source: branches/dev_004_VVL/NEMO/OPA_SRC/step.F90 @ 1433

MODULE step
   !!======================================================================
   !!                       ***  MODULE step  ***
   !! Time-stepping    : manager of the ocean, tracer and ice time stepping
   !!======================================================================
   !! History :  OPA  !  1991-03  (G. Madec)  Original code
   !!                 !  1991-11  (G. Madec)
   !!                 !  1992-06  (M. Imbard)  add a first output record
   !!                 !  1996-04  (G. Madec)  introduction of dynspg
   !!                 !  1996-04  (M.A. Foujols)  introduction of passive tracer
   !!            8.0  !  1997-06  (G. Madec)  new architecture of call
   !!            8.2  !  1997-06  (G. Madec, M. Imbard, G. Roullet)  free surface
   !!             -   !  1999-02  (G. Madec, N. Grima)  hpg implicit
   !!             -   !  2000-07  (J-M Molines, M. Imbard)  Open Bondary Conditions
   !!   NEMO     1.0  !  2002-06  (G. Madec)  free form, suppress macro-tasking
   !!             -   !  2004-08  (C. Talandier) New trends organization
   !!                 !  2005-01  (C. Ethe) Add the KPP closure scheme
   !!                 !  2005-11  (G. Madec)  Reorganisation of tra and dyn calls
   !!                 !  2006-01  (L. Debreu, C. Mazauric)  Agrif implementation
   !!                 !  2006-07  (S. Masson)  restart using iom
   !!            3.2  !  2009-02  (G. Madec, R. Benshila)  reintroduicing z*-coordinate
   !!----------------------------------------------------------------------

   !!----------------------------------------------------------------------
   !!   stp            : OPA system time-stepping
   !!----------------------------------------------------------------------
   USE oce             ! ocean dynamics and tracers variables
   USE dom_oce         ! ocean space and time domain variables 
   USE zdf_oce         ! ocean vertical physics variables
   USE ldftra_oce      ! ocean tracer   - trends
   USE ldfdyn_oce      ! ocean dynamics - trends
   USE in_out_manager  ! I/O manager
   USE iom             !
   USE lbclnk

   USE daymod          ! calendar                         (day     routine)

   USE dtatem          ! ocean temperature data           (dta_tem routine)
   USE dtasal          ! ocean salinity    data           (dta_sal routine)
   USE sbcmod          ! surface boundary condition       (sbc     routine)
   USE sbcrnf          ! surface boundary condition: runoff variables
   USE sbccpl          ! surface boundary condition: coupled formulation (call send at end of step)
   USE cpl_oasis3, ONLY : lk_cpl

   USE trcstp          ! passive tracer time-stepping      (trc_stp routine)

   USE traqsr          ! solar radiation penetration      (tra_qsr routine)
   USE trasbc          ! surface boundary condition       (tra_sbc routine)
   USE trabbc          ! bottom boundary condition        (tra_bbc routine)
   USE trabbl          ! bottom boundary layer            (tra_bbl routine)
   USE tradmp          ! internal damping                 (tra_dmp routine)
   USE traadv          ! advection scheme control     (tra_adv_ctl routine)
   USE traldf          ! lateral mixing                   (tra_ldf routine)
   USE cla             ! cross land advection             (tra_cla routine)
   !   zdfkpp          ! KPP non-local tracer fluxes      (tra_kpp routine)
   USE trazdf          ! vertical mixing                  (tra_zdf routine)
   USE tranxt          ! time-stepping                    (tra_nxt routine)
   USE tranpc          ! non-penetrative convection       (tra_npc routine)

   USE eosbn2          ! equation of state                (eos_bn2 routine)

   USE dynadv          ! advection                        (dyn_adv routine)
   USE dynvor          ! vorticity term                   (dyn_vor routine)
   USE dynhpg          ! hydrostatic pressure grad.       (dyn_hpg routine)
   USE dynldf          ! lateral momentum diffusion       (dyn_ldf routine)
   USE dynzdf          ! vertical diffusion               (dyn_zdf routine)
   USE dynspg_oce      ! surface pressure gradient        (dyn_spg routine)
   USE dynspg          ! surface pressure gradient        (dyn_spg routine)
   USE dynnxt          ! time-stepping                    (dyn_nxt routine)

   USE obc_par         ! open boundary condition variables
   USE obcdta          ! open boundary condition data     (obc_dta routine)
   USE obcrst          ! open boundary cond. restart      (obc_rst routine)
   USE obcrad          ! open boundary cond. radiation    (obc_rad routine)
   USE obcspg          ! open boundary cond  spg          (obc_spg routine)

   USE bdy_par         ! unstructured open boundary data variables
   USE bdydta          ! unstructured open boundary data  (bdy_dta routine)

   USE divcur          ! hor. divergence and curl      (div & cur routines)
   USE cla_div         ! cross land: hor. divergence      (div_cla routine)
   USE wzvmod          ! vertical velocity                (wzv     routine)

   USE ldfslp          ! iso-neutral slopes               (ldf_slp routine)
   USE ldfeiv          ! eddy induced velocity coef.      (ldf_eiv routine)

   USE zdftmx          ! tide-induced vertical mixing     (zdf_tmx routine)
   USE zdfbfr          ! bottom friction                  (zdf_bfr routine)
   USE zdftke          ! TKE vertical mixing              (zdf_tke routine)
   USE zdftke2         ! TKE2 vertical mixing             (zdf_tke2 routine)
   USE zdfkpp          ! KPP vertical mixing              (zdf_kpp routine)
   USE zdfddm          ! double diffusion mixing          (zdf_ddm routine)
   USE zdfevd          ! enhanced vertical diffusion      (zdf_evd routine)
   USE zdfric          ! Richardson vertical mixing       (zdf_ric routine)
   USE zdfmxl          ! Mixed-layer depth                (zdf_mxl routine)

   USE zpshde          ! partial step: hor. derivative     (zps_hde routine)
   USE ice_oce         ! sea-ice variable

   USE diawri          ! Standard run outputs             (dia_wri routine)
   USE trdicp          ! Ocean momentum/tracers trends    (trd_wri routine)
   USE trdmld          ! mixed-layer trends               (trd_mld routine)
   USE trdmld_rst      ! restart for mixed-layer trends
   USE trdmod_oce      ! ocean momentum/tracers trends
   USE trdvor          ! vorticity budget                 (trd_vor routine)
   USE diagap          ! hor. mean model-data gap         (dia_gap routine)
   USE diahdy          ! dynamic height                   (dia_hdy routine)
   USE diaptr          ! poleward transports              (dia_ptr routine)
   USE diahth          ! thermocline depth                (dia_hth routine)
   USE diafwb          ! freshwater budget                (dia_fwb routine)
   USE diaspr          ! suface pressure (rigid-lid)      (dia_spr routine)
   USE flo_oce         ! floats variables
   USE floats          ! floats computation               (flo_stp routine)

   USE stpctl          ! time stepping control            (stp_ctl routine)
   USE restart         ! ocean restart                    (rst_wri routine)
   USE prtctl          ! Print control                    (prt_ctl routine)

#if defined key_agrif
   USE agrif_opa_sponge ! Momemtum and tracers sponges
#endif

   IMPLICIT NONE
   PRIVATE

   PUBLIC stp            ! called by opa.F90

   !! * Substitutions
#  include "domzgr_substitute.h90"
#  include "zdfddm_substitute.h90"
   !!----------------------------------------------------------------------
   !!   OPA 9.0 , LOCEAN-IPSL (2005) 
   !! $Id$
   !! Software governed by the CeCILL licence (modipsl/doc/NEMO_CeCILL.txt) 
   !!----------------------------------------------------------------------

CONTAINS

#if defined key_agrif
   SUBROUTINE stp( )
      INTEGER             ::   kstp   ! ocean time-step index
#else
   SUBROUTINE stp( kstp )
      INTEGER, INTENT(in) ::   kstp   ! ocean time-step index
#endif
      !!----------------------------------------------------------------------
      !!                     ***  ROUTINE stp  ***
      !!                      
      !! ** Purpose : - Time stepping of OPA (momentum and active tracer eqs.)
      !!              - Time stepping of LIM (dynamic and thermodynamic eqs.)
      !!              - Tme stepping  of TRC (passive tracer eqs.)
      !! 
      !! ** Method  : -1- Update forcings and data  
      !!              -2- Update ocean physics 
      !!              -3- Compute the t and s trends 
      !!              -4- Update t and s 
      !!              -5- Compute the momentum trends
      !!              -6- Update the horizontal velocity
      !!              -7- Compute the diagnostics variables (rd,N2, div,cur,w)
      !!              -8- Outputs and diagnostics
      !!----------------------------------------------------------------------
      INTEGER ::   jk       ! dummy loop indice
      INTEGER ::   indic    ! error indicator if < 0
      !! ---------------------------------------------------------------------

#if defined key_agrif
      kstp = nit000 + Agrif_Nb_Step()
!      IF ( Agrif_Root() .and. lwp) Write(*,*) '---'
!      IF (lwp) Write(*,*) 'Grid Number',Agrif_Fixed(),' time step ',kstp
#endif   
      indic = 1                    ! reset to no error condition

      CALL day( kstp )             ! Calendar

      CALL iom_setkt( kstp )       ! say to iom that we are at time step kstp
      
      CALL rst_opn( kstp )         ! Open the restart file

      !>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>
      ! Update data, open boundaries, surface boundary condition (including sea-ice)
      !<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<

      IF( lk_dtatem  )   CALL dta_tem( kstp )         ! update 3D temperature data
      IF( lk_dtasal  )   CALL dta_sal( kstp )         ! update 3D salinity data

                         CALL sbc    ( kstp )         ! Sea Boundary Condition (including sea-ice)

      IF( lk_obc     )   CALL obc_dta( kstp )         ! update dynamic and tracer data at open boundaries
      IF( lk_obc     )   CALL obc_rad( kstp )         ! compute phase velocities at open boundaries

      IF( lk_bdy     )   CALL bdy_dta( kstp )         ! update dynamic and tracer data at unstructured open boundary

      IF( ninist == 1 ) THEN                       ! Output the initial state and forcings
                        CALL dia_wri_state( 'output.init', kstp )
                        ninist = 0
      ENDIF

      !>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>
      !                Ocean dynamics : ssh, wn, hdiv, rot                   !
      !<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<
                       CALL div_cur( kstp )                 ! Horizontal divergence & Relative vorticity
      IF( n_cla == 1 ) CALL div_cla( kstp )                 ! Cross Land Advection (Update Hor. divergence)
                       CALL ssh_wzv( kstp )                 ! after ssh & vertical velocity

      !>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>
      ! Ocean physics update
      !<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<
      ! N.B. ua, va, ta, sa arrays are used as workspace in this section
      !-----------------------------------------------------------------------
      IF( neuler == 0 .AND. kstp == nit000 ) THEN
                        CALL bn2( tn, sn, rn2 )              ! now    Brunt-Vaisala frequency
                        rn2b(:,:,:) = rn2(:,:,:)
      ELSE
                        rn2b(:,:,:) = rn2(:,:,:)             ! before Brunt-Vaisala frequency  
                        CALL bn2( tn, sn, rn2 )              ! now    Brunt-Vaisala frequency
      ENDIF

#if defined key_zdftke2
      IF ( ln_dynhpg_imp ) THEN
      !-----------------------------------------------------------------------
      !  LATERAL PHYSICS
      !-----------------------------------------------------------------------
                               CALL zdf_mxl( kstp )                 ! mixed layer depth
         IF( lk_ldfslp     )   CALL ldf_slp( kstp, rhd, rn2b )      ! before slope of the lateral mixing
#  if defined key_traldf_c2d
         IF( lk_traldf_eiv )   CALL ldf_eiv( kstp )                 ! eddy induced velocity coefficient
#  endif
      ENDIF
#endif
      !-----------------------------------------------------------------------
      !  VERTICAL PHYSICS
      !-----------------------------------------------------------------------
      !                                                     ! Vertical eddy viscosity and diffusivity coefficients
      IF( lk_zdfric )   CALL zdf_ric( kstp )                       ! Richardson number dependent Kz

      IF( lk_zdftke )   CALL zdf_tke ( kstp )                      ! TKE  closure scheme for Kz
      IF( lk_zdftke2)   CALL zdf_tke2( kstp )                      ! TKE2 closure scheme for Kz

      IF( lk_zdfkpp )   CALL zdf_kpp( kstp )                       ! KPP closure scheme for Kz

      IF( lk_zdfcst )   THEN                                       ! Constant Kz (reset avt, avm[uv] to the background value)
         avt (:,:,:) = avt0 * tmask(:,:,:)
         avmu(:,:,:) = avm0 * umask(:,:,:)
         avmv(:,:,:) = avm0 * vmask(:,:,:)
      ENDIF

      IF( ln_rnf_mouth ) THEN                                ! increase diffusivity at rivers mouths
         DO jk = 2, nkrnf   ;   avt(:,:,jk) = avt(:,:,jk) + 2.e0 * rn_avt_rnf * rnfmsk(:,:) * tmask(:,:,jk)   ;   END DO
      ENDIF

      IF( ln_zdfevd )   CALL zdf_evd( kstp )                 ! enhanced vertical eddy diffusivity

      IF( lk_zdfddm .AND. .NOT. lk_zdfkpp )   &
         &              CALL zdf_ddm( kstp )                 ! double diffusive mixing

      IF( lk_zdftmx )   CALL zdf_tmx( kstp )                 ! tidal vertical mixing

                        CALL zdf_bfr( kstp )                 ! bottom friction

                        CALL zdf_mxl( kstp )                 ! mixed layer depth

#if defined key_zdftke2
      IF( .NOT. ln_dynhpg_imp ) THEN
                        CALL eos( tb, sb, rhd, rhop )        ! now (swap=before) in situ density for dynhpg module
#endif
      !-----------------------------------------------------------------------
      !  LATERAL PHYSICS
      !-----------------------------------------------------------------------
      IF( lk_ldfslp     )   CALL ldf_slp( kstp, rhd, rn2b )      ! before slope of the lateral mixing
#if defined key_traldf_c2d
      IF( lk_traldf_eiv )   CALL ldf_eiv( kstp )                 ! eddy induced velocity coefficient
#  endif
#if defined key_zdftke2
      ENDIF
#endif

#if defined key_top
      !>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>
      ! Passive Tracer Model
      !<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<
      ! N.B. ua, va, ta, sa arrays are used as workspace in this section
      !-----------------------------------------------------------------------
                             CALL trc_stp( kstp, indic )            ! time-stepping
#endif

      !>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>
      ! Active tracers
      !<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<
      ! N.B. ua, va arrays are used as workspace in this section
      !-----------------------------------------------------------------------
                             ta(:,:,:) = 0.e0               ! set tracer trends to zero
                             sa(:,:,:) = 0.e0

                             CALL tra_sbc    ( kstp )       ! surface boundary condition
      IF( ln_traqsr      )   CALL tra_qsr    ( kstp )       ! penetrative solar radiation qsr
      IF( lk_trabbc      )   CALL tra_bbc    ( kstp )       ! bottom heat flux
      IF( lk_trabbl_dif  )   CALL tra_bbl_dif( kstp )       ! diffusive bottom boundary layer scheme
      IF( lk_trabbl_adv  )   CALL tra_bbl_adv( kstp )       ! advective (and/or diffusive) bottom boundary layer scheme
      IF( lk_tradmp      )   CALL tra_dmp    ( kstp )       ! internal damping trends
                             CALL tra_adv    ( kstp )       ! horizontal & vertical advection
      IF( n_cla == 1     )   CALL tra_cla    ( kstp )       ! Cross Land Advection (Update Hor. advection)
      IF( lk_zdfkpp )        CALL tra_kpp    ( kstp )       ! KPP non-local tracer fluxes
                             CALL tra_ldf    ( kstp )       ! lateral mixing
#if defined key_agrif
      IF(.NOT. Agrif_Root()) CALL Agrif_Sponge_tra          ! tracers sponge
#endif
                             CALL tra_zdf    ( kstp )       ! vertical mixing and after tracer fields

#if ! defined key_zdftke2
      IF( ln_zdfnpc      )   CALL tra_npc    ( kstp )       ! update after fields by non-penetrative convection
                             CALL tra_nxt    ( kstp )       ! tracer fields at next time step

      IF( ln_dynhpg_imp  ) THEN                             ! semi-implicit hpg
                               CALL eos( ta, sa, rhd, rhop )          ! Time-filtered in situ density used in dynhpg module
         IF( ln_zps    )       CALL zps_hde( kstp, ta, sa, rhd,   &   ! Partial steps: time filtered hor. gradient
            &                                     gtu, gsu, gru,  &   ! of t, s, rd at the bottom ocean level
            &                                     gtv, gsv, grv )
      ELSE                                                  ! centered hpg (default case)
                               CALL eos( tb, sb, rhd, rhop )          ! now (swap=before) in situ density for dynhpg module
         IF( ln_zps    )       CALL zps_hde( kstp, tb, sb, rhd,   &   ! Partial steps: now horizontal gradient
            &                                     gtu, gsu, gru,  &   ! of t, s, rd at the bottom ocean level
            &                                     gtv, gsv, grv )
      ENDIF
#else
      IF( .NOT. ln_dynhpg_imp  ) THEN                       ! centered hpg (default case)
                               CALL eos( tn, sn, rhd, rhop )          ! now (swap=before) in situ density for dynhpg module
         IF( ln_zps    )       CALL zps_hde( kstp, tn, sn, rhd,   &   ! Partial steps: now horizontal gradient
            &                                     gtu, gsu, gru,  &   ! of t, s, rd at the bottom ocean level
            &                                     gtv, gsv, grv )
      ENDIF 
      IF( ln_zdfnpc      )   CALL tra_npc    ( kstp )       ! update after fields by non-penetrative convection
                             CALL tra_nxt    ( kstp )       ! tracer fields at next time step
      IF( ln_dynhpg_imp  ) THEN                             ! semi-implicit hpg
                               CALL eos( ta, sa, rhd, rhop )          ! Time-filtered in situ density used in dynhpg module
         IF( lk_ldfslp     )   CALL bn2( ta, sa, rn2 )                ! Time-filtered Brunt-Vaisala frequency
         IF( ln_zps    )       CALL zps_hde( kstp, ta, sa, rhd,   &   ! Partial steps: time filtered hor. gradient
            &                                     gtu, gsu, gru,  &   ! of t, s, rd at the bottom ocean level
            &                                     gtv, gsv, grv )
      ENDIF
#endif
      !>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>
      ! Dynamics
      !<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<
      ! N.B. ta, sa arrays are used as workspace in this section 
      !-----------------------------------------------------------------------
                               ua(:,:,:) = 0.e0               ! set dynamics trends to zero
                               va(:,:,:) = 0.e0

                               CALL dyn_adv( kstp )           ! advection (vector or flux form)
                               CALL dyn_vor( kstp )           ! vorticity term including Coriolis
                               CALL dyn_ldf( kstp )           ! lateral mixing
#if defined key_agrif
      IF(.NOT. Agrif_Root())   CALL Agrif_Sponge_dyn          ! momemtum sponge
#endif
                               CALL dyn_hpg( kstp )           ! horizontal gradient of Hydrostatic pressure
                               CALL dyn_zdf( kstp )           ! vertical diffusion
      IF( lk_dynspg_rl ) THEN
         IF( lk_obc    )       CALL obc_spg( kstp )           ! surface pressure gradient at open boundaries
      ENDIF
                               indic=0
                               CALL dyn_spg( kstp, indic )    ! surface pressure gradient
                               CALL dyn_nxt( kstp )           ! lateral velocity at next time step

                               CALL ssh_nxt( kstp )           ! sea surface height at next time step

      !>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>
      ! Control and restarts
      !<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<
                                 CALL stp_ctl( kstp, indic )
      IF( indic < 0          )   CALL ctl_stop( 'step: indic < 0' )
      IF( kstp == nit000     )   CALL iom_close( numror )             ! close input  ocean restart file
      IF( lrst_oce           )   CALL rst_write    ( kstp )           ! write output ocean restart file
      IF( lk_obc             )   CALL obc_rst_write( kstp )           ! write open boundary restart file

      !>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>
      ! diagnostics and outputs
      !<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<
      ! N.B. ua, va, ta, sa arrays are used as workspace in this section
      !-----------------------------------------------------------------------

      IF( nstop == 0 ) THEN                                 ! Diagnostics:
         IF( lk_floats  )   CALL flo_stp( kstp )                 ! drifting Floats
         IF( lk_trddyn  )   CALL trd_dwr( kstp )                 ! trends: dynamics 
         IF( lk_trdtra  )   CALL trd_twr( kstp )                 ! trends: active tracers
         IF( lk_trdmld  )   CALL trd_mld( kstp )                 ! trends: Mixed-layer 
         IF( lk_trdvor  )   CALL trd_vor( kstp )                 ! trends: vorticity budget
         IF( lk_diaspr  )   CALL dia_spr( kstp )                 ! Surface pressure diagnostics
         IF( lk_diahth  )   CALL dia_hth( kstp )                 ! Thermocline depth (20 degres isotherm depth)
         IF( lk_diagap  )   CALL dia_gap( kstp )                 ! basin averaged diagnostics
         IF( lk_diahdy  )   CALL dia_hdy( kstp )                 ! dynamical heigh diagnostics
         IF( lk_diafwb  )   CALL dia_fwb( kstp )                 ! Fresh water budget diagnostics
         IF( ln_diaptr  )   CALL dia_ptr( kstp )                 ! Poleward TRansports diagnostics
         !                                                 ! outputs
                            CALL dia_wri( kstp, indic )          ! ocean model: outputs
      ENDIF

      !>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>
      ! Coupled mode
      !<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<

      IF( lk_cpl )   CALL sbc_cpl_snd( kstp )                 ! coupled mode : field exchanges

#if defined key_zdftke2
      IF( ( kstp == nitend ).AND.( lrst_oce ) )  THEN

         CALL day( kstp+1 )             ! Calendar
         !>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>
         ! Update data, open boundaries, surface boundary condition (including sea-ice)
         !<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<
                            CALL sbc    ( kstp+1 )         ! Sea Boundary Condition (including sea-ice)
         !-----------------------------------------------------------------------
         !  VERTICAL PHYSICS
         !-----------------------------------------------------------------------
         ! N.B. ua, va, ta, sa arrays are used as workspace in this section
         !-----------------------------------------------------------------------
                            CALL bn2( tn, sn, rn2 )            ! now Brunt-Vaisala frequency
         !                                                     ! Vertical eddy viscosity and diffusivity coefficients
         IF( lk_zdftke2 )   CALL zdf_tke2 ( kstp+1 )           ! TKE2 closure scheme for Kz
                            CALL rst_write( kstp+1 )           ! close the restart file
      ENDIF
#endif
      !
   END SUBROUTINE stp

   !!======================================================================
END MODULE step