E-03
(PID.TID 0000.0001) %MON seaice_vice_sd               =   5.2466556792718E-02
(PID.TID 0000.0001) %MON seaice_vice_del2             =   4.6115733714001E-05
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // End MONITOR SEAICE statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // Begin MONITOR Therm.SeaIce statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) %MON thSI_time_sec                =   3.6000000000000E+03
(PID.TID 0000.0001) %MON thSI_Ice_Area_G              =   6.9372180792247E+10
(PID.TID 0000.0001) %MON thSI_Ice_Area_S              =   2.9378991156833E+10
(PID.TID 0000.0001) %MON thSI_Ice_Area_N              =   3.9993189635414E+10
(PID.TID 0000.0001) %MON thSI_IceH_ave_G              =   2.0036850278107E-01
(PID.TID 0000.0001) %MON thSI_IceH_ave_S              =   2.0082439400904E-01
(PID.TID 0000.0001) %MON thSI_IceH_ave_N              =   2.0003360515282E-01
(PID.TID 0000.0001) %MON thSI_IceH_max_S              =   2.5156326620130E-01
(PID.TID 0000.0001) %MON thSI_IceH_max_N              =   2.0023343737268E-01
(PID.TID 0000.0001) %MON thSI_SnwH_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_min_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_min_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_min_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_min_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_min_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_min_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_TotEnerg_G              =  -4.1574014390118E+18
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // End MONITOR Therm.SeaIce statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       1    401 0.99000E+00 0.10953E-01
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      1 /    401, Nb. of FGMRES iterations =      1
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       2    402 0.99000E+00 0.82146E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      2 /    402, Nb. of FGMRES iterations =      1
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       3    403 0.99000E+00 0.71175E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      3 /    403, Nb. of FGMRES iterations =      1
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       4    404 0.99000E+00 0.62167E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      4 /    404, Nb. of FGMRES iterations =      1
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       5    405 0.79297E+00 0.53260E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      5 /    405, Nb. of FGMRES iterations =      2
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       6    406 0.51329E+00 0.34143E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      6 /    406, Nb. of FGMRES iterations =      7
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       7    407 0.67401E+00 0.26247E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      7 /    407, Nb. of FGMRES iterations =      2
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       8    408 0.50386E+00 0.16620E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      8 /    408, Nb. of FGMRES iterations =      8
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       9    409 0.39608E+00 0.89635E-03
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      9 /    409, Nb. of FGMRES iterations =      8
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      10    410 0.26961E+00 0.37408E-03
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     10 /    410, Nb. of FGMRES iterations =     11
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      11    411 0.12694E+00 0.94486E-04
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     11 /    411, Nb. of FGMRES iterations =     15
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      12    412 0.10000E+00 0.80589E-05
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     12 /    412, Nb. of FGMRES iterations =     16
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      13    413 0.10000E+00 0.63763E-06
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     13 /    413, Nb. of FGMRES iterations =     20
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      14    414 0.10000E+00 0.53016E-07
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     14 /    414, Nb. of FGMRES iterations =     20
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      15    415 0.10000E+00 0.49278E-08
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     15 /    415, Nb. of FGMRES iterations =     20
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      16    416 0.10000E+00 0.47813E-09
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     16 /    416, Nb. of FGMRES iterations =     21
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      17    417 0.10000E+00 0.43635E-10
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     17 /    417, Nb. of FGMRES iterations =     21
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  // Begin JFNK statistics
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  %JFNK_MON: time step              =          3
(PID.TID 0000.0001)  %JFNK_MON: Nb. of time steps      =          1
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Newton steps    =         18
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Krylov steps    =        175
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Newton failures =          0
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Krylov failures =          0
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  // End JFNK statistics
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Total number FGMRES iterations =    175 in timestep          3
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // Begin MONITOR SEAICE statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) %MON seaice_tsnumber              =                     3
(PID.TID 0000.0001) %MON seaice_time_sec              =   5.4000000000000E+03
(PID.TID 0000.0001) %MON seaice_uice_max              =   6.9120639703719E-01
(PID.TID 0000.0001) %MON seaice_uice_min              =   2.7696543769723E-01
(PID.TID 0000.0001) %MON seaice_uice_mean             =   5.2754011323878E-01
(PID.TID 0000.0001) %MON seaice_uice_sd               =   7.9712661223631E-02
(PID.TID 0000.0001) %MON seaice_uice_del2             =   1.0090403249739E-04
(PID.TID 0000.0001) %MON seaice_vice_max              =   1.5490791095437E-01
(PID.TID 0000.0001) %MON seaice_vice_min              =  -1.2923393197748E-01
(PID.TID 0000.0001) %MON seaice_vice_mean             =  -1.4629763721882E-03
(PID.TID 0000.0001) %MON seaice_vice_sd               =   5.4113172770418E-02
(PID.TID 0000.0001) %MON seaice_vice_del2             =   5.5442292908020E-05
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // End MONITOR SEAICE statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // Begin MONITOR Therm.SeaIce statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) %MON thSI_time_sec                =   5.4000000000000E+03
(PID.TID 0000.0001) %MON thSI_Ice_Area_G              =   6.9308813978476E+10
(PID.TID 0000.0001) %MON thSI_Ice_Area_S              =   2.9318960839147E+10
(PID.TID 0000.0001) %MON thSI_Ice_Area_N              =   3.9989853139328E+10
(PID.TID 0000.0001) %MON thSI_IceH_ave_G              =   2.0055169324232E-01
(PID.TID 0000.0001) %MON thSI_IceH_ave_S              =   2.0123695858553E-01
(PID.TID 0000.0001) %MON thSI_IceH_ave_N              =   2.0004928410138E-01
(PID.TID 0000.0001) %MON thSI_IceH_max_S              =   2.7173212022099E-01
(PID.TID 0000.0001) %MON thSI_IceH_max_N              =   2.0034255146434E-01
(PID.TID 0000.0001) %MON thSI_SnwH_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_min_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_min_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_min_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_min_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_min_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_min_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_TotEnerg_G              =  -4.1574014390118E+18
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // End MONITOR Therm.SeaIce statistics
(PID.TID 0000.0001) // =======================================================
 Computing Diagnostic #    155  SIuice       Counter:       1   Parms: UU      M1      
           Vector  Mate for  SIuice       Diagnostic #    156  SIvice   exists 
 Computing Diagnostic #    156  SIvice       Counter:       1   Parms: VV      M1      
           Vector  Mate for  SIvice       Diagnostic #    155  SIuice   exists 
 Computing Diagnostic #    149  SIheff       Counter:       1   Parms: SM      M1      
 Computing Diagnostic #    216  SI_Fract     Counter:       1   Parms: SM P    M1      
 Computing Diagnostic #    217  SI_Thick     Counter:       1   Parms: SM PC   M1      
       use Counter Mate for  SI_Thick     Diagnostic #    216  SI_Fract
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       1    601 0.99000E+00 0.91204E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      1 /    601, Nb. of FGMRES iterations =      1
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       2    602 0.99000E+00 0.54444E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      2 /    602, Nb. of FGMRES iterations =      1
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       3    603 0.70133E+00 0.42976E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      3 /    603, Nb. of FGMRES iterations =      2
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       4    604 0.35010E+00 0.21348E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      4 /    604, Nb. of FGMRES iterations =      4
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       5    605 0.25838E+00 0.86602E-03
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      5 /    605, Nb. of FGMRES iterations =      5
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       6    606 0.14606E+00 0.24018E-03
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      6 /    606, Nb. of FGMRES iterations =     11
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       7    607 0.10000E+00 0.31384E-04
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      7 /    607, Nb. of FGMRES iterations =     17
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       8    608 0.10000E+00 0.31551E-05
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      8 /    608, Nb. of FGMRES iterations =     19
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       9    609 0.10000E+00 0.23379E-06
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      9 /    609, Nb. of FGMRES iterations =     17
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      10    610 0.10000E+00 0.22073E-07
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     10 /    610, Nb. of FGMRES iterations =     18
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      11    611 0.10000E+00 0.18993E-08
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     11 /    611, Nb. of FGMRES iterations =     15
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      12    612 0.10000E+00 0.18275E-09
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     12 /    612, Nb. of FGMRES iterations =     18
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      13    613 0.10000E+00 0.16187E-10
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     13 /    613, Nb. of FGMRES iterations =     19
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  // Begin JFNK statistics
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  %JFNK_MON: time step              =          4
(PID.TID 0000.0001)  %JFNK_MON: Nb. of time steps      =          1
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Newton steps    =         14
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Krylov steps    =        147
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Newton failures =          0
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Krylov failures =          0
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  // End JFNK statistics
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Total number FGMRES iterations =    147 in timestep          4
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // Begin MONITOR SEAICE statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) %MON seaice_tsnumber              =                     4
(PID.TID 0000.0001) %MON seaice_time_sec              =   7.2000000000000E+03
(PID.TID 0000.0001) %MON seaice_uice_max              =   6.9288692426672E-01
(PID.TID 0000.0001) %MON seaice_uice_min              =   2.4201549882673E-01
(PID.TID 0000.0001) %MON seaice_uice_mean             =   5.2726544954150E-01
(PID.TID 0000.0001) %MON seaice_uice_sd               =   8.0657041850005E-02
(PID.TID 0000.0001) %MON seaice_uice_del2             =   1.3343919092839E-04
(PID.TID 0000.0001) %MON seaice_vice_max              =   1.6608417628208E-01
(PID.TID 0000.0001) %MON seaice_vice_min              =  -1.3060998672480E-01
(PID.TID 0000.0001) %MON seaice_vice_mean             =  -1.3232395307652E-03
(PID.TID 0000.0001) %MON seaice_vice_sd               =   5.4862673606709E-02
(PID.TID 0000.0001) %MON seaice_vice_del2             =   6.6513977804402E-05
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // End MONITOR SEAICE statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // Begin MONITOR Therm.SeaIce statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) %MON thSI_time_sec                =   7.2000000000000E+03
(PID.TID 0000.0001) %MON thSI_Ice_Area_G              =   6.9245878780228E+10
(PID.TID 0000.0001) %MON thSI_Ice_Area_S              =   2.9259271109367E+10
(PID.TID 0000.0001) %MON thSI_Ice_Area_N              =   3.9986607670861E+10
(PID.TID 0000.0001) %MON thSI_IceH_ave_G              =   2.0073396778046E-01
(PID.TID 0000.0001) %MON thSI_IceH_ave_S              =   2.0164806232776E-01
(PID.TID 0000.0001) %MON thSI_IceH_ave_N              =   2.0006510033366E-01
(PID.TID 0000.0001) %MON thSI_IceH_max_S              =   2.8889190879901E-01
(PID.TID 0000.0001) %MON thSI_IceH_max_N              =   2.0045047813571E-01
(PID.TID 0000.0001) %MON thSI_SnwH_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_min_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_min_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_min_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_min_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_min_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_min_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_TotEnerg_G              =  -4.1574014390118E+18
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // End MONITOR Therm.SeaIce statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       1    801 0.99000E+00 0.74596E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      1 /    801, Nb. of FGMRES iterations =      1
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       2    802 0.99000E+00 0.40130E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      2 /    802, Nb. of FGMRES iterations =      1
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       3    803 0.62779E+00 0.29422E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      3 /    803, Nb. of FGMRES iterations =      2
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       4    804 0.42982E+00 0.16757E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      4 /    804, Nb. of FGMRES iterations =      3
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       5    805 0.39287E+00 0.89887E-03
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      5 /    805, Nb. of FGMRES iterations =      2
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       6    806 0.20297E+00 0.31045E-03
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      6 /    806, Nb. of FGMRES iterations =     11
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       7    807 0.10000E+00 0.62205E-04
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      7 /    807, Nb. of FGMRES iterations =     14
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       8    808 0.10000E+00 0.49537E-05
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      8 /    808, Nb. of FGMRES iterations =     17
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       9    809 0.10000E+00 0.37962E-06
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      9 /    809, Nb. of FGMRES iterations =     18
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      10    810 0.10000E+00 0.34594E-07
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     10 /    810, Nb. of FGMRES iterations =     20
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      11    811 0.10000E+00 0.33830E-08
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     11 /    811, Nb. of FGMRES iterations =     21
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      12    812 0.10000E+00 0.28889E-09
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     12 /    812, Nb. of FGMRES iterations =     21
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      13    813 0.10000E+00 0.26492E-10
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     13 /    813, Nb. of FGMRES iterations =     21
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  // Begin JFNK statistics
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  %JFNK_MON: time step              =          5
(PID.TID 0000.0001)  %JFNK_MON: Nb. of time steps      =          1
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Newton steps    =         14
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Krylov steps    =        152
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Newton failures =          0
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Krylov failures =          0
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  // End JFNK statistics
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Total number FGMRES iterations =    152 in timestep          5
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // Begin MONITOR SEAICE statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) %MON seaice_tsnumber              =                     5
(PID.TID 0000.0001) %MON seaice_time_sec              =   9.0000000000000E+03
(PID.TID 0000.0001) %MON seaice_uice_max              =   6.9434187464337E-01
(PID.TID 0000.0001) %MON seaice_uice_min              =   2.1495728640178E-01
(PID.TID 0000.0001) %MON seaice_uice_mean             =   5.2697844798388E-01
(PID.TID 0000.0001) %MON seaice_uice_sd               =   8.1528050896002E-02
(PID.TID 0000.0001) %MON seaice_uice_del2             =   1.6001675492418E-04
(PID.TID 0000.0001) %MON seaice_vice_max              =   1.7571844469803E-01
(PID.TID 0000.0001) %MON seaice_vice_min              =  -1.3158146418065E-01
(PID.TID 0000.0001) %MON seaice_vice_mean             =  -1.2006119828869E-03
(PID.TID 0000.0001) %MON seaice_vice_sd               =   5.5389005039947E-02
(PID.TID 0000.0001) %MON seaice_vice_del2             =   8.0140903384205E-05
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // End MONITOR SEAICE statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // Begin MONITOR Therm.SeaIce statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) %MON thSI_time_sec                =   9.0000000000000E+03
(PID.TID 0000.0001) %MON thSI_Ice_Area_G              =   6.9183281565711E+10
(PID.TID 0000.0001) %MON thSI_Ice_Area_S              =   2.9199854798377E+10
(PID.TID 0000.0001) %MON thSI_Ice_Area_N              =   3.9983426767334E+10
(PID.TID 0000.0001) %MON thSI_IceH_ave_G              =   2.0091559240071E-01
(PID.TID 0000.0001) %MON thSI_IceH_ave_S              =   2.0205833593146E-01
(PID.TID 0000.0001) %MON thSI_IceH_ave_N              =   2.0008104799400E-01
(PID.TID 0000.0001) %MON thSI_IceH_max_S              =   3.0398880859130E-01
(PID.TID 0000.0001) %MON thSI_IceH_max_N              =   2.0065298071228E-01
(PID.TID 0000.0001) %MON thSI_SnwH_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_min_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_min_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_min_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_min_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_min_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_min_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_TotEnerg_G              =  -4.1574014390118E+18
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // End MONITOR Therm.SeaIce statistics
(PID.TID 0000.0001) // =======================================================
 Compute Stats, Diag. #    216  SI_Fract  vol(   0 ): 2.780E+11  Parms: SM P    M1      
 Compute Stats, Diag. #    217  SI_Thick  vol(   0 ): 2.774E+11  Parms: SM PC   M1      
    use Counter Mate  #    216  SI_Fract  vol(   0 ): 2.780E+11 integral 2.774E+11
 Compute Stats, Diag. #    146  SIarea    vol(   0 ): 2.780E+11  Parms: SM      M1      
 Compute Stats, Diag. #    149  SIheff    vol(   0 ): 2.780E+11  Parms: SM      M1      
 Compute Stats, Diag. #    155  SIuice    vol(   0 ): 2.760E+11  Parms: UU      M1      
 Compute Stats, Diag. #    156  SIvice    vol(   0 ): 2.700E+11  Parms: VV      M1      
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       1   1001 0.99000E+00 0.61109E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      1 /   1001, Nb. of FGMRES iterations =      1
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       2   1002 0.99000E+00 0.31219E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      2 /   1002, Nb. of FGMRES iterations =      1
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       3   1003 0.56012E+00 0.21213E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      3 /   1003, Nb. of FGMRES iterations =      3
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       4   1004 0.69671E+00 0.16671E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      4 /   1004, Nb. of FGMRES iterations =      1
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       5   1005 0.31873E+00 0.77789E-03
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      5 /   1005, Nb. of FGMRES iterations =      6
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       6   1006 0.15379E+00 0.22329E-03
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      6 /   1006, Nb. of FGMRES iterations =     13
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       7   1007 0.10000E+00 0.45984E-04
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      7 /   1007, Nb. of FGMRES iterations =     16
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       8   1008 0.10000E+00 0.35125E-05
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      8 /   1008, Nb. of FGMRES iterations =     16
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       9   1009 0.10000E+00 0.32577E-06
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      9 /   1009, Nb. of FGMRES iterations =     18
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      10   1010 0.10000E+00 0.29392E-07
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     10 /   1010, Nb. of FGMRES iterations =     20
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      11   1011 0.10000E+00 0.23554E-08
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     11 /   1011, Nb. of FGMRES iterations =     19
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      12   1012 0.10000E+00 0.23272E-09
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     12 /   1012, Nb. of FGMRES iterations =     20
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      13   1013 0.10000E+00 0.22591E-10
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     13 /   1013, Nb. of FGMRES iterations =     21
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  // Begin JFNK statistics
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  %JFNK_MON: time step              =          6
(PID.TID 0000.0001)  %JFNK_MON: Nb. of time steps      =          1
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Newton steps    =         14
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Krylov steps    =        155
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Newton failures =          0
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Krylov failures =          0
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  // End JFNK statistics
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Total number FGMRES iterations =    155 in timestep          6
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // Begin MONITOR SEAICE statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) %MON seaice_tsnumber              =                     6
(PID.TID 0000.0001) %MON seaice_time_sec              =   1.0800000000000E+04
(PID.TID 0000.0001) %MON seaice_uice_max              =   6.9557915676692E-01
(PID.TID 0000.0001) %MON seaice_uice_min              =   1.9428268693220E-01
(PID.TID 0000.0001) %MON seaice_uice_mean             =   5.2671575837934E-01
(PID.TID 0000.0001) %MON seaice_uice_sd               =   8.2321628449459E-02
(PID.TID 0000.0001) %MON seaice_uice_del2             =   1.7812109259306E-04
(PID.TID 0000.0001) %MON seaice_vice_max              =   1.8359239891719E-01
(PID.TID 0000.0001) %MON seaice_vice_min              =  -1.3262906048862E-01
(PID.TID 0000.0001) %MON seaice_vice_mean             =  -1.0886901987345E-03
(PID.TID 0000.0001) %MON seaice_vice_sd               =   5.5818318451862E-02
(PID.TID 0000.0001) %MON seaice_vice_del2             =   9.6742176871102E-05
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // End MONITOR SEAICE statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // Begin MONITOR Therm.SeaIce statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) %MON thSI_time_sec                =   1.0800000000000E+04
(PID.TID 0000.0001) %MON thSI_Ice_Area_G              =   6.9120967725799E+10
(PID.TID 0000.0001) %MON thSI_Ice_Area_S              =   2.9140690916232E+10
(PID.TID 0000.0001) %MON thSI_Ice_Area_N              =   3.9980276809566E+10
(PID.TID 0000.0001) %MON thSI_IceH_ave_G              =   2.0109672154969E-01
(PID.TID 0000.0001) %MON thSI_IceH_ave_S              =   2.0246810076361E-01
(PID.TID 0000.0001) %MON thSI_IceH_ave_N              =   2.0009715523872E-01
(PID.TID 0000.0001) %MON thSI_IceH_max_S              =   3.1768265038162E-01
(PID.TID 0000.0001) %MON thSI_IceH_max_N              =   2.0091554544188E-01
(PID.TID 0000.0001) %MON thSI_SnwH_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_min_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_min_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_min_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_min_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_min_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_min_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_TotEnerg_G              =  -4.1574014390118E+18
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // End MONITOR Therm.SeaIce statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       1   1201 0.99000E+00 0.51184E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      1 /   1201, Nb. of FGMRES iterations =      1
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       2   1202 0.99000E+00 0.27262E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      2 /   1202, Nb. of FGMRES iterations =      1
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       3   1203 0.55377E+00 0.18384E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      3 /   1203, Nb. of FGMRES iterations =      2
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       4   1204 0.39404E+00 0.98810E-03
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      4 /   1204, Nb. of FGMRES iterations =      6
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       5   1205 0.21533E+00 0.35498E-03
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      5 /   1205, Nb. of FGMRES iterations =      7
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       6   1206 0.20107E+00 0.12183E-03
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      6 /   1206, Nb. of FGMRES iterations =      9
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       7   1207 0.10000E+00 0.17637E-04
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      7 /   1207, Nb. of FGMRES iterations =     16
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       8   1208 0.10000E+00 0.17405E-05
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      8 /   1208, Nb. of FGMRES iterations =     18
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       9   1209 0.10000E+00 0.14734E-06
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      9 /   1209, Nb. of FGMRES iterations =     19
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      10   1210 0.10000E+00 0.14135E-07
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     10 /   1210, Nb. of FGMRES iterations =     21
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      11   1211 0.10000E+00 0.11071E-08
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     11 /   1211, Nb. of FGMRES iterations =     21
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      12   1212 0.10000E+00 0.98761E-10
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     12 /   1212, Nb. of FGMRES iterations =     21
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      13   1213 0.10000E+00 0.93179E-11
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     13 /   1213, Nb. of FGMRES iterations =     21
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  // Begin JFNK statistics
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  %JFNK_MON: time step              =          7
(PID.TID 0000.0001)  %JFNK_MON: Nb. of time steps      =          1
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Newton steps    =         14
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Krylov steps    =        163
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Newton failures =          0
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Krylov failures =          0
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  // End JFNK statistics
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Total number FGMRES iterations =    163 in timestep          7
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // Begin MONITOR SEAICE statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) %MON seaice_tsnumber              =                     7
(PID.TID 0000.0001) %MON seaice_time_sec              =   1.2600000000000E+04
(PID.TID 0000.0001) %MON seaice_uice_max              =   6.9663596743664E-01
(PID.TID 0000.0001) %MON seaice_uice_min              =   1.7700179464700E-01
(PID.TID 0000.0001) %MON seaice_uice_mean             =   5.2646451833498E-01
(PID.TID 0000.0001) %MON seaice_uice_sd               =   8.3074471621059E-02
(PID.TID 0000.0001) %MON seaice_uice_del2             =   1.9184018385419E-04
(PID.TID 0000.0001) %MON seaice_vice_max              =   1.9011182726080E-01
(PID.TID 0000.0001) %MON seaice_vice_min              =  -1.3386396481674E-01
(PID.TID 0000.0001) %MON seaice_vice_mean             =  -9.7694262316479E-04
(PID.TID 0000.0001) %MON seaice_vice_sd               =   5.6183940400714E-02
(PID.TID 0000.0001) %MON seaice_vice_del2             =   1.1581066530695E-04
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // End MONITOR SEAICE statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // Begin MONITOR Therm.SeaIce statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) %MON thSI_time_sec                =   1.2600000000000E+04
(PID.TID 0000.0001) %MON thSI_Ice_Area_G              =   6.9058911688832E+10
(PID.TID 0000.0001) %MON thSI_Ice_Area_S              =   2.9081767409690E+10
(PID.TID 0000.0001) %MON thSI_Ice_Area_N              =   3.9977144279142E+10
(PID.TID 0000.0001) %MON thSI_IceH_ave_G              =   2.0127742618695E-01
(PID.TID 0000.0001) %MON thSI_IceH_ave_S              =   2.0287753298871E-01
(PID.TID 0000.0001) %MON thSI_IceH_ave_N              =   2.0011341273180E-01
(PID.TID 0000.0001) %MON thSI_IceH_max_S              =   3.3032524886470E-01
(PID.TID 0000.0001) %MON thSI_IceH_max_N              =   2.0121766078594E-01
(PID.TID 0000.0001) %MON thSI_SnwH_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_min_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_min_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_min_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_min_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_min_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_min_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_TotEnerg_G              =  -4.1574014390118E+18
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // End MONITOR Therm.SeaIce statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       1   1401 0.99000E+00 0.43067E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      1 /   1401, Nb. of FGMRES iterations =      1
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       2   1402 0.99000E+00 0.24109E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      2 /   1402, Nb. of FGMRES iterations =      1
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       3   1403 0.58465E+00 0.16857E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      3 /   1403, Nb. of FGMRES iterations =      2
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       4   1404 0.41166E+00 0.93282E-03
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      4 /   1404, Nb. of FGMRES iterations =      5
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       5   1405 0.26340E+00 0.38330E-03
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      5 /   1405, Nb. of FGMRES iterations =      6
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       6   1406 0.16828E+00 0.11683E-03
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      6 /   1406, Nb. of FGMRES iterations =     13
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       7   1407 0.10000E+00 0.19275E-04
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      7 /   1407, Nb. of FGMRES iterations =     17
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       8   1408 0.10000E+00 0.15910E-05
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      8 /   1408, Nb. of FGMRES iterations =     16
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       9   1409 0.10000E+00 0.14301E-06
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      9 /   1409, Nb. of FGMRES iterations =     19
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      10   1410 0.10000E+00 0.12207E-07
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     10 /   1410, Nb. of FGMRES iterations =     21
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      11   1411 0.10000E+00 0.10031E-08
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     11 /   1411, Nb. of FGMRES iterations =     21
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      12   1412 0.10000E+00 0.86365E-10
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     12 /   1412, Nb. of FGMRES iterations =     21
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      13   1413 0.10000E+00 0.77416E-11
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     13 /   1413, Nb. of FGMRES iterations =     22
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  // Begin JFNK statistics
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  %JFNK_MON: time step              =          8
(PID.TID 0000.0001)  %JFNK_MON: Nb. of time steps      =          1
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Newton steps    =         14
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Krylov steps    =        165
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Newton failures =          0
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Krylov failures =          0
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  // End JFNK statistics
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Total number FGMRES iterations =    165 in timestep          8
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // Begin MONITOR SEAICE statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) %MON seaice_tsnumber              =                     8
(PID.TID 0000.0001) %MON seaice_time_sec              =   1.4400000000000E+04
(PID.TID 0000.0001) %MON seaice_uice_max              =   6.9755676807505E-01
(PID.TID 0000.0001) %MON seaice_uice_min              =   1.6297042033576E-01
(PID.TID 0000.0001) %MON seaice_uice_mean             =   5.2622430202480E-01
(PID.TID 0000.0001) %MON seaice_uice_sd               =   8.3791898598237E-02
(PID.TID 0000.0001) %MON seaice_uice_del2             =   2.0219830174698E-04
(PID.TID 0000.0001) %MON seaice_vice_max              =   1.9568689963190E-01
(PID.TID 0000.0001) %MON seaice_vice_min              =  -1.3877918237425E-01
(PID.TID 0000.0001) %MON seaice_vice_mean             =  -8.6817451656315E-04
(PID.TID 0000.0001) %MON seaice_vice_sd               =   5.6512879752051E-02
(PID.TID 0000.0001) %MON seaice_vice_del2             =   1.3501548138195E-04
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // End MONITOR SEAICE statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // Begin MONITOR Therm.SeaIce statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) %MON thSI_time_sec                =   1.4400000000000E+04
(PID.TID 0000.0001) %MON thSI_Ice_Area_G              =   6.8997075648496E+10
(PID.TID 0000.0001) %MON thSI_Ice_Area_S              =   2.9023050227596E+10
(PID.TID 0000.0001) %MON thSI_Ice_Area_N              =   3.9974025420901E+10
(PID.TID 0000.0001) %MON thSI_IceH_ave_G              =   2.0145781352840E-01
(PID.TID 0000.0001) %MON thSI_IceH_ave_S              =   2.0328686475396E-01
(PID.TID 0000.0001) %MON thSI_IceH_ave_N              =   2.0012983504665E-01
(PID.TID 0000.0001) %MON thSI_IceH_max_S              =   3.4210792319560E-01
(PID.TID 0000.0001) %MON thSI_IceH_max_N              =   2.0155255158282E-01
(PID.TID 0000.0001) %MON thSI_SnwH_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_min_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_min_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_min_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_min_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_min_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_min_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_TotEnerg_G              =  -4.1574014390118E+18
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // End MONITOR Therm.SeaIce statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       1   1601 0.99000E+00 0.36191E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      1 /   1601, Nb. of FGMRES iterations =      1
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       2   1602 0.99000E+00 0.21502E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      2 /   1602, Nb. of FGMRES iterations =      1
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       3   1603 0.55017E+00 0.14437E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      3 /   1603, Nb. of FGMRES iterations =      3
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       4   1604 0.30690E+00 0.65687E-03
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      4 /   1604, Nb. of FGMRES iterations =      8
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       5   1605 0.14102E+00 0.17796E-03
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      5 /   1605, Nb. of FGMRES iterations =     15
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       6   1606 0.10000E+00 0.24321E-04
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      6 /   1606, Nb. of FGMRES iterations =     16
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       7   1607 0.10000E+00 0.22479E-05
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      7 /   1607, Nb. of FGMRES iterations =     17
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       8   1608 0.10000E+00 0.19969E-06
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      8 /   1608, Nb. of FGMRES iterations =     18
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       9   1609 0.10000E+00 0.19442E-07
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      9 /   1609, Nb. of FGMRES iterations =     20
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      10   1610 0.10000E+00 0.17921E-08
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     10 /   1610, Nb. of FGMRES iterations =     21
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      11   1611 0.10000E+00 0.16449E-09
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     11 /   1611, Nb. of FGMRES iterations =     21
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      12   1612 0.10000E+00 0.15743E-10
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     12 /   1612, Nb. of FGMRES iterations =     21
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  // Begin JFNK statistics
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  %JFNK_MON: time step              =          9
(PID.TID 0000.0001)  %JFNK_MON: Nb. of time steps      =          1
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Newton steps    =         13
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Krylov steps    =        162
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Newton failures =          0
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Krylov failures =          0
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  // End JFNK statistics
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Total number FGMRES iterations =    162 in timestep          9
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // Begin MONITOR SEAICE statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) %MON seaice_tsnumber              =                     9
(PID.TID 0000.0001) %MON seaice_time_sec              =   1.6200000000000E+04
(PID.TID 0000.0001) %MON seaice_uice_max              =   6.9840479235556E-01
(PID.TID 0000.0001) %MON seaice_uice_min              =   1.5110280382254E-01
(PID.TID 0000.0001) %MON seaice_uice_mean             =   5.2600030409539E-01
(PID.TID 0000.0001) %MON seaice_uice_sd               =   8.4456879249817E-02
(PID.TID 0000.0001) %MON seaice_uice_del2             =   2.0805057891168E-04
(PID.TID 0000.0001) %MON seaice_vice_max              =   2.0045466147737E-01
(PID.TID 0000.0001) %MON seaice_vice_min              =  -1.4380274730277E-01
(PID.TID 0000.0001) %MON seaice_vice_mean             =  -7.7497253274533E-04
(PID.TID 0000.0001) %MON seaice_vice_sd               =   5.6826039379073E-02
(PID.TID 0000.0001) %MON seaice_vice_del2             =   1.4783886621589E-04
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // End MONITOR SEAICE statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // Begin MONITOR Therm.SeaIce statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) %MON thSI_time_sec                =   1.6200000000000E+04
(PID.TID 0000.0001) %MON thSI_Ice_Area_G              =   6.8935433356277E+10
(PID.TID 0000.0001) %MON thSI_Ice_Area_S              =   2.8964518073574E+10
(PID.TID 0000.0001) %MON thSI_Ice_Area_N              =   3.9970915282703E+10
(PID.TID 0000.0001) %MON thSI_IceH_ave_G              =   2.0163795777073E-01
(PID.TID 0000.0001) %MON thSI_IceH_ave_S              =   2.0369620542949E-01
(PID.TID 0000.0001) %MON thSI_IceH_ave_N              =   2.0014646949506E-01
(PID.TID 0000.0001) %MON thSI_IceH_max_S              =   3.5317540530732E-01
(PID.TID 0000.0001) %MON thSI_IceH_max_N              =   2.0191951532146E-01
(PID.TID 0000.0001) %MON thSI_SnwH_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_min_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_min_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_min_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_min_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_min_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_min_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_TotEnerg_G              =  -4.1574014390118E+18
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // End MONITOR Therm.SeaIce statistics
(PID.TID 0000.0001) // =======================================================
 Compute Stats, Diag. #    216  SI_Fract  vol(   0 ): 2.780E+11  Parms: SM P    M1      
 Compute Stats, Diag. #    217  SI_Thick  vol(   0 ): 2.764E+11  Parms: SM PC   M1      
    use Counter Mate  #    216  SI_Fract  vol(   0 ): 2.780E+11 integral 2.764E+11
 Compute Stats, Diag. #    146  SIarea    vol(   0 ): 2.780E+11  Parms: SM      M1      
 Compute Stats, Diag. #    149  SIheff    vol(   0 ): 2.780E+11  Parms: SM      M1      
 Compute Stats, Diag. #    155  SIuice    vol(   0 ): 2.760E+11  Parms: UU      M1      
 Compute Stats, Diag. #    156  SIvice    vol(   0 ): 2.700E+11  Parms: VV      M1      
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       1   1801 0.99000E+00 0.34278E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      1 /   1801, Nb. of FGMRES iterations =      1
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       2   1802 0.99000E+00 0.20692E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      2 /   1802, Nb. of FGMRES iterations =      1
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       3   1803 0.52503E+00 0.13466E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      3 /   1803, Nb. of FGMRES iterations =      3
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       4   1804 0.33229E+00 0.64604E-03
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      4 /   1804, Nb. of FGMRES iterations =      7
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       5   1805 0.18844E+00 0.21235E-03
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      5 /   1805, Nb. of FGMRES iterations =     15
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       6   1806 0.10000E+00 0.29975E-04
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      6 /   1806, Nb. of FGMRES iterations =     17
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       7   1807 0.10000E+00 0.22931E-05
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      7 /   1807, Nb. of FGMRES iterations =     17
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       8   1808 0.10000E+00 0.22111E-06
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      8 /   1808, Nb. of FGMRES iterations =     18
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       9   1809 0.10000E+00 0.19139E-07
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      9 /   1809, Nb. of FGMRES iterations =     20
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      10   1810 0.10000E+00 0.17183E-08
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     10 /   1810, Nb. of FGMRES iterations =     21
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      11   1811 0.10000E+00 0.15502E-09
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     11 /   1811, Nb. of FGMRES iterations =     22
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      12   1812 0.10000E+00 0.12070E-10
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     12 /   1812, Nb. of FGMRES iterations =     21
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  // Begin JFNK statistics
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  %JFNK_MON: time step              =         10
(PID.TID 0000.0001)  %JFNK_MON: Nb. of time steps      =          1
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Newton steps    =         13
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Krylov steps    =        163
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Newton failures =          0
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Krylov failures =          0
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  // End JFNK statistics
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Total number FGMRES iterations =    163 in timestep         10
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // Begin MONITOR SEAICE statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) %MON seaice_tsnumber              =                    10
(PID.TID 0000.0001) %MON seaice_time_sec              =   1.8000000000000E+04
(PID.TID 0000.0001) %MON seaice_uice_max              =   6.9921968015612E-01
(PID.TID 0000.0001) %MON seaice_uice_min              =   1.4075364327971E-01
(PID.TID 0000.0001) %MON seaice_uice_mean             =   5.2578908940800E-01
(PID.TID 0000.0001) %MON seaice_uice_sd               =   8.5081396848136E-02
(PID.TID 0000.0001) %MON seaice_uice_del2             =   2.1073040776791E-04
(PID.TID 0000.0001) %MON seaice_vice_max              =   2.0452365938622E-01
(PID.TID 0000.0001) %MON seaice_vice_min              =  -1.4803614522496E-01
(PID.TID 0000.0001) %MON seaice_vice_mean             =  -6.9941682070351E-04
(PID.TID 0000.0001) %MON seaice_vice_sd               =   5.7125518165080E-02
(PID.TID 0000.0001) %MON seaice_vice_del2             =   1.5427270284641E-04
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // End MONITOR SEAICE statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // Begin MONITOR Therm.SeaIce statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) %MON thSI_time_sec                =   1.8000000000000E+04
(PID.TID 0000.0001) %MON thSI_Ice_Area_G              =   6.8873968993350E+10
(PID.TID 0000.0001) %MON thSI_Ice_Area_S              =   2.8906159160909E+10
(PID.TID 0000.0001) %MON thSI_Ice_Area_N              =   3.9967809832441E+10
(PID.TID 0000.0001) %MON thSI_IceH_ave_G              =   2.0181790309401E-01
(PID.TID 0000.0001) %MON thSI_IceH_ave_S              =   2.0410564113693E-01
(PID.TID 0000.0001) %MON thSI_IceH_ave_N              =   2.0016332856856E-01
(PID.TID 0000.0001) %MON thSI_IceH_max_S              =   3.6366336775719E-01
(PID.TID 0000.0001) %MON thSI_IceH_max_N              =   2.0231510077699E-01
(PID.TID 0000.0001) %MON thSI_SnwH_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_min_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_min_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_min_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_min_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_min_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_min_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_TotEnerg_G              =  -4.1574014390118E+18
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // End MONITOR Therm.SeaIce statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       1   2001 0.99000E+00 0.35506E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      1 /   2001, Nb. of FGMRES iterations =      1
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       2   2002 0.99000E+00 0.19897E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      2 /   2002, Nb. of FGMRES iterations =      1
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       3   2003 0.52034E+00 0.12872E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      3 /   2003, Nb. of FGMRES iterations =      3
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       4   2004 0.35568E+00 0.64618E-03
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      4 /   2004, Nb. of FGMRES iterations =      6
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       5   2005 0.23852E+00 0.24852E-03
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      5 /   2005, Nb. of FGMRES iterations =     10
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       6   2006 0.13111E+00 0.64140E-04
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      6 /   2006, Nb. of FGMRES iterations =     12
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       7   2007 0.10000E+00 0.70708E-05
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      7 /   2007, Nb. of FGMRES iterations =     17
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       8   2008 0.10000E+00 0.62690E-06
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      8 /   2008, Nb. of FGMRES iterations =     18
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       9   2009 0.10000E+00 0.59871E-07
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      9 /   2009, Nb. of FGMRES iterations =     19
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      10   2010 0.10000E+00 0.57919E-08
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     10 /   2010, Nb. of FGMRES iterations =     21
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      11   2011 0.10000E+00 0.49959E-09
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     11 /   2011, Nb. of FGMRES iterations =     22
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      12   2012 0.10000E+00 0.41216E-10
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     12 /   2012, Nb. of FGMRES iterations =     20
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      13   2013 0.10000E+00 0.41124E-11
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     13 /   2013, Nb. of FGMRES iterations =     21
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  // Begin JFNK statistics
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  %JFNK_MON: time step              =         11
(PID.TID 0000.0001)  %JFNK_MON: Nb. of time steps      =          1
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Newton steps    =         14
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Krylov steps    =        171
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Newton failures =          0
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Krylov failures =          0
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  // End JFNK statistics
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Total number FGMRES iterations =    171 in timestep         11
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // Begin MONITOR SEAICE statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) %MON seaice_tsnumber              =                    11
(PID.TID 0000.0001) %MON seaice_time_sec              =   1.9800000000000E+04
(PID.TID 0000.0001) %MON seaice_uice_max              =   7.0001186010923E-01
(PID.TID 0000.0001) %MON seaice_uice_min              =   1.3160136359025E-01
(PID.TID 0000.0001) %MON seaice_uice_mean             =   5.2558772475168E-01
(PID.TID 0000.0001) %MON seaice_uice_sd               =   8.5675219731328E-02
(PID.TID 0000.0001) %MON seaice_uice_del2             =   2.1179167117476E-04
(PID.TID 0000.0001) %MON seaice_vice_max              =   2.0802636000253E-01
(PID.TID 0000.0001) %MON seaice_vice_min              =  -1.5147415929820E-01
(PID.TID 0000.0001) %MON seaice_vice_mean             =  -6.3680638268280E-04
(PID.TID 0000.0001) %MON seaice_vice_sd               =   5.7411336295285E-02
(PID.TID 0000.0001) %MON seaice_vice_del2             =   1.5732890484456E-04
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // End MONITOR SEAICE statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // Begin MONITOR Therm.SeaIce statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) %MON thSI_time_sec                =   1.9800000000000E+04
(PID.TID 0000.0001) %MON thSI_Ice_Area_G              =   6.8812670973149E+10
(PID.TID 0000.0001) %MON thSI_Ice_Area_S              =   2.8847966928169E+10
(PID.TID 0000.0001) %MON thSI_Ice_Area_N              =   3.9964704044980E+10
(PID.TID 0000.0001) %MON thSI_IceH_ave_G              =   2.0199768158140E-01
(PID.TID 0000.0001) %MON thSI_IceH_ave_S              =   2.0451524191447E-01
(PID.TID 0000.0001) %MON thSI_IceH_ave_N              =   2.0018041559724E-01
(PID.TID 0000.0001) %MON thSI_IceH_max_S              =   3.7366857892521E-01
(PID.TID 0000.0001) %MON thSI_IceH_max_N              =   2.0273767499120E-01
(PID.TID 0000.0001) %MON thSI_SnwH_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_min_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_min_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_min_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_min_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_min_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_min_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_TotEnerg_G              =  -4.1574014390118E+18
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // End MONITOR Therm.SeaIce statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       1   2201 0.99000E+00 0.36152E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      1 /   2201, Nb. of FGMRES iterations =      1
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       2   2202 0.99000E+00 0.19225E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      2 /   2202, Nb. of FGMRES iterations =      1
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       3   2203 0.50855E+00 0.12249E-02
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      3 /   2203, Nb. of FGMRES iterations =      3
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       4   2204 0.36810E+00 0.62914E-03
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      4 /   2204, Nb. of FGMRES iterations =      5
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       5   2205 0.20751E+00 0.22052E-03
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      5 /   2205, Nb. of FGMRES iterations =     13
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       6   2206 0.10000E+00 0.43783E-04
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      6 /   2206, Nb. of FGMRES iterations =     14
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       7   2207 0.10000E+00 0.38794E-05
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      7 /   2207, Nb. of FGMRES iterations =     16
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       8   2208 0.10000E+00 0.37026E-06
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      8 /   2208, Nb. of FGMRES iterations =     19
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =       9   2209 0.10000E+00 0.36985E-07
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =      9 /   2209, Nb. of FGMRES iterations =     20
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      10   2210 0.10000E+00 0.30344E-08
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     10 /   2210, Nb. of FGMRES iterations =     21
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      11   2211 0.10000E+00 0.26320E-09
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     11 /   2211, Nb. of FGMRES iterations =     21
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total, JFNKgamma_lin, initial norm =      12   2212 0.10000E+00 0.24141E-10
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Newton iterate / total =     12 /   2212, Nb. of FGMRES iterations =     21
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  // Begin JFNK statistics
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  %JFNK_MON: time step              =         12
(PID.TID 0000.0001)  %JFNK_MON: Nb. of time steps      =          1
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Newton steps    =         13
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Krylov steps    =        155
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Newton failures =          0
(PID.TID 0000.0001)  %JFNK_MON: Nb. of Krylov failures =          0
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  // End JFNK statistics
(PID.TID 0000.0001)  // =======================================================
(PID.TID 0000.0001)  S/R SEAICE_JFNK: Total number FGMRES iterations =    155 in timestep         12
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // Begin MONITOR SEAICE statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) %MON seaice_tsnumber              =                    12
(PID.TID 0000.0001) %MON seaice_time_sec              =   2.1600000000000E+04
(PID.TID 0000.0001) %MON seaice_uice_max              =   7.0078281779279E-01
(PID.TID 0000.0001) %MON seaice_uice_min              =   1.2345486022649E-01
(PID.TID 0000.0001) %MON seaice_uice_mean             =   5.2539464056980E-01
(PID.TID 0000.0001) %MON seaice_uice_sd               =   8.6243733195215E-02
(PID.TID 0000.0001) %MON seaice_uice_del2             =   2.1248295056058E-04
(PID.TID 0000.0001) %MON seaice_vice_max              =   2.1105554438495E-01
(PID.TID 0000.0001) %MON seaice_vice_min              =  -1.5416876645337E-01
(PID.TID 0000.0001) %MON seaice_vice_mean             =  -5.8084327230900E-04
(PID.TID 0000.0001) %MON seaice_vice_sd               =   5.7681648419713E-02
(PID.TID 0000.0001) %MON seaice_vice_del2             =   1.5879136498135E-04
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // End MONITOR SEAICE statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // Begin MONITOR Therm.SeaIce statistics
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) %MON thSI_time_sec                =   2.1600000000000E+04
(PID.TID 0000.0001) %MON thSI_Ice_Area_G              =   6.8751528006476E+10
(PID.TID 0000.0001) %MON thSI_Ice_Area_S              =   2.8789933711175E+10
(PID.TID 0000.0001) %MON thSI_Ice_Area_N              =   3.9961594295302E+10
(PID.TID 0000.0001) %MON thSI_IceH_ave_G              =   2.0217732467983E-01
(PID.TID 0000.0001) %MON thSI_IceH_ave_S              =   2.0492508423542E-01
(PID.TID 0000.0001) %MON thSI_IceH_ave_N              =   2.0019772859878E-01
(PID.TID 0000.0001) %MON thSI_IceH_max_S              =   3.8325483875023E-01
(PID.TID 0000.0001) %MON thSI_IceH_max_N              =   2.0318509304844E-01
(PID.TID 0000.0001) %MON thSI_SnwH_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_SnwH_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_min_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_min_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tsrf_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_min_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_min_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic1_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_ave_G              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_ave_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_ave_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_min_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_min_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_max_S              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_Tic2_max_N              =   0.0000000000000E+00
(PID.TID 0000.0001) %MON thSI_TotEnerg_G              =  -4.1574014390118E+18
(PID.TID 0000.0001) // =======================================================
(PID.TID 0000.0001) // End MONITOR Therm.SeaIce statistics
(PID.TID 0000.0001) // =======================================================
 Compute Stats, Diag. #    216  SI_Fract  vol(   0 ): 2.085E+11  Parms: SM P    M1      
 Compute Stats, Diag. #    217  SI_Thick  vol(   0 ): 2.066E+11  Parms: SM PC   M1      
    use Counter Mate  #    216  SI_Fract  vol(   0 ): 2.085E+11 integral 2.066E+11
 Compute Stats, Diag. #    146  SIarea    vol(   0 ): 2.085E+11  Parms: SM      M1      
 Compute Stats, Diag. #    149  SIheff    vol(   0 ): 2.085E+11  Parms: SM      M1      
 Compute Stats, Diag. #    155  SIuice    vol(   0 ): 2.070E+11  Parms: UU      M1      
 Compute Stats, Diag. #    156  SIvice    vol(   0 ): 2.025E+11  Parms: VV      M1      
(PID.TID 0000.0001) DIAGSTATS_CLOSE_IO: close file: iceStDiag.0000000000.txt , unit=     9
(PID.TID 0000.0001) %CHECKPOINT        12 ckptA
(PID.TID 0000.0001)   Seconds in section "ALL                    [THE_MODEL_MAIN]":
(PID.TID 0000.0001)           User time:   179.95764858298935
(PID.TID 0000.0001)         System time:  2.89960000663995743E-002
(PID.TID 0000.0001)     Wall clock time:   180.41772890090942
(PID.TID 0000.0001)          No. starts:           1
(PID.TID 0000.0001)           No. stops:           1
(PID.TID 0000.0001)   Seconds in section "INITIALISE_FIXED       [THE_MODEL_MAIN]":
(PID.TID 0000.0001)           User time:  4.59930005017668009E-002
(PID.TID 0000.0001)         System time:  5.99899981170892715E-003
(PID.TID 0000.0001)     Wall clock time:  5.15110492706298828E-002
(PID.TID 0000.0001)          No. starts:           1
(PID.TID 0000.0001)           No. stops:           1
(PID.TID 0000.0001)   Seconds in section "THE_MAIN_LOOP          [THE_MODEL_MAIN]":
(PID.TID 0000.0001)           User time:   179.91165558248758
(PID.TID 0000.0001)         System time:  2.29970002546906471E-002
(PID.TID 0000.0001)     Wall clock time:   180.36617183685303
(PID.TID 0000.0001)          No. starts:           1
(PID.TID 0000.0001)           No. stops:           1
(PID.TID 0000.0001)   Seconds in section "INITIALISE_VARIA    [THE_MAIN_LOOP]":
(PID.TID 0000.0001)           User time:  3.59949991106987000E-002
(PID.TID 0000.0001)         System time:  4.99999988824129105E-003
(PID.TID 0000.0001)     Wall clock time:  4.08878326416015625E-002
(PID.TID 0000.0001)          No. starts:           1
(PID.TID 0000.0001)           No. stops:           1
(PID.TID 0000.0001)   Seconds in section "MAIN LOOP           [THE_MAIN_LOOP]":
(PID.TID 0000.0001)           User time:   179.87566058337688
(PID.TID 0000.0001)         System time:  1.79970003664493561E-002
(PID.TID 0000.0001)     Wall clock time:   180.32525181770325
(PID.TID 0000.0001)          No. starts:           1
(PID.TID 0000.0001)           No. stops:           1
(PID.TID 0000.0001)   Seconds in section "MAIN_DO_LOOP        [THE_MAIN_LOOP]":
(PID.TID 0000.0001)           User time:   179.87466876208782
(PID.TID 0000.0001)         System time:  1.79970003664493561E-002
(PID.TID 0000.0001)     Wall clock time:   180.32511687278748
(PID.TID 0000.0001)          No. starts:          12
(PID.TID 0000.0001)           No. stops:          12
(PID.TID 0000.0001)   Seconds in section "FORWARD_STEP        [MAIN_DO_LOOP]":
(PID.TID 0000.0001)           User time:   179.87466876208782
(PID.TID 0000.0001)         System time:  1.79970003664493561E-002
(PID.TID 0000.0001)     Wall clock time:   180.32487082481384
(PID.TID 0000.0001)          No. starts:          12
(PID.TID 0000.0001)           No. stops:          12
(PID.TID 0000.0001)   Seconds in section "DO_STATEVARS_DIAGS  [FORWARD_STEP]":
(PID.TID 0000.0001)           User time:  2.60144248604774475E-002
(PID.TID 0000.0001)         System time:   0.0000000000000000
(PID.TID 0000.0001)     Wall clock time:  2.74360179901123047E-002
(PID.TID 0000.0001)          No. starts:          36
(PID.TID 0000.0001)           No. stops:          36
(PID.TID 0000.0001)   Seconds in section "LOAD_FIELDS_DRIVER  [FORWARD_STEP]":
(PID.TID 0000.0001)           User time:  9.59663093090057373E-002
(PID.TID 0000.0001)         System time:  9.98999923467636108E-004
(PID.TID 0000.0001)     Wall clock time:  9.51576232910156250E-002
(PID.TID 0000.0001)          No. starts:          12
(PID.TID 0000.0001)           No. stops:          12
(PID.TID 0000.0001)   Seconds in section "EXF_GETFORCING     [LOAD_FLDS_DRIVER]":
(PID.TID 0000.0001)           User time:  9.59663093090057373E-002
(PID.TID 0000.0001)         System time:  9.98999923467636108E-004
(PID.TID 0000.0001)     Wall clock time:  9.46581363677978516E-002
(PID.TID 0000.0001)          No. starts:          12
(PID.TID 0000.0001)           No. stops:          12
(PID.TID 0000.0001)   Seconds in section "EXTERNAL_FLDS_LOAD [LOAD_FLDS_DRIVER]":
(PID.TID 0000.0001)           User time:   0.0000000000000000
(PID.TID 0000.0001)         System time:   0.0000000000000000
(PID.TID 0000.0001)     Wall clock time:  1.28746032714843750E-004
(PID.TID 0000.0001)          No. starts:          12
(PID.TID 0000.0001)           No. stops:          12
(PID.TID 0000.0001)   Seconds in section "DO_ATMOSPHERIC_PHYS [FORWARD_STEP]":
(PID.TID 0000.0001)           User time:   0.0000000000000000
(PID.TID 0000.0001)         System time:   0.0000000000000000
(PID.TID 0000.0001)     Wall clock time:  1.24216079711914063E-004
(PID.TID 0000.0001)          No. starts:          12
(PID.TID 0000.0001)           No. stops:          12
(PID.TID 0000.0001)   Seconds in section "DO_OCEANIC_PHYS     [FORWARD_STEP]":
(PID.TID 0000.0001)           User time:   179.65369472652674
(PID.TID 0000.0001)         System time:  1.39979999512434006E-002
(PID.TID 0000.0001)     Wall clock time:   180.09847068786621
(PID.TID 0000.0001)          No. starts:          12
(PID.TID 0000.0001)           No. stops:          12
(PID.TID 0000.0001)   Seconds in section "THSICE_MAIN     [DO_OCEANIC_PHYS]":
(PID.TID 0000.0001)           User time:  2.30056345462799072E-002
(PID.TID 0000.0001)         System time:   0.0000000000000000
(PID.TID 0000.0001)     Wall clock time:  2.18927860260009766E-002
(PID.TID 0000.0001)          No. starts:          12
(PID.TID 0000.0001)           No. stops:          12
(PID.TID 0000.0001)   Seconds in section "SEAICE_MODEL    [DO_OCEANIC_PHYS]":
(PID.TID 0000.0001)           User time:   179.61368889361620
(PID.TID 0000.0001)         System time:  1.39979999512434006E-002
(PID.TID 0000.0001)     Wall clock time:   180.06203103065491
(PID.TID 0000.0001)          No. starts:          12
(PID.TID 0000.0001)           No. stops:          12
(PID.TID 0000.0001)   Seconds in section "SEAICE_DYNSOLVER   [SEAICE_MODEL]":
(PID.TID 0000.0001)           User time:   179.46969551593065
(PID.TID 0000.0001)         System time:  1.39979999512434006E-002
(PID.TID 0000.0001)     Wall clock time:   179.91331291198730
(PID.TID 0000.0001)          No. starts:          12
(PID.TID 0000.0001)           No. stops:          12
(PID.TID 0000.0001)   Seconds in section "BLOCKING_EXCHANGES  [FORWARD_STEP]":
(PID.TID 0000.0001)           User time:  4.98962402343750000E-003
(PID.TID 0000.0001)         System time:   0.0000000000000000
(PID.TID 0000.0001)     Wall clock time:  4.81390953063964844E-003
(PID.TID 0000.0001)          No. starts:          24
(PID.TID 0000.0001)           No. stops:          24
(PID.TID 0000.0001)   Seconds in section "THERMODYNAMICS      [FORWARD_STEP]":
(PID.TID 0000.0001)           User time:  4.00543212890625000E-003
(PID.TID 0000.0001)         System time:   0.0000000000000000
(PID.TID 0000.0001)     Wall clock time:  5.15174865722656250E-003
(PID.TID 0000.0001)          No. starts:          12
(PID.TID 0000.0001)           No. stops:          12
(PID.TID 0000.0001)   Seconds in section "TRC_CORRECTION_STEP [FORWARD_STEP]":
(PID.TID 0000.0001)           User time:   0.0000000000000000
(PID.TID 0000.0001)         System time:   0.0000000000000000
(PID.TID 0000.0001)     Wall clock time:  1.32799148559570313E-004
(PID.TID 0000.0001)          No. starts:          12
(PID.TID 0000.0001)           No. stops:          12
(PID.TID 0000.0001)   Seconds in section "MONITOR             [FORWARD_STEP]":
(PID.TID 0000.0001)           User time:   0.0000000000000000
(PID.TID 0000.0001)         System time:   0.0000000000000000
(PID.TID 0000.0001)     Wall clock time:  1.37805938720703125E-004
(PID.TID 0000.0001)          No. starts:          12
(PID.TID 0000.0001)           No. stops:          12
(PID.TID 0000.0001)   Seconds in section "DO_THE_MODEL_IO     [FORWARD_STEP]":
(PID.TID 0000.0001)           User time:  8.09726715087890625E-002
(PID.TID 0000.0001)         System time:  3.00000049173831940E-003
(PID.TID 0000.0001)     Wall clock time:  8.50868225097656250E-002
(PID.TID 0000.0001)          No. starts:          12
(PID.TID 0000.0001)           No. stops:          12
(PID.TID 0000.0001)   Seconds in section "DO_WRITE_PICKUP     [FORWARD_STEP]":
(PID.TID 0000.0001)           User time:  6.01196289062500000E-003
(PID.TID 0000.0001)         System time:   0.0000000000000000
(PID.TID 0000.0001)     Wall clock time:  6.57391548156738281E-003
(PID.TID 0000.0001)          No. starts:          12
(PID.TID 0000.0001)           No. stops:          12
(PID.TID 0000.0001) // ======================================================
(PID.TID 0000.0001) // Tile <-> Tile communication statistics
(PID.TID 0000.0001) // ======================================================
(PID.TID 0000.0001) // o Tile number: 000001
(PID.TID 0000.0001) //         No. X exchanges =              0
(PID.TID 0000.0001) //            Max. X spins =              0
(PID.TID 0000.0001) //            Min. X spins =     1000000000
(PID.TID 0000.0001) //          Total. X spins =              0
(PID.TID 0000.0001) //            Avg. X spins =       0.00E+00
(PID.TID 0000.0001) //         No. Y exchanges =              0
(PID.TID 0000.0001) //            Max. Y spins =              0
(PID.TID 0000.0001) //            Min. Y spins =     1000000000
(PID.TID 0000.0001) //          Total. Y spins =              0
(PID.TID 0000.0001) //            Avg. Y spins =       0.00E+00
(PID.TID 0000.0001) // o Tile number: 000002
(PID.TID 0000.0001) //         No. X exchanges =              0
(PID.TID 0000.0001) //            Max. X spins =              0
(PID.TID 0000.0001) //            Min. X spins =     1000000000
(PID.TID 0000.0001) //          Total. X spins =              0
(PID.TID 0000.0001) //            Avg. X spins =       0.00E+00
(PID.TID 0000.0001) //         No. Y exchanges =              0
(PID.TID 0000.0001) //            Max. Y spins =              0
(PID.TID 0000.0001) //            Min. Y spins =     1000000000
(PID.TID 0000.0001) //          Total. Y spins =              0
(PID.TID 0000.0001) //            Avg. Y spins =       0.00E+00
(PID.TID 0000.0001) // o Tile number: 000003
(PID.TID 0000.0001) //         No. X exchanges =              0
(PID.TID 0000.0001) //            Max. X spins =              0
(PID.TID 0000.0001) //            Min. X spins =     1000000000
(PID.TID 0000.0001) //          Total. X spins =              0
(PID.TID 0000.0001) //            Avg. X spins =       0.00E+00
(PID.TID 0000.0001) //         No. Y exchanges =              0
(PID.TID 0000.0001) //            Max. Y spins =              0
(PID.TID 0000.0001) //            Min. Y spins =     1000000000
(PID.TID 0000.0001) //          Total. Y spins =              0
(PID.TID 0000.0001) //            Avg. Y spins =       0.00E+00
(PID.TID 0000.0001) // o Tile number: 000004
(PID.TID 0000.0001) //         No. X exchanges =              0
(PID.TID 0000.0001) //            Max. X spins =              0
(PID.TID 0000.0001) //            Min. X spins =     1000000000
(PID.TID 0000.0001) //          Total. X spins =              0
(PID.TID 0000.0001) //            Avg. X spins =       0.00E+00
(PID.TID 0000.0001) //         No. Y exchanges =              0
(PID.TID 0000.0001) //            Max. Y spins =              0
(PID.TID 0000.0001) //            Min. Y spins =     1000000000
(PID.TID 0000.0001) //          Total. Y spins =              0
(PID.TID 0000.0001) //            Avg. Y spins =       0.00E+00
(PID.TID 0000.0001) // o Thread number: 000001
(PID.TID 0000.0001) //            No. barriers =          44328
(PID.TID 0000.0001) //      Max. barrier spins =              1
(PID.TID 0000.0001) //      Min. barrier spins =              1
(PID.TID 0000.0001) //     Total barrier spins =          44328
(PID.TID 0000.0001) //      Avg. barrier spins =       1.00E+00
PROGRAM MAIN: Execution ended Normally
