source: NEMO/trunk/tests/OVERFLOW/EXPREF/AGRIF/1_namelist_cfg

!!>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>
!! NEMO/OCE  Configuration namelist : used to overwrite defaults values defined in SHARED/namelist_ref
!!>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>
!
!-----------------------------------------------------------------------
&namusr_def    !   User defined :   OVERFLOW configuration 
!-----------------------------------------------------------------------
   !                       !  type of vertical coordinate
   ln_zco      = .false.      ! z-coordinate
   ln_zps      = .true.       ! z-partial-step coordinate
   ln_sco      = .false.      ! s-coordinate   
   rn_dx       =   1000.   !  horizontal resolution   [meters]
   rn_dz       =     50.   !  vertical   resolution   [meters]
/
!
!-----------------------------------------------------------------------
&namagrif      !  AGRIF zoom                                            ("key_agrif")
!-----------------------------------------------------------------------
   ln_vert_remap   = .true.  !  use vertical remapping
/
!-----------------------------------------------------------------------
&namrun        !   parameters of the run
!-----------------------------------------------------------------------
   nn_no       =       0   !  job number (no more used...)
   cn_exp      =    "OVF"  !  experience name
   nn_it000    =       1   !  first time step
   nn_itend    =    1530   ! here 16h of simulation  (=5760 time-step) abort after 5802 for zps: pb of physics conditions
   nn_istate   =       0   !  output the initial state (1) or not (0)
   nn_stock    =    9999   !  frequency of creation of a restart file (modulo referenced to 1)
   nn_write    =    9999   !  frequency of write in the output file   (modulo referenced to nn_it000)
/
!-----------------------------------------------------------------------
&namcfg        !   parameters of the configuration
!-----------------------------------------------------------------------
   ln_read_cfg = .true.     !  (=T) read the domain configuration file
      !                     !  (=F) user defined configuration           (F => create/check namusr_def)
      cn_domcfg = "OVF_domcfg"  ! domain configuration filename
      !
/
!-----------------------------------------------------------------------
&namtile        !   parameters of the tiling
!-----------------------------------------------------------------------
/
!-----------------------------------------------------------------------
&namdom        !   space and time domain (bathymetry, mesh, timestep)
!-----------------------------------------------------------------------
   rn_Dt      =   40.     !  time step for the dynamics (and tracer if nn_acc=0)
   rn_atfp    =    0.1    !  asselin time filter parameter
   ln_meshmask = .false.  !  =T create a mesh file
/
!-----------------------------------------------------------------------
&namtsd    !   data : Temperature  & Salinity
!-----------------------------------------------------------------------
/
!-----------------------------------------------------------------------
&namsbc        !   Surface Boundary Condition (surface module)
!-----------------------------------------------------------------------
  nn_fsbc     = 1         !  frequency of surface boundary condition computation
                          !     (also = the frequency of sea-ice & iceberg model call)
  ln_usr      = .true.    !  user defined formulation                  (T => check usrdef_sbc)
  ln_blk      = .false.   !  Bulk formulation                          (T => fill namsbc_blk )
  nn_ice      = 0         !  =0 no ice boundary condition   
  ln_traqsr   = .false.   !  Light penetration in the ocean            (T => fill namtra_qsr )
  ln_rnf      = .false.   !  runoffs                                   (T => fill namsbc_rnf)
  ln_ssr      = .false.   !  Sea Surface Restoring on T and/or S       (T => fill namsbc_ssr)
  nn_fwb      = 0         !  FreshWater Budget: =0 unchecked
/
!-----------------------------------------------------------------------
&namlbc        !   lateral momentum boundary condition                  (default: NO selection)
!-----------------------------------------------------------------------
   rn_shlat    =    0.     !  free slip
/
!!======================================================================
!!                ***  Top/Bottom boundary condition  ***             !!
!!======================================================================
!!   namdrg        top/bottom drag coefficient                          (default: NO selection)
!!   namdrg_top    top    friction                                      (ln_isfcav=T)
!!   namdrg_bot    bottom friction
!!   nambbc        bottom temperature boundary condition                (default: OFF)
!!   nambbl        bottom boundary layer scheme                         (default: OFF)
!!======================================================================
!
!-----------------------------------------------------------------------
&namdrg            !   top/bottom drag coefficient                      (default: NO selection)
!-----------------------------------------------------------------------
   ln_drg_OFF = .true.     !  free-slip       : Cd = 0                  (F => fill namdrg_bot
   ln_lin     = .false.    !      linear  drag: Cd = Cd0 Uc0                   &   namdrg_top)
   ln_non_lin = .false.    !  non-linear  drag: Cd = Cd0 |U|
   ln_loglayer = .false.   !  logarithmic drag: Cd = vkarmn/log(z/z0) |U|
   !
   ln_drgimp  = .true.     !  implicit top/bottom friction flag
/
!-----------------------------------------------------------------------
&nameos        !   ocean physical parameters
!-----------------------------------------------------------------------
   ln_seos     = .true.         !  = Use simplified equation of state (S-EOS)
   !                             !  rd(T,S,Z)*rau0 = -a0*(1+.5*lambda*dT+mu*Z+nu*dS)*dT+b0*dS
   rn_a0       =  0.2         !  thermal expension coefficient (for simplified equation of state)
   rn_b0       =  0.          !  saline  expension coefficient (for simplified equation of state)
   rn_lambda1  =  0.          !  cabbeling coeff in T^2  (=0 for linear eos)
   rn_lambda2  =  0.          !  cabbeling coeff in S^2  (=0 for linear eos)
   rn_mu1      =  0.          !  thermobaric coeff. in T (=0 for linear eos)
   rn_mu2      =  0.          !  thermobaric coeff. in S (=0 for linear eos)
   rn_nu       =  0.          !  cabbeling coeff in T*S  (=0 for linear eos)
/
!-----------------------------------------------------------------------
&namtra_adv    !   advection scheme for tracer
!-----------------------------------------------------------------------
   ln_traadv_cen = .false. !  2nd order centered scheme
      nn_cen_h   =  4            !  =2/4, horizontal 2nd order CEN / 4th order CEN
      nn_cen_v   =  4            !  =2/4, vertical   2nd order CEN / 4th order COMPACT
   ln_traadv_fct = .true. !  FCT scheme
      nn_fct_h   =  2            !  =2/4, horizontal 2nd / 4th order
      nn_fct_v   =  2            !  =2/4, vertical   2nd / COMPACT 4th order
   ln_traadv_mus = .false. !  MUSCL scheme
      ln_mus_ups = .false.       !  use upstream scheme near river mouths
   ln_traadv_ubs = .false. !  UBS scheme
      nn_ubs_v   =  2            !  =2  , vertical 2nd order FCT / COMPACT 4th order
   ln_traadv_qck = .false. !  QUICKEST scheme
/
!-----------------------------------------------------------------------
&namtra_ldf    !   lateral diffusion scheme for tracers
!-----------------------------------------------------------------------
   !                       !  Operator type:    both false = No lateral diffusion
   ln_traldf_OFF   =  .true.  !  No explicit diffusion
   ln_traldf_lap   =  .false.  !    laplacian operator
   ln_traldf_blp   =  .false.  !  bilaplacian operator
/

!!======================================================================
!!                      ***  Dynamics namelists  ***                  !!
!!======================================================================
!
!-----------------------------------------------------------------------
&namdyn_adv    !   formulation of the momentum advection                (default: NO selection)
!-----------------------------------------------------------------------
   ln_dynadv_OFF = .false. !  linear dynamics (no momentum advection)
   ln_dynadv_vec = .false. !  vector form (T) or flux form (F)
   nn_dynkeg     = 0       ! scheme for grad(KE): =0   C2  ;  =1   Hollingsworth correction
   ln_dynadv_cen2 = .false. !  flux form - 2nd order centered scheme
   ln_dynadv_ubs = .true.  !  flux form - 3rd order UBS      scheme
/
!-----------------------------------------------------------------------
&nam_vvl    !   vertical coordinate options                             (default: zstar)
!-----------------------------------------------------------------------
   ln_vvl_zstar  = .true.           !  zstar vertical coordinate
/
!-----------------------------------------------------------------------
&namdyn_vor    !   option of physics/algorithm
!-----------------------------------------------------------------------
   ln_dynvor_ene = .false. !  enstrophy conserving scheme
   ln_dynvor_ens = .true.  !  energy conserving scheme
   ln_dynvor_mix = .false. !  mixed scheme
   ln_dynvor_een = .false. !  energy & enstrophy scheme
/
!-----------------------------------------------------------------------
&namdyn_hpg    !   Hydrostatic pressure gradient option
!-----------------------------------------------------------------------
   ln_hpg_zps  = .false.  !  z-coordinate - partial steps (interpolation)
   ln_hpg_sco  = .true.   !  s-coordinate (standard jacobian formulation)
/
!-----------------------------------------------------------------------
&namdyn_spg    !   Surface pressure gradient
!-----------------------------------------------------------------------
   ln_dynspg_ts  = .true.   ! split-explicit free surface
      ln_bt_fw      = .true.     ! Forward integration of barotropic Eqs.
      ln_bt_av      = .true.     ! Time filtering of barotropic variables
         nn_bt_flt     = 1          ! Time filter choice  = 0 None
         !                          !                     = 1 Boxcar over   nn_e sub-steps
         !                          !                     = 2 Boxcar over 2*nn_e  "    "
      ln_bt_auto    = .true.     ! Number of sub-step defined from:
         nn_e      =  1         ! =F : the number of sub-step in rn_Dt seconds
/
!-----------------------------------------------------------------------
&namdyn_ldf    !   lateral diffusion on momentum                        (default: NO selection)
!-----------------------------------------------------------------------
   !                       !  Type of the operator :
   ln_dynldf_OFF =  .true.    !  No operator (i.e. no explicit diffusion)
   ln_dynldf_lap =  .false.    !    laplacian operator
   ln_dynldf_blp =  .false.    !  bilaplacian operator
   !                       !  Direction of action  :
   ln_dynldf_lev =  .false.    !  iso-level
   ln_dynldf_hor =  .false.    !  horizontal (geopotential)
   ln_dynldf_iso =  .false.    !  iso-neutral
   !                       !  Coefficient
   nn_ahm_ijk_t  = 0           !  space/time variation of eddy coef
      !                             !  =  0  constant 
      !                        !  time invariant coefficients :  ahm = 1/2  Uv*Lv   (lap case) 
      !                             !                            bhm = 1/12 Uv*Lv^3 (blp case)
      rn_Uv      = 2.0              !  lateral viscous velocity [m/s] (nn_ahm_ijk_t= 0, 10, 20, 30)
      rn_Lv      = 1000.            !  lateral viscous length   [m]   (nn_ahm_ijk_t= 0, 10)
/

!!======================================================================
!!                     vertical physics namelists                     !!
!!======================================================================
!-----------------------------------------------------------------------
&namzdf        !   vertical physics                                     (default: NO selection)
!-----------------------------------------------------------------------
   ln_zad_Aimp = .true.      !  Courant number dependent scheme (Shchepetkin 2015)
   !                       ! type of vertical closure (required)
   ln_zdfcst   = .true.      !  constant mixing
   ln_zdfric   = .false.      !  local Richardson dependent formulation (T =>   fill namzdf_ric)
   ln_zdftke   = .false.      !  Turbulent Kinetic Energy closure       (T =>   fill namzdf_tke)
   ln_zdfgls   = .false.      !  Generic Length Scale closure           (T =>   fill namzdf_gls)
   ln_zdfosm   = .false.      !  OSMOSIS BL closure                     (T =>   fill namzdf_osm)
   !   
   !                       ! convection
   ln_zdfevd   = .false.      !  enhanced vertical diffusion
      nn_evdm     =    0         ! apply on tracer (=0) or on tracer and momentum (=1) 
      rn_evd      =  100.        ! mixing coefficient [m2/s]
   ln_zdfnpc   = .false.      !  Non-Penetrative Convective algorithm
      nn_npc      =    1         ! frequency of application of npc 
      nn_npcp     =  365         ! npc control print frequency
   !   
   ln_zdfddm   = .false.   ! double diffusive mixing
      rn_avts  =    1.e-4     !  maximum avs (vertical mixing on salinity)
      rn_hsbfr =    1.6       !  heat/salt buoyancy flux ratio
   !   
   !                       ! gravity wave-driven vertical mixing
   ln_zdfiwm   = .false.      ! internal wave-induced mixing            (T =>   fill namzdf_iwm)
   ln_zdfswm   = .false.      ! surface  wave-induced mixing            (T => ln_wave=ln_sdw=T )
   !   
   !                       ! coefficients
   rn_avm0     =   1.e-4     !  vertical eddy viscosity   [m2/s]       (background Kz if ln_zdfcst=F)
   rn_avt0     =   0.0       !  vertical eddy diffusivity [m2/s]       (background Kz if ln_zdfcst=F)
   nn_avb      =    0        !  profile for background avt & avm (=1) or not (=0)
   nn_havtb    =    0        !  horizontal shape for avtb (=1) or not (=0)
/
!-----------------------------------------------------------------------
&nammpp        !   Massively Parallel Processing
!-----------------------------------------------------------------------
   jpni        =  12       !  number of processors following i (set automatically if < 1), see also ln_listonly = T
   jpnj        =   1       !  number of processors following j (set automatically if < 1), see also ln_listonly = T
/
!-----------------------------------------------------------------------
&namctl        !   Control prints & Benchmark
!-----------------------------------------------------------------------
/