source: branches/2016/dev_r6859_LIM3_meltponds/NEMOGCM/NEMO/LIM_SRC_3/limmp.F90 @ 8099

MODULE limmp 
   !!======================================================================
   !!                     ***  MODULE  limmp   ***
   !!   Melt ponds
   !!======================================================================
   !! history :       ! Original code by Daniela Flocco and Adrian Turner
   !!            1.0  ! 2012    (O. Lecomte) Adaptation for scientific tests (NEMO3.1)
   !!            2.0  ! 2016    (O. Lecomte, C. Rousset, M. Vancoppenolle) Implementation in NEMO3.6
   !!----------------------------------------------------------------------
#if defined key_lim3
   !!----------------------------------------------------------------------
   !!   'key_lim3' :                                 LIM3 sea-ice model
   !!----------------------------------------------------------------------
   !!   lim_mp_init      : some initialization and namelist read
   !!   lim_mp           : main calling routine
   !!   lim_mp_topo      : main melt pond routine for the "topographic" formulation (FloccoFeltham)
   !!   lim_mp_area      : ??? compute melt pond fraction per category
   !!   lim_mp_perm      : computes permeability (should be a FUNCTION!)
   !!   calc_hpond       : computes melt pond depth
   !!   permeability_phy : computes permeability

   !!----------------------------------------------------------------------
   USE phycst           ! physical constants
   USE dom_oce          ! ocean space and time domain
!  USE sbc_ice          ! Surface boundary condition: ice   fields
   USE ice              ! LIM-3 variables
   USE lbclnk           ! lateral boundary conditions - MPP exchanges
   USE lib_mpp          ! MPP library
   USE wrk_nemo         ! work arrays
   USE in_out_manager   ! I/O manager
   USE lib_fortran      ! glob_sum
   USE timing           ! Timing
!  USE limcons          ! conservation tests
!  USE limctl           ! control prints
!  USE limvar

!OLI_CODE    USE ice_oce, ONLY: rdt_ice, tatm_ice
!OLI_CODE    USE phycst
!OLI_CODE    USE dom_ice
!OLI_CODE    USE dom_oce
!OLI_CODE    USE sbc_oce
!OLI_CODE    USE sbc_ice
!OLI_CODE    USE par_ice
!OLI_CODE    USE par_oce
!OLI_CODE    USE ice
!OLI_CODE    USE thd_ice
!OLI_CODE    USE in_out_manager
!OLI_CODE    USE lbclnk
!OLI_CODE    USE lib_mpp
!OLI_CODE 
!OLI_CODE    IMPLICIT NONE
!OLI_CODE    PRIVATE
!OLI_CODE 
!OLI_CODE    PUBLIC   lim_mp_init
!OLI_CODE    PUBLIC   lim_mp

   IMPLICIT NONE
   PRIVATE

   PUBLIC   lim_mp_init    ! routine called by sbcice_lim.F90
   PUBLIC   lim_mp         ! routine called by sbcice_lim.F90

   !! * Substitutions
#  include "vectopt_loop_substitute.h90"
   !!----------------------------------------------------------------------
   !! NEMO/LIM3 4.0 , UCL - NEMO Consortium (2011)
   !! $Id: limdyn.F90 6994 2016-10-05 13:07:10Z clem $
   !! Software governed by the CeCILL licence     (NEMOGCM/NEMO_CeCILL.txt)
   !!----------------------------------------------------------------------
CONTAINS

   SUBROUTINE lim_mp_init 
      !!-------------------------------------------------------------------
      !!                  ***  ROUTINE lim_mp_init   ***
      !!
      !! ** Purpose : Physical constants and parameters linked to melt ponds
      !!      over sea ice
      !!
      !! ** Method  :  Read the namicemp  namelist and check the melt pond  
      !!       parameter values called at the first timestep (nit000)
      !!
      !! ** input   :   Namelist namicemp  
      !!-------------------------------------------------------------------
      INTEGER  ::   ios                 ! Local integer output status for namelist read
      NAMELIST/namicemp/  ln_pnd, nn_pnd_scheme, nn_pnd_cpl, rn_apnd, rn_hpnd
      !!-------------------------------------------------------------------

      REWIND( numnam_ice_ref )              ! Namelist namicemp  in reference namelist : Melt Ponds  
      READ  ( numnam_ice_ref, namicemp, IOSTAT = ios, ERR = 901)
901   IF( ios /= 0 ) CALL ctl_nam ( ios , 'namicemp  in reference namelist', lwp )

      REWIND( numnam_ice_cfg )              ! Namelist namicemp  in configuration namelist : Melt Ponds
      READ  ( numnam_ice_cfg, namicemp, IOSTAT = ios, ERR = 902 )
902   IF( ios /= 0 ) CALL ctl_nam ( ios , 'namicemp in configuration namelist', lwp )
      IF(lwm) WRITE ( numoni, namicemp )
      
      ! Shortcut for radiatively active melt ponds
      ln_pnd_rad = ln_pnd .AND. ( ( nn_pnd_cpl == 1 ) .OR. ( nn_pnd_cpl == 2 ) )

      IF(lwp) THEN                        ! control print
         WRITE(numout,*)
         WRITE(numout,*) 'lim_mp_init : ice parameters for melt ponds'
         WRITE(numout,*) '~~~~~~~~~~~~'
         WRITE(numout,*)'    Activate melt ponds                                         ln_pnd        = ', ln_pnd
         WRITE(numout,*)'    Type of melt pond scheme =0 presc, =1 empirical = 2 topo    nn_pnd_scheme = ', nn_pnd_scheme
         WRITE(numout,*)'    Type of melt pond coupling =0 pass., =1 full, =2 rad, 3=fw  nn_pnd_cpl    = ', nn_pnd_cpl
         WRITE(numout,*)'    Prescribed pond fraction                                    rn_apnd       = ', rn_apnd
         WRITE(numout,*)'    Prescribed pond depth                                       rn_hpnd       = ', rn_hpnd
         WRITE(numout,*)'    Melt ponds radiatively active                               ln_pnd_rad    = ', ln_pnd_rad
      ENDIF

      IF ( .NOT. ln_pnd ) THEN
         WRITE(numout,*)
         WRITE(numout,*) ' Melt ponds are not activated '
         WRITE(numout,*) ' nn_pnd_scheme, nn_pnd_cpl, rn_apnd and rn_hpnd are set to zero '
         nn_pnd_scheme = 0
         nn_pnd_cpl    = 0
         rn_apnd       = 0._wp
         rn_hpnd       = 0._wp
      ENDIF


      !
   END SUBROUTINE lim_mp_init
   


   SUBROUTINE lim_mp( kt )
      !!-------------------------------------------------------------------
      !!               ***  ROUTINE lim_mp   ***
      !!               
      !! ** Purpose :   change melt pond fraction
      !!                
      !! ** Method  :   brutal force
      !!
      !! ** Action  : - 
      !!              - 
      !!------------------------------------------------------------------------------------

      INTEGER, INTENT(in) :: kt    ! number of iteration
      INTEGER  ::   ji, jj, jl     ! dummy loop indices

!     REAL(wp), POINTER, DIMENSION(:,:) ::   zfsurf  ! surface heat flux(obsolete, should be droped)
      !
      !!-------------------------------------------------------------------

      IF( nn_timing == 1 )  CALL timing_start('limthd')

      IF( nn_timing == 1 )  CALL timing_start('lim_mp')

      SELECT CASE ( nn_pnd_scheme )

         CASE (0)

            CALL lim_mp_cstt       ! staircase melt ponds

         CASE (1)

            CALL lim_mp_cesm       ! empirical melt ponds

         CASE (2)

            CALL lim_mp_topo   &   ! topographic melt ponds 
                      &          (at_i, a_i,                                       &
                      &          vt_i, v_i, v_s,            t_i, s_i, a_ip_frac,   &
                      &          h_ip,     t_su)

      END SELECT

      ! we should probably not aggregate here since we do it in lim_var_agg
      ! before output, unless we need the total volume and faction else where

      ! we should also make sure a_ip and v_ip are properly updated at the end
      ! of the routine

   END SUBROUTINE lim_mp 

   SUBROUTINE lim_mp_cstt 
       !!-------------------------------------------------------------------
       !!                ***  ROUTINE lim_mp_cstt  ***
       !!
       !! ** Purpose    : Compute melt pond evolution
       !!
       !! ** Method     : Melt pond fraction and thickness are prescribed 
       !!                 to non-zero values when t_su = 0C
       !!
       !! ** Tunable parameters : pond fraction (rn_apnd), pond depth (rn_hpnd)
       !!                
       !! ** Note       : Coupling with such melt ponds is only radiative
       !!                 Advection, ridging, rafting... are bypassed
       !!
       !! ** References : Bush, G.W., and Trump, D.J. (2017)
       !!    
       !!-------------------------------------------------------------------
       INTEGER                             :: ji, jj, jl
       REAL(wp)                            :: z1_jpl            ! 1/jpl
       !!-------------------------------------------------------------------

       z1_jpl     = 1. / FLOAT(jpl)

       WHERE ( ( a_i > epsi10 ) .AND. ( t_su >= rt0-epsi06 ) ) 
          a_ip      = rn_apnd * z1_jpl 
          h_ip      = rn_hpnd    
          v_ip      = a_ip * h_ip 
          a_ip_frac = a_ip / a_i
       ELSE WHERE
          a_ip      = 0._wp
          h_ip      = 0._wp
          v_ip      = 0._wp
          a_ip_frac = 0._wp
       END WHERE

       wfx_pnd(:,:) = 0._wp

   END SUBROUTINE lim_mp_cstt

   SUBROUTINE lim_mp_cesm
       !!-------------------------------------------------------------------
       !!                ***  ROUTINE lim_mp_cesm  ***
       !!
       !! ** Purpose    : Compute melt pond evolution
       !!
       !! ** Method     : Empirical method. A fraction of meltwater is accumulated 
       !!                 in pond volume. It is then released exponentially when
       !!                 surface is freezing.
       !!
       !! ** Tunable parameters : (no expertise yet)
       !! 
       !! ** Note       : Stolen from CICE for quick test of the melt pond
       !!                 radiation and freshwater interfaces
       !!                 Coupling can be radiative AND freshwater
       !!                 Advection, ridging, rafting are called
       !!
       !! ** References : Holland, M. M. et al (J Clim 2012)
       !!    
       !!-------------------------------------------------------------------

       INTEGER, POINTER, DIMENSION(:)      :: indxi             ! compressed indices for cells with ice melting
       INTEGER, POINTER, DIMENSION(:)      :: indxj             !

       REAL(wp), POINTER, DIMENSION(:,:)   :: zwfx_mlw          ! available meltwater for melt ponding
       REAL(wp), POINTER, DIMENSION(:,:,:) :: zrfrac            ! fraction of available meltwater retained for melt ponding

       REAL(wp), PARAMETER                 :: zrmin  = 0.15_wp  ! minimum fraction of available meltwater retained for melt ponding
       REAL(wp), PARAMETER                 :: zrmax  = 0.70_wp  ! maximum   ''           ''       ''        ''            ''
       REAL(wp), PARAMETER                 :: zrexp  = 0.01_wp  ! rate constant to refreeze melt ponds
       REAL(wp), PARAMETER                 :: zpnd_aspect = 0.8_wp ! pond aspect ratio

       REAL(wp)                            :: zhi               ! dummy ice thickness
       REAL(wp)                            :: zhs               ! dummy snow depth
       REAL(wp)                            :: zTp               ! reference temperature
       REAL(wp)                            :: zdTs              ! dummy temperature difference
       REAL(wp)                            :: z1_rhofw          ! inverse freshwater density
       REAL(wp)                            :: z1_zpnd_aspect    ! inverse pond aspect ratio
       REAL(wp)                            :: zvpold            ! dummy pond volume

       INTEGER                             :: ji, jj, jl, ij    ! loop indices
       INTEGER                             :: icells            ! size of dummy array

       !!-------------------------------------------------------------------

       CALL wrk_alloc( jpi*jpj, indxi, indxj)
       CALL wrk_alloc( jpi,jpj,     zwfx_mlw )
       CALL wrk_alloc( jpi,jpj,jpl, zrfrac   )

       z1_rhofw       = 1. / rhofw 
       z1_zpnd_aspect = 1. / zpnd_aspect
       zTp            = -2. 

       !------------------------------------------------------------------
       ! Available melt water for melt ponding and corresponding fraction
       !------------------------------------------------------------------

       zwfx_mlw(:,:) = wfx_sum(:,:) + wfx_snw(:,:)        ! available meltwater for melt ponding

       zrfrac(:,:,:) = zrmin + ( zrmax - zrmin ) * a_i(:,:,:)  

       DO jl = 1, jpl   

          ! v_ip(:,:,jl) ! Initialize things
          ! a_ip(:,:,jl)
          ! volpn(:,:) = hpnd(:,:) * apnd(:,:) * aicen(:,:)

          !------------------------------------------------------------------------------
          ! Identify grid cells where ponds should be updated (can probably be improved)
          !------------------------------------------------------------------------------

          indxi(:) = 0
          indxj(:) = 0
          icells   = 0

          DO jj = 1, jpj
            DO ji = 1, jpi
               IF ( a_i(ji,jj,jl) > epsi10 ) THEN
                  icells = icells + 1
                  indxi(icells) = ji
                  indxj(icells) = jj
               ENDIF
            END DO                 ! ji
         END DO                    ! jj

         DO ij = 1, icells

            ji = indxi(ij)
            jj = indxj(ij)

            zhi = v_i(ji,jj,jl) / a_i(ji,jj,jl)
            zhs = v_s(ji,jj,jl) / a_i(ji,jj,jl)

            IF ( zhi < rn_himin) THEN   !--- Remove ponds on thin ice if ice is too thin

               a_ip(ji,jj,jl)      = 0._wp                               !--- Dump ponds
               v_ip(ji,jj,jl)      = 0._wp
               a_ip_frac(ji,jj,jl) = 0._wp
               h_ip(ji,jj,jl)      = 0._wp

               IF ( ( nn_pnd_cpl == 1 ) .OR. ( nn_pnd_cpl == 3 ) ) & !--- Give freshwater to the ocean
                  wfx_pnd(ji,jj)   = wfx_pnd(ji,jj) + v_ip(ji,jj,jl) 


            ELSE                        !--- Update pond characteristics

               !--- Add retained melt water to melt ponds
               v_ip(ji,jj,jl)      = v_ip(ji,jj,jl) + zrfrac(ji,jj,jl) * z1_rhofw * zwfx_mlw(ji,jj) * a_i(ji,jj,jl) * rdt_ice

               !--- Shrink pond due to refreezing
               zdTs                = MAX ( zTp - t_su(ji,jj,jl) + rt0 , 0. )
               
               zvpold              = v_ip(ji,jj,jl)

               v_ip(ji,jj,jl)      = v_ip(ji,jj,jl) * EXP( zrexp * zdTs / zTp )

               !--- Dump meltwater due to refreezing ( of course this is wrong
               !--- but this parameterization is too simple )
               IF ( ( nn_pnd_cpl == 1 ) .OR. ( nn_pnd_cpl == 3 ) ) THEN

                  wfx_pnd(ji,jj)   = wfx_pnd(ji,jj) + rhofw * ( v_ip(ji,jj,jl) - zvpold ) * r1_rdtice

               ENDIF

               a_ip_frac(ji,jj,jl) = MIN( 1._wp , SQRT( v_ip(ji,jj,jl) * z1_zpnd_aspect / a_i(ji,jj,jl) ) )

               h_ip(ji,jj,jl)      = zpnd_aspect * a_ip_frac(ji,jj,jl)

               a_ip(ji,jj,jl)      = a_ip_frac(ji,jj,jl) * a_i(ji,jj,jl)

            !-----------------------------------------------------------
            ! Limit pond depth
            !-----------------------------------------------------------
            ! hpondn = min(hpondn, dpthhi*hi)

            !--- Give freshwater to the ocean ?

            ENDIF

          END DO

       END DO ! jpl

       !--- Remove retained meltwater from surface fluxes 

       IF ( ( nn_pnd_cpl .EQ. 1 ) .OR. ( nn_pnd_cpl .EQ. 3 ) ) THEN

           wfx_snw(:,:) = wfx_snw(:,:) *  ( 1. - zrmin - ( zrmax - zrmin ) * at_i(:,:) )

           wfx_sum(:,:) = wfx_sum(:,:) *  ( 1. - zrmin - ( zrmax - zrmin ) * at_i(:,:) )

       ENDIF

   END SUBROUTINE lim_mp_cesm

   SUBROUTINE lim_mp_topo    (aice,      aicen,     &
                              vice,      vicen,     &
                              vsnon,                &
                              ticen,     salin,     &
                              a_ip_frac, h_ip,      &
                                         Tsfc )
       !!-------------------------------------------------------------------
       !!                ***  ROUTINE lim_mp_topo  ***
       !!
       !! ** Purpose :   Compute melt pond evolution based on the ice 
       !!                topography as inferred from the ice thickness 
       !!                distribution.  
       !!
       !! ** Method  :   This code is initially based on Flocco and Feltham 
       !!                (2007) and Flocco et al. (2010). More to come...
       !!
       !! ** Tunable parameters :
       !! 
       !! ** Note :
       !!
       !! ** References
       !!    Flocco, D. and D. L. Feltham, 2007.  A continuum model of melt pond 
       !!    evolution on Arctic sea ice.  J. Geophys. Res. 112, C08016, doi: 
       !!    10.1029/2006JC003836.
       !!    Flocco, D., D. L. Feltham and A. K. Turner, 2010.  Incorporation of
       !!    a physically based melt pond scheme into the sea ice component of a
       !!    climate model.  J. Geophys. Res. 115, C08012, 
       !!    doi: 10.1029/2009JC005568.
       !!    
       !!-------------------------------------------------------------------
 
       REAL (wp), DIMENSION (jpi,jpj), &
          INTENT(IN) :: &
          aice, &    ! total ice area fraction
          vice       ! total ice volume (m)
 
       REAL (wp), DIMENSION (jpi,jpj,jpl), &
          INTENT(IN) :: &
          aicen, &   ! ice area fraction, per category
          vsnon, &   ! snow volume, per category (m)
          vicen      ! ice volume, per category (m)
 
       REAL (wp), DIMENSION (jpi,jpj,nlay_i,jpl), &
          INTENT(IN) :: &
          ticen, &   ! ice enthalpy, per category
          salin
 
       REAL (wp), DIMENSION (jpi,jpj,jpl), &
          INTENT(INOUT) :: &
          a_ip_frac , &   ! pond area fraction of ice, per ice category
          h_ip       ! pond depth, per ice category (m)
 
       REAL (wp), DIMENSION (jpi,jpj,jpl), &
          INTENT(IN) :: &
          Tsfc       ! snow/sea ice surface temperature
 
       ! local variables
       REAL (wp), DIMENSION (jpi,jpj,jpl) :: &
          zTsfcn, & ! ice/snow surface temperature (C)
          zvolpn, & ! pond volume per unit area, per category (m)
          zvuin     ! water-equivalent volume of ice lid on melt pond ('upper ice', m)
 
       REAL (wp), DIMENSION (jpi,jpj,jpl) :: &
          zapondn,& ! pond area fraction, per category
          zhpondn   ! pond depth, per category (m)
 
       REAL (wp), DIMENSION (jpi,jpj) :: &
          zvolp       ! total volume of pond, per unit area of pond (m)
 
       REAL (wp) :: &
          zhi,    & ! ice thickness (m)
          zdHui,  & ! change in thickness of ice lid (m)
          zomega, & ! conduction
          zdTice, & ! temperature difference across ice lid (C)
          zdvice, & ! change in ice volume (m)
          zTavg,  & ! mean surface temperature across categories (C)
          zTp,    & ! pond freezing temperature (C)
          zdvn      ! change in melt pond volume for fresh water budget
       INTEGER, DIMENSION (jpi*jpj) :: &
          indxi, indxj    ! compressed indices for cells with ice melting
 
       INTEGER :: n,k,i,j,ij,icells,indxij ! loop indices
 
       INTEGER, DIMENSION (jpl) :: &
          kcells          ! cells where ice lid combines with vice
 
       INTEGER, DIMENSION (jpi*jpj,jpl) :: &
          indxii, indxjj  ! i,j indices for kcells loop
 
       REAL (wp), parameter :: &
          zhicemin  = 0.1_wp , & ! minimum ice thickness with ponds (m) 
          zTd       = 0.15_wp, & ! temperature difference for freeze-up (C)
          zr1_rlfus = 1._wp / 0.334e+6 / 917._wp , & ! (J/m^3)
          zmin_volp = 1.e-4_wp, & ! minimum pond volume (m)
          z0       = 0._wp,    & 
          zTimelt   = 0._wp,    &
          z01      = 0.01_wp,  &
          z25      = 0.25_wp,  &
          z5       = 0.5_wp

       !---------------------------------------------------------------
       ! Initialization
       !---------------------------------------------------------------
 
       zhpondn(:,:,:) = 0._wp
       zapondn(:,:,:) = 0._wp
       indxii(:,:) = 0
       indxjj(:,:) = 0
       kcells(:)   = 0

       zvolp(:,:) = wfx_sum(:,:) + wfx_snw(:,:) + vt_ip(:,:) ! Total available melt water, to be distributed as melt ponds
       zTsfcn(:,:,:) = zTsfcn(:,:,:) - rt0                   ! Convert in Celsius
 
       ! The freezing temperature for meltponds is assumed slightly below 0C,
       ! as if meltponds had a little salt in them.  The salt budget is not
       ! altered for meltponds, but if it were then an actual pond freezing 
       ! temperature could be computed.
 
       ! zTp = zTimelt - zTd  ---> for lids
 
       !-----------------------------------------------------------------
       ! Identify grid cells with ponds
       !-----------------------------------------------------------------
 
       icells = 0
       DO j = 1, jpj
       DO i = 1, jpi
          zhi = z0
          IF (aice(i,j) > epsi10 ) zhi = vice(i,j)/aice(i,j)
          IF ( aice(i,j) > z01 .and. zhi > zhicemin .and. &
             zvolp(i,j) > zmin_volp*aice(i,j)) THEN
             icells = icells + 1
             indxi(icells) = i
             indxj(icells) = j
          ELSE  ! remove ponds on thin ice
             !fpond(i,j) = fpond(i,j) - zvolp(i,j)
             zvolpn(i,j,:) = z0
             zvuin (i,j,:) = z0
             zvolp (i,j) = z0
          END IF
       END DO                     ! i
       END DO                     ! j
 
       DO ij = 1, icells
          i = indxi(ij)
          j = indxj(ij)
 
          !--------------------------------------------------------------
          ! calculate pond area and depth
          !--------------------------------------------------------------
          CALL lim_mp_area(aice(i,j),vice(i,j), &
                    aicen(i,j,:), vicen(i,j,:), vsnon(i,j,:), &
                    ticen(i,j,:,:), salin(i,j,:,:), &
                    zvolpn(i,j,:), zvolp(i,j), &
                    zapondn(i,j,:),zhpondn(i,j,:), zdvn)
         ! outputs are
         ! - zdvn
         ! - zvolpn
         ! - zvolp
         ! - zapondn
         ! - zhpondn

          wfx_pnd(i,j) = wfx_pnd(i,j) + zdvn ! update flux from ponds to ocean
 
          ! mean surface temperature MV - why do we need that ? --> for the lid

          ! zTavg = z0
          ! DO n = 1, jpl
          !   zTavg = zTavg + zTsfcn(i,j,n)*aicen(i,j,n)
          ! END DO
          ! zTavg = zTavg / aice(i,j)
 
       END DO ! ij
 
       !---------------------------------------------------------------
       ! Update pond volume and fraction
       !---------------------------------------------------------------
 
       a_ip(:,:,:) = zapondn(:,:,:)
       v_ip(:,:,:) = zapondn(:,:,:) * zhpondn(:,:,:)
       a_ip_frac(:,:,:) = 0._wp
       h_ip     (:,:,:) = 0._wp

    END SUBROUTINE lim_mp_topo

    SUBROUTINE lim_mp_area(aice,vice, &
                         aicen, vicen, vsnon, ticen, &
                         salin, zvolpn, zvolp,         &
                         zapondn,zhpondn,dvolp)

       !!-------------------------------------------------------------------
       !!                ***  ROUTINE lim_mp_area ***
       !!
       !! ** Purpose : Given the total volume of meltwater, update
       !!              pond fraction (a_ip) and depth (should be volume)
       !!
       !! **
       !!              
       !!------------------------------------------------------------------

       REAL (wp), INTENT(IN) :: &
          aice,vice
 
       REAL (wp), DIMENSION(jpl), INTENT(IN) :: &
          aicen, vicen, vsnon
 
       REAL (wp), DIMENSION(nlay_i,jpl), INTENT(IN) :: &
          ticen, salin
 
       REAL (wp), DIMENSION(jpl), INTENT(INOUT) :: &
          zvolpn
 
       REAL (wp), INTENT(INOUT) :: &
          zvolp, dvolp
 
       REAL (wp), DIMENSION(jpl), INTENT(OUT) :: &
          zapondn, zhpondn
 
       INTEGER :: &
          n, ns,   &
          m_index, &
          permflag
 
       REAL (wp), DIMENSION(jpl) :: &
          hicen, &
          hsnon, &
          asnon, &
          alfan, &
          betan, &
          cum_max_vol, &
          reduced_aicen        
 
       REAL (wp), DIMENSION(0:jpl) :: &
          cum_max_vol_tmp
 
       REAL (wp) :: &
          hpond, &
          drain, &
          floe_weight, &
          pressure_head, &
          hsl_rel, &
          deltah, &
          perm, &
          msno
 
       REAL (wp), parameter :: & 
          viscosity = 1.79e-3_wp, &  ! kinematic water viscosity in kg/m/s
          z0        = 0.0_wp    , &
          c1        = 1.0_wp    , &
          p4        = 0.4_wp    , &
          p6        = 0.6_wp    , &
          epsi10      = 1.0e-11_wp
          
      !-----------|
      !           |
      !           |-----------|
      !___________|___________|______________________________________sea-level
      !           |           |
      !           |           |---^--------|
      !           |           |   |        |
      !           |           |   |        |-----------|              |-------
      !           |           |   |alfan(n)|           |              |
      !           |           |   |        |           |--------------|
      !           |           |   |        |           |              |
      !---------------------------v-------------------------------------------
      !           |           |   ^        |           |              |
      !           |           |   |        |           |--------------|
      !           |           |   |betan(n)|           |              |
      !           |           |   |        |-----------|              |-------
      !           |           |   |        |
      !           |           |---v------- |
      !           |           |
      !           |-----------|
      !           |
      !-----------|
     
       !-------------------------------------------------------------------
       ! initialize
       !-------------------------------------------------------------------
 
       DO n = 1, jpl
 
          zapondn(n) = z0
          zhpondn(n) = z0
 
          !----------------------------------------
          ! X) compute the effective snow fraction
          !----------------------------------------
          IF (aicen(n) < epsi10)  THEN
             hicen(n) =  z0 
             hsnon(n) = z0
             reduced_aicen(n) = z0
          ELSE
             hicen(n) = vicen(n) / aicen(n)
             hsnon(n) = vsnon(n) / aicen(n)
             reduced_aicen(n) = c1 ! n=jpl
             IF (n < jpl) reduced_aicen(n) = aicen(n) &
                                  * (-0.024_wp*hicen(n) + 0.832_wp) 
             asnon(n) = reduced_aicen(n)  ! effective snow fraction (empirical)
             ! MV should check whether this makes sense to have the same effective snow fraction in here
          END IF
 
 ! This choice for alfa and beta ignores hydrostatic equilibium of categories.
 ! Hydrostatic equilibium of the entire ITD is accounted for below, assuming
 ! a surface topography implied by alfa=0.6 and beta=0.4, and rigidity across all
 ! categories.  alfa and beta partition the ITD - they are areas not thicknesses!
 ! Multiplying by hicen, alfan and betan (below) are thus volumes per unit area.
 ! Here, alfa = 60% of the ice area (and since hice is constant in a category, 
 ! alfan = 60% of the ice volume) in each category lies above the reference line, 
 ! and 40% below. Note: p6 is an arbitrary choice, but alfa+beta=1 is required.

 ! MV:  
 ! Note that this choice is not in the original FF07 paper and has been adopted in CICE
 ! No reason why is explained in the doc, but I guess there is a reason. I'll try to investigate, maybe

 ! Where does that choice come from
 
          alfan(n) = 0.6 * hicen(n)
          betan(n) = 0.4 * hicen(n)
        
          cum_max_vol(n)     = z0
          cum_max_vol_tmp(n) = z0
     
       END DO ! jpl
 
       cum_max_vol_tmp(0) = z0
       drain = z0
       dvolp = z0

       !----------------------------------------------------------
       ! x) Drain overflow water, update pond fraction and volume
       !----------------------------------------------------------
       
       !--------------------------------------------------------------------------
       ! the maximum amount of water that can be contained up to each ice category
       !--------------------------------------------------------------------------

       ! MV
       ! If melt ponds are too deep to be sustainable given the ITD (OVERFLOW)
       ! Then the excess volume cum_max_vol(jl) drains out of the system
       ! It should be added to wfx_pnd
       ! END MV
     
       DO n = 1, jpl-1 ! last category can not hold any volume
 
          IF (alfan(n+1) >= alfan(n) .and. alfan(n+1) > z0) THEN
 
             ! total volume in level including snow
             cum_max_vol_tmp(n) = cum_max_vol_tmp(n-1) + &
                (alfan(n+1) - alfan(n)) * sum(reduced_aicen(1:n)) 
 
             ! subtract snow solid volumes from lower categories in current level
             DO ns = 1, n 
                cum_max_vol_tmp(n) = cum_max_vol_tmp(n) &
                   - rhosn/rhofw * &   ! free air fraction that can be filled by water
                     asnon(ns)  * &    ! effective areal fraction of snow in that category
                     max(min(hsnon(ns)+alfan(ns)-alfan(n), alfan(n+1)- &
                                   alfan(n)), z0)  
             END DO

          ELSE ! assume higher categories unoccupied
             cum_max_vol_tmp(n) = cum_max_vol_tmp(n-1)
          END IF
          !IF (cum_max_vol_tmp(n) < z0) THEN
          !   call abort_ice('negative melt pond volume')
          !END IF
       END DO
       cum_max_vol_tmp(jpl) = cum_max_vol_tmp(jpl-1)  ! last category holds no volume
       cum_max_vol  (1:jpl) = cum_max_vol_tmp(1:jpl)
     
       !----------------------------------------------------------------
       ! is there more meltwater than can be held in the floe?
       !----------------------------------------------------------------
       IF (zvolp >= cum_max_vol(jpl)) THEN
          drain = zvolp - cum_max_vol(jpl) + epsi10
          zvolp = zvolp - drain ! update meltwater volume available
          dvolp = drain         ! this is the drained water
          IF (zvolp < epsi10) THEN
             dvolp = dvolp + zvolp
             zvolp = z0
          END IF
       END IF
     
       ! height and area corresponding to the remaining volume
 
!      call calc_hpond(reduced_aicen, asnon, hsnon, rhos, alfan, &
!           zvolp, cum_max_vol, hpond, m_index)
     
       DO n=1, m_index
          zhpondn(n) = hpond - alfan(n) + alfan(1) ! here oui choulde update
                                                   !  volume instead, no ?
          zapondn(n) = reduced_aicen(n) 
          ! in practise, pond fraction depends on the empirical snow fraction
          ! so in turn on ice thickness
       END DO
     
       !------------------------------------------------------------------------
       ! Drainage through brine network (permeability)
       !------------------------------------------------------------------------
       !!! drainage due to ice permeability - Darcy's law
     
       ! sea water level 
       msno = z0
       DO n=1,jpl
         msno = msno + vsnon(n) * rhosn
       END DO
       floe_weight = (msno + rhoic*vice + rau0*zvolp) / aice
       hsl_rel = floe_weight / rau0 &
               - ((sum(betan(:)*aicen(:))/aice) + alfan(1))
     
       deltah = hpond - hsl_rel
       pressure_head = grav * rau0 * max(deltah, z0)
 
       ! drain IF ice is permeable    
       permflag = 0
       IF (pressure_head > z0) THEN
       DO n = 1, jpl-1
          IF (hicen(n) /= z0) THEN
             perm = 0. ! MV ugly dummy patch
             CALL lim_mp_perm(ticen(:,n), salin(:,n), vicen(n), perm)
             IF (perm > z0) permflag = 1

             drain = perm*zapondn(n)*pressure_head*rdt_ice / &
                                      (viscosity*hicen(n))
             dvolp = dvolp + min(drain, zvolp)
             zvolp = max(zvolp - drain, z0)
             IF (zvolp < epsi10) THEN
                dvolp = dvolp + zvolp
                zvolp = z0
             END IF
          END IF
       END DO
  
       ! adjust melt pond DIMENSIONs
       IF (permflag > 0) THEN
          ! recompute pond depth    
!         CALL calc_hpond(reduced_aicen, asnon, hsnon, rhos, alfan, &
!                         zvolp, cum_max_vol, hpond, m_index)
          DO n=1, m_index
             zhpondn(n) = hpond - alfan(n) + alfan(1)
             zapondn(n) = reduced_aicen(n) 
          END DO
       END IF
       END IF ! pressure_head
 
       !-------------------------------
       ! X) remove water from the snow
       !-------------------------------
       !------------------------------------------------------------------------
       ! total melt pond volume in category DOes not include snow volume
       ! snow in melt ponds is not melted
       !------------------------------------------------------------------------
 
       ! Calculate pond volume for lower categories
       DO n=1,m_index-1
          zvolpn(n) = zapondn(n) * zhpondn(n) & ! what is not in the snow
                   - (rhosn/rhofw) * asnon(n) * min(hsnon(n), zhpondn(n))
       END DO
 
       ! Calculate pond volume for highest category = remaining pond volume

       ! The following is completely unclear to Martin at least
       ! Could we redefine properly and recode in a more readable way ?

       ! m_index = last category with melt pond

       IF (m_index == 1) zvolpn(m_index) = zvolp ! volume of mw in 1st category is the total volume of melt water

       IF (m_index > 1) THEN
         IF (zvolp > sum(zvolpn(1:m_index-1))) THEN
           zvolpn(m_index) = zvolp - sum(zvolpn(1:m_index-1)) ! 
         ELSE
           zvolpn(m_index) = z0
           zhpondn(m_index) = z0
           zapondn(m_index) = z0
           ! If remaining pond volume is negative reduce pond volume of 
           ! lower category
           IF (zvolp+epsi10 < sum(zvolpn(1:m_index-1))) & 
             zvolpn(m_index-1) = zvolpn(m_index-1)-sum(zvolpn(1:m_index-1))&
                                + zvolp
         END IF
       END IF
 
       DO n=1,m_index
          IF (zapondn(n) > epsi10) THEN
              zhpondn(n) = zvolpn(n) / zapondn(n)
          ELSE
             dvolp = dvolp + zvolpn(n)
             zhpondn(n) = z0
             zvolpn(n) = z0
             zapondn(n) = z0
          end IF
       END DO
       DO n = m_index+1, jpl
          zhpondn(n) = z0
          zapondn(n) = z0
          zvolpn (n) = z0
       END DO
 
    END SUBROUTINE lim_mp_area

!OLI_CODE   
!OLI_CODE 
!OLI_CODE    SUBROUTINE calc_hpond(aicen, asnon, hsnon, rhos, alfan, &
!OLI_CODE                          zvolp, cum_max_vol,                &
!OLI_CODE                          hpond, m_index)
!OLI_CODE       !!-------------------------------------------------------------------
!OLI_CODE       !!                ***  ROUTINE calc_hpond  ***
!OLI_CODE       !!
!OLI_CODE       !! ** Purpose :   Compute melt pond depth
!OLI_CODE       !!-------------------------------------------------------------------
!OLI_CODE     
!OLI_CODE       REAL (wp), DIMENSION(jpl), INTENT(IN) :: &
!OLI_CODE          aicen, &
!OLI_CODE          asnon, &
!OLI_CODE          hsnon, &
!OLI_CODE          rhos,  &
!OLI_CODE          alfan, &
!OLI_CODE          cum_max_vol
!OLI_CODE     
!OLI_CODE       REAL (wp), INTENT(IN) :: &
!OLI_CODE          zvolp
!OLI_CODE     
!OLI_CODE       REAL (wp), INTENT(OUT) :: &
!OLI_CODE          hpond
!OLI_CODE     
!OLI_CODE       INTEGER, INTENT(OUT) :: &
!OLI_CODE          m_index
!OLI_CODE     
!OLI_CODE       INTEGER :: n, ns
!OLI_CODE     
!OLI_CODE       REAL (wp), DIMENSION(0:jpl+1) :: &
!OLI_CODE          hitl, &
!OLI_CODE          aicetl
!OLI_CODE     
!OLI_CODE       REAL (wp) :: &
!OLI_CODE          rem_vol, &
!OLI_CODE          area, &
!OLI_CODE          vol, &
!OLI_CODE          tmp, &
!OLI_CODE          z0   = 0.0_wp,    &   
!OLI_CODE          epsi10 = 1.0e-11_wp
!OLI_CODE     
!OLI_CODE       !----------------------------------------------------------------
!OLI_CODE       ! hpond is zero if zvolp is zero - have we fully drained? 
!OLI_CODE       !----------------------------------------------------------------
!OLI_CODE     
!OLI_CODE       IF (zvolp < epsi10) THEN
!OLI_CODE        hpond = z0
!OLI_CODE        m_index = 0
!OLI_CODE       ELSE
!OLI_CODE        
!OLI_CODE        !----------------------------------------------------------------
!OLI_CODE        ! Calculate the category where water fills up to 
!OLI_CODE        !----------------------------------------------------------------
!OLI_CODE        
!OLI_CODE        !----------|
!OLI_CODE        !          |
!OLI_CODE        !          |
!OLI_CODE        !          |----------|                                     -- --
!OLI_CODE        !__________|__________|_________________________________________ ^
!OLI_CODE        !          |          |             rem_vol     ^                | Semi-filled
!OLI_CODE        !          |          |----------|-- -- -- - ---|-- ---- -- -- --v layer
!OLI_CODE        !          |          |          |              |
!OLI_CODE        !          |          |          |              |hpond
!OLI_CODE        !          |          |          |----------|   |     |-------
!OLI_CODE        !          |          |          |          |   |     |
!OLI_CODE        !          |          |          |          |---v-----|
!OLI_CODE        !          |          | m_index  |          |         |
!OLI_CODE        !-------------------------------------------------------------
!OLI_CODE        
!OLI_CODE        m_index = 0  ! 1:m_index categories have water in them
!OLI_CODE        DO n = 1, jpl
!OLI_CODE           IF (zvolp <= cum_max_vol(n)) THEN
!OLI_CODE              m_index = n
!OLI_CODE              IF (n == 1) THEN
!OLI_CODE                 rem_vol = zvolp
!OLI_CODE              ELSE
!OLI_CODE                 rem_vol = zvolp - cum_max_vol(n-1)
!OLI_CODE              END IF
!OLI_CODE              exit ! to break out of the loop
!OLI_CODE           END IF
!OLI_CODE        END DO
!OLI_CODE        m_index = min(jpl-1, m_index)
!OLI_CODE        
!OLI_CODE        !----------------------------------------------------------------
!OLI_CODE        ! semi-filled layer may have m_index different snow in it
!OLI_CODE        !----------------------------------------------------------------
!OLI_CODE        
!OLI_CODE        !-----------------------------------------------------------  ^
!OLI_CODE        !                                                             |  alfan(m_index+1)
!OLI_CODE        !                                                             |
!OLI_CODE        !hitl(3)-->                             |----------|          |
!OLI_CODE        !hitl(2)-->                |------------| * * * * *|          |
!OLI_CODE        !hitl(1)-->     |----------|* * * * * * |* * * * * |          |
!OLI_CODE        !hitl(0)-->-------------------------------------------------  |  ^
!OLI_CODE        !                various snow from lower categories          |  |alfa(m_index)
!OLI_CODE        
!OLI_CODE        ! hitl - heights of the snow layers from thinner and current categories
!OLI_CODE        ! aicetl - area of each snow depth in this layer
!OLI_CODE        
!OLI_CODE        hitl(:) = z0
!OLI_CODE        aicetl(:) = z0
!OLI_CODE        DO n = 1, m_index
!OLI_CODE           hitl(n)   = max(min(hsnon(n) + alfan(n) - alfan(m_index), &
!OLI_CODE                                  alfan(m_index+1) - alfan(m_index)), z0)
!OLI_CODE           aicetl(n) = asnon(n)
!OLI_CODE           
!OLI_CODE           aicetl(0) = aicetl(0) + (aicen(n) - asnon(n))
!OLI_CODE        END DO
!OLI_CODE        hitl(m_index+1) = alfan(m_index+1) - alfan(m_index)
!OLI_CODE        aicetl(m_index+1) = z0
!OLI_CODE        
!OLI_CODE        !----------------------------------------------------------------
!OLI_CODE        ! reorder array according to hitl 
!OLI_CODE        ! snow heights not necessarily in height order
!OLI_CODE        !----------------------------------------------------------------
!OLI_CODE        
!OLI_CODE        DO ns = 1, m_index+1
!OLI_CODE           DO n = 0, m_index - ns + 1
!OLI_CODE              IF (hitl(n) > hitl(n+1)) THEN ! swap order
!OLI_CODE                 tmp = hitl(n)
!OLI_CODE                 hitl(n) = hitl(n+1)
!OLI_CODE                 hitl(n+1) = tmp
!OLI_CODE                 tmp = aicetl(n)
!OLI_CODE                 aicetl(n) = aicetl(n+1)
!OLI_CODE                 aicetl(n+1) = tmp
!OLI_CODE              END IF
!OLI_CODE           END DO
!OLI_CODE        END DO
!OLI_CODE        
!OLI_CODE        !----------------------------------------------------------------
!OLI_CODE        ! divide semi-filled layer into set of sublayers each vertically homogenous
!OLI_CODE        !----------------------------------------------------------------
!OLI_CODE        
!OLI_CODE        !hitl(3)----------------------------------------------------------------
!OLI_CODE        !                                                       | * * * * * * * *  
!OLI_CODE        !                                                       |* * * * * * * * * 
!OLI_CODE        !hitl(2)----------------------------------------------------------------
!OLI_CODE        !                                    | * * * * * * * *  | * * * * * * * *  
!OLI_CODE        !                                    |* * * * * * * * * |* * * * * * * * * 
!OLI_CODE        !hitl(1)----------------------------------------------------------------
!OLI_CODE        !                 | * * * * * * * *  | * * * * * * * *  | * * * * * * * *  
!OLI_CODE        !                 |* * * * * * * * * |* * * * * * * * * |* * * * * * * * * 
!OLI_CODE        !hitl(0)----------------------------------------------------------------
!OLI_CODE        !    aicetl(0)         aicetl(1)           aicetl(2)          aicetl(3)            
!OLI_CODE        
!OLI_CODE        ! move up over layers incrementing volume
!OLI_CODE        DO n = 1, m_index+1
!OLI_CODE           
!OLI_CODE           area = sum(aicetl(:)) - &                 ! total area of sub-layer
!OLI_CODE                (rhos(n)/rau0) * sum(aicetl(n:jpl+1)) ! area of sub-layer occupied by snow
!OLI_CODE           
!OLI_CODE           vol = (hitl(n) - hitl(n-1)) * area      ! thickness of sub-layer times area
!OLI_CODE           
!OLI_CODE           IF (vol >= rem_vol) THEN  ! have reached the sub-layer with the depth within
!OLI_CODE              hpond = rem_vol / area + hitl(n-1) + alfan(m_index) - &
!OLI_CODE                           alfan(1)
!OLI_CODE              exit
!OLI_CODE           ELSE  ! still in sub-layer below the sub-layer with the depth
!OLI_CODE              rem_vol = rem_vol - vol
!OLI_CODE           END IF
!OLI_CODE           
!OLI_CODE        END DO
!OLI_CODE        
!OLI_CODE       END IF
!OLI_CODE     
!OLI_CODE    END SUBROUTINE calc_hpond
!OLI_CODE   
!OLI_CODE 
    SUBROUTINE lim_mp_perm(ticen, salin, vicen, perm)
       !!-------------------------------------------------------------------
       !!                ***  ROUTINE lim_mp_perm ***
       !!
       !! ** Purpose :   Determine the liquid fraction of brine in the ice
       !!                and its permeability
       !!-------------------------------------------------------------------
       REAL (wp), DIMENSION(nlay_i), INTENT(IN) :: &
          ticen,  & ! energy of melting for each ice layer (J/m2)
          salin
 
       REAL (wp), INTENT(IN) :: &
          vicen     ! ice volume
     
       REAL (wp), INTENT(OUT) :: &
          perm      ! permeability
 
       REAL (wp) ::   &
          Sbr        ! brine salinity
 
       REAL (wp), DIMENSION(nlay_i) ::   &
          Tin, &    ! ice temperature
          phi       ! liquid fraction
 
       INTEGER :: k
     
       REAL (wp) :: &
          c2    = 2.0_wp
  
       !-----------------------------------------------------------------
       ! Compute ice temperatures from enthalpies using quadratic formula
       !-----------------------------------------------------------------
 
       DO k = 1,nlay_i
          Tin(k) = ticen(k) 
       END DO
 
       !-----------------------------------------------------------------
       ! brine salinity and liquid fraction
       !-----------------------------------------------------------------
 
       IF (maxval(Tin-rtt) <= -c2) THEN
 
          DO k = 1,nlay_i
             Sbr = - 1.2_wp                 &
                   -21.8_wp     * (Tin(k)-rtt)    &
                   - 0.919_wp   * (Tin(k)-rtt)**2 &
                   - 0.01878_wp * (Tin(k)-rtt)**3
             phi(k) = salin(k)/Sbr ! liquid fraction
          END DO ! k
        
       ELSE
 
          DO k = 1,nlay_i
             Sbr = -17.6_wp    * (Tin(k)-rtt)    &
                   - 0.389_wp  * (Tin(k)-rtt)**2 &
                   - 0.00362_wp* (Tin(k)-rtt)**3
             phi(k) = salin(k)/Sbr ! liquid fraction
          END DO
 
       END IF
     
       !-----------------------------------------------------------------
       ! permeability
       !-----------------------------------------------------------------
 
       perm = 3.0e-08_wp * (minval(phi))**3 ! REFERENCE PLEASE (this fucking
                                            ! bastard of Golden)
     
    END SUBROUTINE lim_mp_perm
!OLI_CODE   
!OLI_CODE #else
!OLI_CODE    !!----------------------------------------------------------------------
!OLI_CODE    !!   Default option         Dummy Module          No LIM-3 sea-ice model
!OLI_CODE    !!----------------------------------------------------------------------
!OLI_CODE CONTAINS
!OLI_CODE    SUBROUTINE lim_mp_init          ! Empty routine
!OLI_CODE    END SUBROUTINE lim_mp_init   
!OLI_CODE    SUBROUTINE lim_mp               ! Empty routine
!OLI_CODE    END SUBROUTINE lim_mp
!OLI_CODE    SUBROUTINE compute_mp_topo      ! Empty routine
!OLI_CODE    END SUBROUTINE compute_mp_topo        
!OLI_CODE    SUBROUTINE pond_area            ! Empty routine
!OLI_CODE    END SUBROUTINE pond_area   
!OLI_CODE    SUBROUTINE calc_hpond           ! Empty routine
!OLI_CODE    END SUBROUTINE calc_hpond   
!OLI_CODE    SUBROUTINE permeability_phy     ! Empty routine
!OLI_CODE    END SUBROUTINE permeability_phy   
!OLI_CODE #endif
!OLI_CODE    !!======================================================================
!OLI_CODE END MODULE limmp_topo


!OLI_CODE MODULE limmp_topo
!OLI_CODE    !!======================================================================
!OLI_CODE    !!                       ***  MODULE limmp_topo ***
!OLI_CODE    !! LIM-3 sea-ice :  computation of melt ponds' properties
!OLI_CODE    !!======================================================================
!OLI_CODE    !! History :  Original code by Daniela Flocco and Adrian Turner
!OLI_CODE    !!            ! 2012-09 (O. Lecomte) Adaptation for routine inclusion in 
!OLI_CODE    !!                      NEMO-LIM3.1
!OLI_CODE    !!            ! 2016-11 (O. Lecomte, C. Rousset, M. Vancoppenolle) 
!OLI_CODE    !!                      Adaptation for merge with NEMO-LIM3.6
!OLI_CODE    !!----------------------------------------------------------------------
!OLI_CODE #if defined key_lim3
!OLI_CODE    !!----------------------------------------------------------------------
!OLI_CODE    !!   'key_lim3'                                      LIM-3 sea-ice model
!OLI_CODE    !!----------------------------------------------------------------------
!OLI_CODE    !!   lim_mp_init     : melt pond properties initialization
!OLI_CODE    !!   lim_mp          : melt pond routine caller
!OLI_CODE    !!   compute_mp_topo : Actual melt pond routine
!OLI_CODE    !!----------------------------------------------------------------------
!OLI_CODE    USE ice_oce, ONLY: rdt_ice, tatm_ice
!OLI_CODE    USE phycst
!OLI_CODE    USE dom_ice
!OLI_CODE    USE dom_oce
!OLI_CODE    USE sbc_oce
!OLI_CODE    USE sbc_ice
!OLI_CODE    USE par_ice
!OLI_CODE    USE par_oce
!OLI_CODE    USE ice
!OLI_CODE    USE thd_ice
!OLI_CODE    USE in_out_manager
!OLI_CODE    USE lbclnk
!OLI_CODE    USE lib_mpp
!OLI_CODE 
!OLI_CODE    IMPLICIT NONE
!OLI_CODE    PRIVATE
!OLI_CODE 
!OLI_CODE    PUBLIC   lim_mp_init
!OLI_CODE    PUBLIC   lim_mp
!OLI_CODE 
!OLI_CODE CONTAINS
!OLI_CODE 
!OLI_CODE    SUBROUTINE lim_mp_init
!OLI_CODE       !!-------------------------------------------------------------------
!OLI_CODE       !!                ***  ROUTINE lim_mp_init  ***
!OLI_CODE       !!
!OLI_CODE       !! ** Purpose :   Initialize melt ponds
!OLI_CODE       !!-------------------------------------------------------------------
!OLI_CODE       a_ip_frac(:,:,:)    = 0._wp
!OLI_CODE       a_ip(:,:,:)         = 0._wp
!OLI_CODE       h_ip(:,:,:)         = 0._wp
!OLI_CODE       v_ip(:,:,:)         = 0._wp
!OLI_CODE       h_il(:,:,:)         = 0._wp
!OLI_CODE       v_il(:,:,:)         = 0._wp
!OLI_CODE         
!OLI_CODE    END SUBROUTINE lim_mp_init
!OLI_CODE 
!OLI_CODE 
!OLI_CODE    SUBROUTINE lim_mp
!OLI_CODE       !!-------------------------------------------------------------------
!OLI_CODE       !!                ***  ROUTINE lim_mp  ***
!OLI_CODE       !!
!OLI_CODE       !! ** Purpose :   Compute surface heat flux and call main melt pond
!OLI_CODE       !!                routine
!OLI_CODE       !!-------------------------------------------------------------------
!OLI_CODE 
!OLI_CODE       INTEGER  ::   ji, jj, jl   ! dummy loop indices
!OLI_CODE 
!OLI_CODE       fsurf(:,:) = 0.e0
!OLI_CODE       DO jl = 1, jpl
!OLI_CODE          DO jj = 1, jpj
!OLI_CODE             DO ji = 1, jpi
!OLI_CODE                fsurf(ji,jj) = fsurf(ji,jj) + a_i(ji,jj,jl) * &
!OLI_CODE                      (qns_ice(ji,jj,jl) + (1.0 - izero(ji,jj,jl)) &
!OLI_CODE                        * qsr_ice(ji,jj,jl))
!OLI_CODE             END DO
!OLI_CODE          END DO
!OLI_CODE       END DO
!OLI_CODE 
!OLI_CODE       CALL compute_mp_topo(at_i, a_i,                               &
!OLI_CODE                          vt_i, v_i, v_s, rhosn_glo, t_i, s_i, a_ip_frac,  &
!OLI_CODE                       h_ip, h_il, t_su, tatm_ice, diag_sur_me*rdt_ice, &
!OLI_CODE                          fsurf, fwoc)
!OLI_CODE 
!OLI_CODE       at_ip(:,:) = 0.0
!OLI_CODE       vt_ip(:,:) = 0.0
!OLI_CODE       vt_il(:,:) = 0.0
!OLI_CODE       DO jl = 1, jpl
!OLI_CODE         DO jj = 1, jpj
!OLI_CODE            DO ji = 1, jpi
!OLI_CODE               a_ip(ji,jj,jl) = MAX(0.0_wp, a_ip_frac(ji,jj,jl) * &
!OLI_CODE                                                   a_i(ji,jj,jl))
!OLI_CODE               v_ip(ji,jj,jl) = MAX(0.0_wp, a_ip_frac(ji,jj,jl) * &
!OLI_CODE                                   a_i(ji,jj,jl) * h_ip(ji,jj,jl))
!OLI_CODE               v_il(ji,jj,jl) = MAX(0.0_wp, a_ip_frac(ji,jj,jl) * &
!OLI_CODE                                   a_i(ji,jj,jl) * h_il(ji,jj,jl))
!OLI_CODE               at_ip(ji,jj)   = at_ip(ji,jj) + a_ip(ji,jj,jl)
!OLI_CODE               vt_ip(ji,jj)   = vt_ip(ji,jj) + v_ip(ji,jj,jl)
!OLI_CODE               vt_il(ji,jj)   = vt_il(ji,jj) + v_il(ji,jj,jl)
!OLI_CODE            END DO
!OLI_CODE         END DO
!OLI_CODE       END DO
!OLI_CODE 
!OLI_CODE    END SUBROUTINE lim_mp
!OLI_CODE 
!OLI_CODE 
!OLI_CODE    SUBROUTINE compute_mp_topo(aice,      aicen,     &
!OLI_CODE                               vice,      vicen,     &
!OLI_CODE                               vsnon,     rhos,      &
!OLI_CODE                               ticen,     salin,     &
!OLI_CODE                               a_ip_frac, h_ip,      &
!OLI_CODE                               h_il,      Tsfc,      &
!OLI_CODE                               potT,      meltt,     &
!OLI_CODE                               fsurf,     fwoc)
!OLI_CODE       !!-------------------------------------------------------------------
!OLI_CODE       !!                ***  ROUTINE compute_mp_topo  ***
!OLI_CODE       !!
!OLI_CODE       !! ** Purpose :   Compute melt pond evolution based on the ice 
!OLI_CODE       !!                topography as inferred from the ice thickness 
!OLI_CODE       !!                distribution.  
!OLI_CODE       !!
!OLI_CODE       !! ** Method  :   This code is initially based on Flocco and Feltham 
!OLI_CODE       !!                (2007) and Flocco et al. (2010). More to come...
!OLI_CODE       !!
!OLI_CODE       !! ** Tunable parameters :
!OLI_CODE       !! 
!OLI_CODE       !! ** Note :
!OLI_CODE       !!
!OLI_CODE       !! ** References
!OLI_CODE       !!    Flocco, D. and D. L. Feltham, 2007.  A continuum model of melt pond 
!OLI_CODE       !!    evolution on Arctic sea ice.  J. Geophys. Res. 112, C08016, doi: 
!OLI_CODE       !!    10.1029/2006JC003836.
!OLI_CODE       !!    Flocco, D., D. L. Feltham and A. K. Turner, 2010.  Incorporation of
!OLI_CODE       !!    a physically based melt pond scheme into the sea ice component of a
!OLI_CODE       !!    climate model.  J. Geophys. Res. 115, C08012, 
!OLI_CODE       !!    doi: 10.1029/2009JC005568.
!OLI_CODE       !!    
!OLI_CODE       !!-------------------------------------------------------------------
!OLI_CODE 
!OLI_CODE       REAL (wp), DIMENSION (jpi,jpj), &
!OLI_CODE          INTENT(IN) :: &
!OLI_CODE          aice, &    ! total ice area fraction
!OLI_CODE          vice       ! total ice volume (m)
!OLI_CODE 
!OLI_CODE       REAL (wp), DIMENSION (jpi,jpj,jpl), &
!OLI_CODE          INTENT(IN) :: &
!OLI_CODE          aicen, &   ! ice area fraction, per category
!OLI_CODE          vsnon, &   ! snow volume, per category (m)
!OLI_CODE          rhos,  &   ! equivalent snow density, per category (kg/m^3)
!OLI_CODE          vicen      ! ice volume, per category (m)
!OLI_CODE 
!OLI_CODE       REAL (wp), DIMENSION (jpi,jpj,nlay_i,jpl), &
!OLI_CODE          INTENT(IN) :: &
!OLI_CODE          ticen, &   ! ice enthalpy, per category
!OLI_CODE          salin
!OLI_CODE 
!OLI_CODE       REAL (wp), DIMENSION (jpi,jpj,jpl), &
!OLI_CODE          INTENT(INOUT) :: &
!OLI_CODE          a_ip_frac , &   ! pond area fraction of ice, per ice category
!OLI_CODE          h_ip , &   ! pond depth, per ice category (m)
!OLI_CODE          h_il       ! Refrozen ice lid thickness, per ice category (m)
!OLI_CODE 
!OLI_CODE       REAL (wp), DIMENSION (jpi,jpj), &
!OLI_CODE          INTENT(IN) :: &
!OLI_CODE          potT,  &   ! air potential temperature
!OLI_CODE          meltt, &   ! total surface meltwater flux
!OLI_CODE          fsurf      ! thermodynamic heat flux at ice/snow surface (W/m^2)
!OLI_CODE 
!OLI_CODE       REAL (wp), DIMENSION (jpi,jpj), &
!OLI_CODE          INTENT(INOUT) :: &
!OLI_CODE          fwoc      ! fresh water flux to the ocean (from draining and other pond volume adjustments)
!OLI_CODE                    ! (m)
!OLI_CODE 
!OLI_CODE       REAL (wp), DIMENSION (jpi,jpj,jpl), &
!OLI_CODE          INTENT(IN) :: &
!OLI_CODE          Tsfc       ! snow/sea ice surface temperature
!OLI_CODE 
!OLI_CODE       ! local variables
!OLI_CODE       REAL (wp), DIMENSION (jpi,jpj,jpl) :: &
!OLI_CODE          zTsfcn, & ! ice/snow surface temperature (C)
!OLI_CODE          zvolpn, & ! pond volume per unit area, per category (m)
!OLI_CODE          zvuin     ! water-equivalent volume of ice lid on melt pond ('upper ice', m)
!OLI_CODE 
!OLI_CODE       REAL (wp), DIMENSION (jpi,jpj,jpl) :: &
!OLI_CODE          zapondn,& ! pond area fraction, per category
!OLI_CODE          zhpondn   ! pond depth, per category (m)
!OLI_CODE 
!OLI_CODE       REAL (wp), DIMENSION (jpi,jpj) :: &
!OLI_CODE          zvolp       ! total volume of pond, per unit area of pond (m)
!OLI_CODE 
!OLI_CODE       REAL (wp) :: &
!OLI_CODE          zhi,    & ! ice thickness (m)
!OLI_CODE          zdHui,  & ! change in thickness of ice lid (m)
!OLI_CODE          zomega, & ! conduction
!OLI_CODE          zdTice, & ! temperature difference across ice lid (C)
!OLI_CODE          zdvice, & ! change in ice volume (m)
!OLI_CODE          zTavg,  & ! mean surface temperature across categories (C)
!OLI_CODE          zTp,    & ! pond freezing temperature (C)
!OLI_CODE          zdvn      ! change in melt pond volume for fresh water budget
!OLI_CODE       INTEGER, DIMENSION (jpi*jpj) :: &
!OLI_CODE          indxi, indxj    ! compressed indices for cells with ice melting
!OLI_CODE 
!OLI_CODE       INTEGER :: n,k,i,j,ij,icells,indxij ! loop indices
!OLI_CODE 
!OLI_CODE       INTEGER, DIMENSION (jpl) :: &
!OLI_CODE          kcells          ! cells where ice lid combines with vice
!OLI_CODE 
!OLI_CODE       INTEGER, DIMENSION (jpi*jpj,jpl) :: &
!OLI_CODE          indxii, indxjj  ! i,j indices for kcells loop
!OLI_CODE 
!OLI_CODE       REAL (wp), parameter :: &
!OLI_CODE          zhicemin  = 0.1_wp , & ! minimum ice thickness with ponds (m) 
!OLI_CODE          zTd       = 0.15_wp, & ! temperature difference for freeze-up (C)
!OLI_CODE          zr1_rlfus = 1._wp / 0.334e+6 / 917._wp , & ! (J/m^3)
!OLI_CODE          zmin_volp = 1.e-4_wp, & ! minimum pond volume (m)
!OLI_CODE          z0       = 0._wp,    & 
!OLI_CODE          zTimelt   = 0._wp,    &
!OLI_CODE          z01      = 0.01_wp,  &
!OLI_CODE          z25      = 0.25_wp,  &
!OLI_CODE          z5       = 0.5_wp,   &
!OLI_CODE          epsi10     = 1.0e-11_wp
!OLI_CODE       !---------------------------------------------------------------
!OLI_CODE       ! initialize
!OLI_CODE       !---------------------------------------------------------------
!OLI_CODE 
!OLI_CODE       DO j = 1, jpj
!OLI_CODE          DO i = 1, jpi
!OLI_CODE             zvolp(i,j) = z0
!OLI_CODE          END DO
!OLI_CODE       END DO
!OLI_CODE       DO n = 1, jpl
!OLI_CODE          DO j = 1, jpj
!OLI_CODE             DO i = 1, jpi
!OLI_CODE                ! load tracers
!OLI_CODE                zvolp(i,j) = zvolp(i,j) + h_ip(i,j,n) &
!OLI_CODE                                      * a_ip_frac(i,j,n) * aicen(i,j,n)
!OLI_CODE                zTsfcn(i,j,n) = Tsfc(i,j,n) - rtt ! convert in Celsius - Oli
!OLI_CODE                zvuin (i,j,n) = h_il(i,j,n) &
!OLI_CODE                             * a_ip_frac(i,j,n) * aicen(i,j,n)
!OLI_CODE 
!OLI_CODE                zhpondn(i,j,n) = z0     ! pond depth, per category
!OLI_CODE                zapondn(i,j,n) = z0     ! pond area,  per category
!OLI_CODE             END DO
!OLI_CODE          END DO
!OLI_CODE          indxii(:,n) = 0
!OLI_CODE          indxjj(:,n) = 0
!OLI_CODE          kcells  (n) = 0
!OLI_CODE       END DO
!OLI_CODE 
!OLI_CODE       ! The freezing temperature for meltponds is assumed slightly below 0C,
!OLI_CODE       ! as if meltponds had a little salt in them.  The salt budget is not
!OLI_CODE       ! altered for meltponds, but if it were then an actual pond freezing 
!OLI_CODE       ! temperature could be computed.
!OLI_CODE 
!OLI_CODE       zTp = zTimelt - zTd
!OLI_CODE 
!OLI_CODE       !-----------------------------------------------------------------
!OLI_CODE       ! Identify grid cells with ponds
!OLI_CODE       !-----------------------------------------------------------------
!OLI_CODE 
!OLI_CODE       icells = 0
!OLI_CODE       DO j = 1, jpj
!OLI_CODE       DO i = 1, jpi
!OLI_CODE          zhi = z0
!OLI_CODE          IF (aice(i,j) > epsi10) zhi = vice(i,j)/aice(i,j)
!OLI_CODE          IF ( aice(i,j) > z01 .and. zhi > zhicemin .and. &
!OLI_CODE             zvolp(i,j) > zmin_volp*aice(i,j)) THEN
!OLI_CODE             icells = icells + 1
!OLI_CODE             indxi(icells) = i
!OLI_CODE             indxj(icells) = j
!OLI_CODE          ELSE  ! remove ponds on thin ice
!OLI_CODE             !fpond(i,j) = fpond(i,j) - zvolp(i,j)
!OLI_CODE             zvolpn(i,j,:) = z0
!OLI_CODE             zvuin (i,j,:) = z0
!OLI_CODE             zvolp (i,j) = z0
!OLI_CODE          END IF
!OLI_CODE       END DO                     ! i
!OLI_CODE       END DO                     ! j
!OLI_CODE 
!OLI_CODE       DO ij = 1, icells
!OLI_CODE          i = indxi(ij)
!OLI_CODE          j = indxj(ij)
!OLI_CODE 
!OLI_CODE          !--------------------------------------------------------------
!OLI_CODE          ! calculate pond area and depth
!OLI_CODE          !--------------------------------------------------------------
!OLI_CODE          CALL pond_area(aice(i,j),vice(i,j),rhos(i,j,:), &
!OLI_CODE                    aicen(i,j,:), vicen(i,j,:), vsnon(i,j,:), &
!OLI_CODE                    ticen(i,j,:,:), salin(i,j,:,:), &
!OLI_CODE                    zvolpn(i,j,:), zvolp(i,j), &
!OLI_CODE                    zapondn(i,j,:),zhpondn(i,j,:), zdvn)
!OLI_CODE 
!OLI_CODE          fwoc(i,j) = fwoc(i,j) + zdvn ! -> Goes to fresh water budget
!OLI_CODE 
!OLI_CODE          ! mean surface temperature
!OLI_CODE          zTavg = z0
!OLI_CODE          DO n = 1, jpl
!OLI_CODE             zTavg = zTavg + zTsfcn(i,j,n)*aicen(i,j,n)
!OLI_CODE          END DO
!OLI_CODE          zTavg = zTavg / aice(i,j)
!OLI_CODE 
!OLI_CODE          DO n = 1, jpl-1
!OLI_CODE                        
!OLI_CODE             IF (zvuin(i,j,n) > epsi10) THEN
!OLI_CODE 
!OLI_CODE          !----------------------------------------------------------------
!OLI_CODE          ! melting: floating upper ice layer melts in whole or part
!OLI_CODE          !----------------------------------------------------------------
!OLI_CODE !               IF (zTsfcn(i,j,n) > zTp) THEN
!OLI_CODE                IF (zTavg > zTp) THEN
!OLI_CODE 
!OLI_CODE                   zdvice = min(meltt(i,j)*zapondn(i,j,n), zvuin(i,j,n))
!OLI_CODE                   IF (zdvice > epsi10) THEN
!OLI_CODE                      zvuin (i,j,n) = zvuin (i,j,n) - zdvice
!OLI_CODE                      zvolpn(i,j,n) = zvolpn(i,j,n) + zdvice
!OLI_CODE                      zvolp (i,j)   = zvolp (i,j)   + zdvice
!OLI_CODE                      !fwoc(i,j)   = fwoc(i,j)   + zdvice
!OLI_CODE                        
!OLI_CODE                      IF (zvuin(i,j,n) < epsi10 .and. zvolpn(i,j,n) > puny) THEN
!OLI_CODE                         ! ice lid melted and category is pond covered
!OLI_CODE                         zvolpn(i,j,n) = zvolpn(i,j,n) + zvuin(i,j,n)
!OLI_CODE                         !fwoc(i,j)   = fwoc(i,j)   + zvuin(i,j,n)
!OLI_CODE                         zvuin(i,j,n)  = z0
!OLI_CODE                      END IF
!OLI_CODE                      zhpondn(i,j,n) = zvolpn(i,j,n) / zapondn(i,j,n)
!OLI_CODE                   END IF
!OLI_CODE 
!OLI_CODE          !----------------------------------------------------------------
!OLI_CODE          ! freezing: existing upper ice layer grows
!OLI_CODE          !----------------------------------------------------------------
!OLI_CODE                ELSE IF (zvolpn(i,j,n) > epsi10) THEN ! zTavg <= zTp
!OLI_CODE 
!OLI_CODE                 ! dIFferential growth of base of surface floating ice layer
!OLI_CODE                   zdTice = max(-zTavg, z0) ! > 0
!OLI_CODE                   zomega = rcdic*zdTice * zr1_rlfus 
!OLI_CODE                   zdHui = sqrt(zomega*rdt_ice + z25*(zvuin(i,j,n)/  &
!OLI_CODE                         aicen(i,j,n))**2)- z5 * zvuin(i,j,n)/aicen(i,j,n)
!OLI_CODE 
!OLI_CODE                   zdvice = min(zdHui*zapondn(i,j,n), zvolpn(i,j,n))   
!OLI_CODE                   IF (zdvice > epsi10) THEN
!OLI_CODE                      zvuin (i,j,n) = zvuin (i,j,n) + zdvice
!OLI_CODE                      zvolpn(i,j,n) = zvolpn(i,j,n) - zdvice
!OLI_CODE                      zvolp (i,j)   = zvolp (i,j)   - zdvice
!OLI_CODE                      !fwoc(i,j)   = fwoc(i,j)   - zdvice
!OLI_CODE                      zhpondn(i,j,n) = zvolpn(i,j,n) / zapondn(i,j,n)
!OLI_CODE                   END IF
!OLI_CODE 
!OLI_CODE                END IF ! zTavg
!OLI_CODE 
!OLI_CODE          !----------------------------------------------------------------
!OLI_CODE          ! freezing: upper ice layer begins to form
!OLI_CODE          ! note: albedo does not change
!OLI_CODE          !----------------------------------------------------------------
!OLI_CODE             ELSE ! zvuin < epsi10
!OLI_CODE                     
!OLI_CODE                ! thickness of newly formed ice
!OLI_CODE                ! the surface temperature of a meltpond is the same as that
!OLI_CODE                ! of the ice underneath (0C), and the thermodynamic surface 
!OLI_CODE                ! flux is the same
!OLI_CODE                zdHui = max(-fsurf(i,j)*rdt_ice*zr1_rlfus, z0)
!OLI_CODE                zdvice = min(zdHui*zapondn(i,j,n), zvolpn(i,j,n))  
!OLI_CODE                IF (zdvice > epsi10) THEN
!OLI_CODE                   zvuin (i,j,n) = zdvice
!OLI_CODE                   zvolpn(i,j,n) = zvolpn(i,j,n) - zdvice
!OLI_CODE                   zvolp (i,j)   = zvolp (i,j)   - zdvice
!OLI_CODE                   !fwoc(i,j)   = fwoc(i,j)   - zdvice
!OLI_CODE                   zhpondn(i,j,n)= zvolpn(i,j,n) / zapondn(i,j,n)
!OLI_CODE                END IF
!OLI_CODE                     
!OLI_CODE             END IF  ! zvuin
!OLI_CODE 
!OLI_CODE          END DO ! jpl
!OLI_CODE 
!OLI_CODE       END DO ! ij
!OLI_CODE 
!OLI_CODE       !---------------------------------------------------------------
!OLI_CODE       ! remove ice lid if there is no liquid pond
!OLI_CODE       ! zvuin may be nonzero on category jpl due to dynamics
!OLI_CODE       !---------------------------------------------------------------
!OLI_CODE 
!OLI_CODE       DO j = 1, jpj
!OLI_CODE       DO i = 1, jpi
!OLI_CODE          DO n = 1, jpl
!OLI_CODE             IF (aicen(i,j,n) > epsi10 .and. zvolpn(i,j,n) < puny &
!OLI_CODE                                     .and. zvuin (i,j,n) > epsi10) THEN
!OLI_CODE                kcells(n) = kcells(n) + 1
!OLI_CODE                indxij    = kcells(n)
!OLI_CODE                indxii(indxij,n) = i
!OLI_CODE                indxjj(indxij,n) = j
!OLI_CODE             END IF
!OLI_CODE          END DO
!OLI_CODE       END DO                     ! i
!OLI_CODE       END DO                     ! j
!OLI_CODE 
!OLI_CODE       DO n = 1, jpl
!OLI_CODE 
!OLI_CODE          IF (kcells(n) > 0) THEN
!OLI_CODE          DO ij = 1, kcells(n)
!OLI_CODE             i = indxii(ij,n)
!OLI_CODE             j = indxjj(ij,n)
!OLI_CODE             fwoc(i,j) = fwoc(i,j) + rhoic/rauw * zvuin(i,j,n) ! Completely refrozen lid goes into ocean (to be changed)
!OLI_CODE             zvuin(i,j,n) = z0 
!OLI_CODE          END DO    ! ij
!OLI_CODE          END IF
!OLI_CODE 
!OLI_CODE          ! reload tracers
!OLI_CODE          DO j = 1, jpj
!OLI_CODE             DO i = 1, jpi
!OLI_CODE                IF (zapondn(i,j,n) > epsi10) THEN
!OLI_CODE                   h_il(i,j,n) = zvuin(i,j,n) / zapondn(i,j,n)
!OLI_CODE                ELSE
!OLI_CODE                   zvuin(i,j,n) = z0
!OLI_CODE                   h_il(i,j,n) = z0
!OLI_CODE                END IF
!OLI_CODE                IF (aicen(i,j,n) > epsi10) THEN
!OLI_CODE                   a_ip_frac(i,j,n) = zapondn(i,j,n) / aicen(i,j,n) * &
!OLI_CODE                         (1.0_wp - MAX(z0, SIGN(1.0_wp, -zvolpn(i,j,n))))
!OLI_CODE                   h_ip(i,j,n) = zhpondn(i,j,n)
!OLI_CODE                ELSE
!OLI_CODE                   a_ip_frac(i,j,n) = z0
!OLI_CODE                   h_ip(i,j,n) = z0
!OLI_CODE                   h_il(i,j,n) = z0
!OLI_CODE                END IF
!OLI_CODE             END DO ! i
!OLI_CODE          END DO    ! j
!OLI_CODE 
!OLI_CODE       END DO       ! n
!OLI_CODE 
!OLI_CODE    END SUBROUTINE compute_mp_topo
!OLI_CODE 
!OLI_CODE 
!OLI_CODE    SUBROUTINE pond_area(aice,vice,rhos,             &
!OLI_CODE                         aicen, vicen, vsnon, ticen, &
!OLI_CODE                         salin, zvolpn, zvolp,         &
!OLI_CODE                         zapondn,zhpondn,dvolp)
!OLI_CODE       !!-------------------------------------------------------------------
!OLI_CODE       !!                ***  ROUTINE pond_area  ***
!OLI_CODE       !!
!OLI_CODE       !! ** Purpose :   Compute melt pond area, depth and melting rates
!OLI_CODE       !!------------------------------------------------------------------
!OLI_CODE       REAL (wp), INTENT(IN) :: &
!OLI_CODE          aice,vice
!OLI_CODE 
!OLI_CODE       REAL (wp), DIMENSION(jpl), INTENT(IN) :: &
!OLI_CODE          aicen, vicen, vsnon, rhos
!OLI_CODE 
!OLI_CODE       REAL (wp), DIMENSION(nlay_i,jpl), INTENT(IN) :: &
!OLI_CODE          ticen, salin
!OLI_CODE 
!OLI_CODE       REAL (wp), DIMENSION(jpl), INTENT(INOUT) :: &
!OLI_CODE          zvolpn
!OLI_CODE 
!OLI_CODE       REAL (wp), INTENT(INOUT) :: &
!OLI_CODE          zvolp, dvolp
!OLI_CODE 
!OLI_CODE       REAL (wp), DIMENSION(jpl), INTENT(OUT) :: &
!OLI_CODE          zapondn, zhpondn
!OLI_CODE 
!OLI_CODE       INTEGER :: &
!OLI_CODE          n, ns,   &
!OLI_CODE          m_index, &
!OLI_CODE          permflag
!OLI_CODE 
!OLI_CODE       REAL (wp), DIMENSION(jpl) :: &
!OLI_CODE          hicen, &
!OLI_CODE          hsnon, &
!OLI_CODE          asnon, &
!OLI_CODE          alfan, &
!OLI_CODE          betan, &
!OLI_CODE          cum_max_vol, &
!OLI_CODE          reduced_aicen        
!OLI_CODE 
!OLI_CODE       REAL (wp), DIMENSION(0:jpl) :: &
!OLI_CODE          cum_max_vol_tmp
!OLI_CODE 
!OLI_CODE       REAL (wp) :: &
!OLI_CODE          hpond, &
!OLI_CODE          drain, &
!OLI_CODE          floe_weight, &
!OLI_CODE          pressure_head, &
!OLI_CODE          hsl_rel, &
!OLI_CODE          deltah, &
!OLI_CODE          perm, &
!OLI_CODE          apond, &
!OLI_CODE          msno
!OLI_CODE 
!OLI_CODE       REAL (wp), parameter :: & 
!OLI_CODE          viscosity = 1.79e-3_wp, &  ! kinematic water viscosity in kg/m/s
!OLI_CODE          z0        = 0.0_wp    , &
!OLI_CODE          c1        = 1.0_wp    , &
!OLI_CODE          p4        = 0.4_wp    , &
!OLI_CODE          p6        = 0.6_wp    , &
!OLI_CODE          epsi10      = 1.0e-11_wp
!OLI_CODE          
!OLI_CODE      !-----------|
!OLI_CODE      !           |
!OLI_CODE      !           |-----------|
!OLI_CODE      !___________|___________|______________________________________sea-level
!OLI_CODE      !           |           |
!OLI_CODE      !           |           |---^--------|
!OLI_CODE      !           |           |   |        |
!OLI_CODE      !           |           |   |        |-----------|              |-------
!OLI_CODE      !           |           |   |alfan(n)|           |              |
!OLI_CODE      !           |           |   |        |           |--------------|
!OLI_CODE      !           |           |   |        |           |              |
!OLI_CODE      !---------------------------v-------------------------------------------
!OLI_CODE      !           |           |   ^        |           |              |
!OLI_CODE      !           |           |   |        |           |--------------|
!OLI_CODE      !           |           |   |betan(n)|           |              |
!OLI_CODE      !           |           |   |        |-----------|              |-------
!OLI_CODE      !           |           |   |        |
!OLI_CODE      !           |           |---v------- |
!OLI_CODE      !           |           |
!OLI_CODE      !           |-----------|
!OLI_CODE      !           |
!OLI_CODE      !-----------|
!OLI_CODE     
!OLI_CODE       !-------------------------------------------------------------------
!OLI_CODE       ! initialize
!OLI_CODE       !-------------------------------------------------------------------
!OLI_CODE 
!OLI_CODE       DO n = 1, jpl
!OLI_CODE 
!OLI_CODE          zapondn(n) = z0
!OLI_CODE          zhpondn(n) = z0
!OLI_CODE 
!OLI_CODE          IF (aicen(n) < epsi10)  THEN
!OLI_CODE             hicen(n) =  z0 
!OLI_CODE             hsnon(n) = z0
!OLI_CODE             reduced_aicen(n) = z0
!OLI_CODE          ELSE
!OLI_CODE             hicen(n) = vicen(n) / aicen(n)
!OLI_CODE             hsnon(n) = vsnon(n) / aicen(n)
!OLI_CODE             reduced_aicen(n) = c1 ! n=jpl
!OLI_CODE             IF (n < jpl) reduced_aicen(n) = aicen(n) &
!OLI_CODE                                  * (-0.024_wp*hicen(n) + 0.832_wp) 
!OLI_CODE             asnon(n) = reduced_aicen(n) 
!OLI_CODE          END IF
!OLI_CODE 
!OLI_CODE ! This choice for alfa and beta ignores hydrostatic equilibium of categories.
!OLI_CODE ! Hydrostatic equilibium of the entire ITD is accounted for below, assuming
!OLI_CODE ! a surface topography implied by alfa=0.6 and beta=0.4, and rigidity across all
!OLI_CODE ! categories.  alfa and beta partition the ITD - they are areas not thicknesses!
!OLI_CODE ! Multiplying by hicen, alfan and betan (below) are thus volumes per unit area.
!OLI_CODE ! Here, alfa = 60% of the ice area (and since hice is constant in a category, 
!OLI_CODE ! alfan = 60% of the ice volume) in each category lies above the reference line, 
!OLI_CODE ! and 40% below. Note: p6 is an arbitrary choice, but alfa+beta=1 is required.
!OLI_CODE 
!OLI_CODE          alfan(n) = p6 * hicen(n)
!OLI_CODE          betan(n) = p4 * hicen(n)
!OLI_CODE        
!OLI_CODE          cum_max_vol(n)     = z0
!OLI_CODE          cum_max_vol_tmp(n) = z0
!OLI_CODE     
!OLI_CODE       END DO ! jpl
!OLI_CODE 
!OLI_CODE       cum_max_vol_tmp(0) = z0
!OLI_CODE       drain = z0
!OLI_CODE       dvolp = z0
!OLI_CODE     
!OLI_CODE       !--------------------------------------------------------------------------
!OLI_CODE       ! the maximum amount of water that can be contained up to each ice category
!OLI_CODE       !--------------------------------------------------------------------------
!OLI_CODE     
!OLI_CODE       DO n = 1, jpl-1 ! last category can not hold any volume
!OLI_CODE 
!OLI_CODE          IF (alfan(n+1) >= alfan(n) .and. alfan(n+1) > z0) THEN
!OLI_CODE 
!OLI_CODE             ! total volume in level including snow
!OLI_CODE             cum_max_vol_tmp(n) = cum_max_vol_tmp(n-1) + &
!OLI_CODE                (alfan(n+1) - alfan(n)) * sum(reduced_aicen(1:n)) 
!OLI_CODE 
!OLI_CODE 
!OLI_CODE             ! subtract snow solid volumes from lower categories in current level
!OLI_CODE             DO ns = 1, n 
!OLI_CODE                cum_max_vol_tmp(n) = cum_max_vol_tmp(n) &
!OLI_CODE                   - rhos(ns)/rauw  * &    ! fraction of snow that is occupied by solid ??rauw
!OLI_CODE                     asnon(ns)  * &    ! area of snow from that category
!OLI_CODE                     max(min(hsnon(ns)+alfan(ns)-alfan(n), alfan(n+1)- &
!OLI_CODE                                   alfan(n)), z0)  
!OLI_CODE                                       ! thickness of snow from ns layer in n layer
!OLI_CODE             END DO
!OLI_CODE 
!OLI_CODE          ELSE ! assume higher categories unoccupied
!OLI_CODE             cum_max_vol_tmp(n) = cum_max_vol_tmp(n-1)
!OLI_CODE          END IF
!OLI_CODE          !IF (cum_max_vol_tmp(n) < z0) THEN
!OLI_CODE          !   call abort_ice('negative melt pond volume')
!OLI_CODE          !END IF
!OLI_CODE       END DO
!OLI_CODE       cum_max_vol_tmp(jpl) = cum_max_vol_tmp(jpl-1)  ! last category holds no volume
!OLI_CODE       cum_max_vol  (1:jpl) = cum_max_vol_tmp(1:jpl)
!OLI_CODE     
!OLI_CODE       !----------------------------------------------------------------
!OLI_CODE       ! is there more meltwater than can be held in the floe?
!OLI_CODE       !----------------------------------------------------------------
!OLI_CODE       IF (zvolp >= cum_max_vol(jpl)) THEN
!OLI_CODE          drain = zvolp - cum_max_vol(jpl) + epsi10
!OLI_CODE          zvolp = zvolp - drain
!OLI_CODE          dvolp = drain
!OLI_CODE          IF (zvolp < epsi10) THEN
!OLI_CODE             dvolp = dvolp + zvolp
!OLI_CODE             zvolp = z0
!OLI_CODE          END IF
!OLI_CODE       END IF
!OLI_CODE     
!OLI_CODE       ! height and area corresponding to the remaining volume
!OLI_CODE 
!OLI_CODE       call calc_hpond(reduced_aicen, asnon, hsnon, rhos, alfan, &
!OLI_CODE            zvolp, cum_max_vol, hpond, m_index)
!OLI_CODE     
!OLI_CODE       DO n=1, m_index
!OLI_CODE          zhpondn(n) = hpond - alfan(n) + alfan(1)
!OLI_CODE          zapondn(n) = reduced_aicen(n) 
!OLI_CODE       END DO
!OLI_CODE       apond = sum(zapondn(1:m_index))
!OLI_CODE     
!OLI_CODE       !------------------------------------------------------------------------
!OLI_CODE       ! drainage due to ice permeability - Darcy's law
!OLI_CODE       !------------------------------------------------------------------------
!OLI_CODE     
!OLI_CODE       ! sea water level 
!OLI_CODE       msno = z0
!OLI_CODE       DO n=1,jpl
!OLI_CODE         msno = msno + vsnon(n) * rhos(n)
!OLI_CODE       END DO
!OLI_CODE       floe_weight = (msno + rhoic*vice + rau0*zvolp) / aice
!OLI_CODE       hsl_rel = floe_weight / rau0 &
!OLI_CODE               - ((sum(betan(:)*aicen(:))/aice) + alfan(1))
!OLI_CODE     
!OLI_CODE       deltah = hpond - hsl_rel
!OLI_CODE       pressure_head = grav * rau0 * max(deltah, z0)
!OLI_CODE 
!OLI_CODE       ! drain IF ice is permeable    
!OLI_CODE       permflag = 0
!OLI_CODE       IF (pressure_head > z0) THEN
!OLI_CODE       DO n = 1, jpl-1
!OLI_CODE          IF (hicen(n) /= z0) THEN
!OLI_CODE             CALL permeability_phi(ticen(:,n), salin(:,n), vicen(n), perm)
!OLI_CODE             IF (perm > z0) permflag = 1
!OLI_CODE             drain = perm*zapondn(n)*pressure_head*rdt_ice / &
!OLI_CODE                                      (viscosity*hicen(n))
!OLI_CODE             dvolp = dvolp + min(drain, zvolp)
!OLI_CODE             zvolp = max(zvolp - drain, z0)
!OLI_CODE             IF (zvolp < epsi10) THEN
!OLI_CODE                dvolp = dvolp + zvolp
!OLI_CODE                zvolp = z0
!OLI_CODE             END IF
!OLI_CODE          END IF
!OLI_CODE       END DO
!OLI_CODE  
!OLI_CODE       ! adjust melt pond DIMENSIONs
!OLI_CODE       IF (permflag > 0) THEN
!OLI_CODE          ! recompute pond depth    
!OLI_CODE          CALL calc_hpond(reduced_aicen, asnon, hsnon, rhos, alfan, &
!OLI_CODE                          zvolp, cum_max_vol, hpond, m_index)
!OLI_CODE          DO n=1, m_index
!OLI_CODE             zhpondn(n) = hpond - alfan(n) + alfan(1)
!OLI_CODE             zapondn(n) = reduced_aicen(n) 
!OLI_CODE          END DO
!OLI_CODE          apond = sum(zapondn(1:m_index))
!OLI_CODE       END IF
!OLI_CODE       END IF ! pressure_head
!OLI_CODE 
!OLI_CODE       !------------------------------------------------------------------------
!OLI_CODE       ! total melt pond volume in category DOes not include snow volume
!OLI_CODE       ! snow in melt ponds is not melted
!OLI_CODE       !------------------------------------------------------------------------
!OLI_CODE 
!OLI_CODE       ! Calculate pond volume for lower categories
!OLI_CODE       DO n=1,m_index-1
!OLI_CODE          zvolpn(n) = zapondn(n) * zhpondn(n) &
!OLI_CODE                   - (rhos(n)/rauw) * asnon(n) * min(hsnon(n), zhpondn(n))! 
!OLI_CODE       END DO
!OLI_CODE 
!OLI_CODE       ! Calculate pond volume for highest category = remaining pond volume
!OLI_CODE       IF (m_index == 1) zvolpn(m_index) = zvolp
!OLI_CODE       IF (m_index > 1) THEN
!OLI_CODE         IF (zvolp > sum(zvolpn(1:m_index-1))) THEN
!OLI_CODE           zvolpn(m_index) = zvolp - sum(zvolpn(1:m_index-1))
!OLI_CODE         ELSE
!OLI_CODE           zvolpn(m_index) = z0
!OLI_CODE           zhpondn(m_index) = z0
!OLI_CODE           zapondn(m_index) = z0
!OLI_CODE           ! If remaining pond volume is negative reduce pond volume of 
!OLI_CODE           ! lower category
!OLI_CODE           IF (zvolp+epsi10 < sum(zvolpn(1:m_index-1))) & 
!OLI_CODE             zvolpn(m_index-1) = zvolpn(m_index-1)-sum(zvolpn(1:m_index-1))&
!OLI_CODE                                + zvolp
!OLI_CODE         END IF
!OLI_CODE       END IF
!OLI_CODE 
!OLI_CODE       DO n=1,m_index
!OLI_CODE          IF (zapondn(n) > epsi10) THEN
!OLI_CODE              zhpondn(n) = zvolpn(n) / zapondn(n)
!OLI_CODE          ELSE
!OLI_CODE             dvolp = dvolp + zvolpn(n)
!OLI_CODE             zhpondn(n) = z0
!OLI_CODE             zvolpn(n) = z0
!OLI_CODE             zapondn(n) = z0
!OLI_CODE          end IF
!OLI_CODE       END DO
!OLI_CODE       DO n = m_index+1, jpl
!OLI_CODE          zhpondn(n) = z0
!OLI_CODE          zapondn(n) = z0
!OLI_CODE          zvolpn (n) = z0
!OLI_CODE       END DO
!OLI_CODE 
!OLI_CODE    END SUBROUTINE pond_area
!OLI_CODE   
!OLI_CODE 
!OLI_CODE    SUBROUTINE calc_hpond(aicen, asnon, hsnon, rhos, alfan, &
!OLI_CODE                          zvolp, cum_max_vol,                &
!OLI_CODE                          hpond, m_index)
!OLI_CODE       !!-------------------------------------------------------------------
!OLI_CODE       !!                ***  ROUTINE calc_hpond  ***
!OLI_CODE       !!
!OLI_CODE       !! ** Purpose :   Compute melt pond depth
!OLI_CODE       !!-------------------------------------------------------------------
!OLI_CODE     
!OLI_CODE       REAL (wp), DIMENSION(jpl), INTENT(IN) :: &
!OLI_CODE          aicen, &
!OLI_CODE          asnon, &
!OLI_CODE          hsnon, &
!OLI_CODE          rhos,  &
!OLI_CODE          alfan, &
!OLI_CODE          cum_max_vol
!OLI_CODE     
!OLI_CODE       REAL (wp), INTENT(IN) :: &
!OLI_CODE          zvolp
!OLI_CODE     
!OLI_CODE       REAL (wp), INTENT(OUT) :: &
!OLI_CODE          hpond
!OLI_CODE     
!OLI_CODE       INTEGER, INTENT(OUT) :: &
!OLI_CODE          m_index
!OLI_CODE     
!OLI_CODE       INTEGER :: n, ns
!OLI_CODE     
!OLI_CODE       REAL (wp), DIMENSION(0:jpl+1) :: &
!OLI_CODE          hitl, &
!OLI_CODE          aicetl
!OLI_CODE     
!OLI_CODE       REAL (wp) :: &
!OLI_CODE          rem_vol, &
!OLI_CODE          area, &
!OLI_CODE          vol, &
!OLI_CODE          tmp, &
!OLI_CODE          z0   = 0.0_wp,    &   
!OLI_CODE          epsi10 = 1.0e-11_wp
!OLI_CODE     
!OLI_CODE       !----------------------------------------------------------------
!OLI_CODE       ! hpond is zero if zvolp is zero - have we fully drained? 
!OLI_CODE       !----------------------------------------------------------------
!OLI_CODE     
!OLI_CODE       IF (zvolp < epsi10) THEN
!OLI_CODE        hpond = z0
!OLI_CODE        m_index = 0
!OLI_CODE       ELSE
!OLI_CODE        
!OLI_CODE        !----------------------------------------------------------------
!OLI_CODE        ! Calculate the category where water fills up to 
!OLI_CODE        !----------------------------------------------------------------
!OLI_CODE        
!OLI_CODE        !----------|
!OLI_CODE        !          |
!OLI_CODE        !          |
!OLI_CODE        !          |----------|                                     -- --
!OLI_CODE        !__________|__________|_________________________________________ ^
!OLI_CODE        !          |          |             rem_vol     ^                | Semi-filled
!OLI_CODE        !          |          |----------|-- -- -- - ---|-- ---- -- -- --v layer
!OLI_CODE        !          |          |          |              |
!OLI_CODE        !          |          |          |              |hpond
!OLI_CODE        !          |          |          |----------|   |     |-------
!OLI_CODE        !          |          |          |          |   |     |
!OLI_CODE        !          |          |          |          |---v-----|
!OLI_CODE        !          |          | m_index  |          |         |
!OLI_CODE        !-------------------------------------------------------------
!OLI_CODE        
!OLI_CODE        m_index = 0  ! 1:m_index categories have water in them
!OLI_CODE        DO n = 1, jpl
!OLI_CODE           IF (zvolp <= cum_max_vol(n)) THEN
!OLI_CODE              m_index = n
!OLI_CODE              IF (n == 1) THEN
!OLI_CODE                 rem_vol = zvolp
!OLI_CODE              ELSE
!OLI_CODE                 rem_vol = zvolp - cum_max_vol(n-1)
!OLI_CODE              END IF
!OLI_CODE              exit ! to break out of the loop
!OLI_CODE           END IF
!OLI_CODE        END DO
!OLI_CODE        m_index = min(jpl-1, m_index)
!OLI_CODE        
!OLI_CODE        !----------------------------------------------------------------
!OLI_CODE        ! semi-filled layer may have m_index different snow in it
!OLI_CODE        !----------------------------------------------------------------
!OLI_CODE        
!OLI_CODE        !-----------------------------------------------------------  ^
!OLI_CODE        !                                                             |  alfan(m_index+1)
!OLI_CODE        !                                                             |
!OLI_CODE        !hitl(3)-->                             |----------|          |
!OLI_CODE        !hitl(2)-->                |------------| * * * * *|          |
!OLI_CODE        !hitl(1)-->     |----------|* * * * * * |* * * * * |          |
!OLI_CODE        !hitl(0)-->-------------------------------------------------  |  ^
!OLI_CODE        !                various snow from lower categories          |  |alfa(m_index)
!OLI_CODE        
!OLI_CODE        ! hitl - heights of the snow layers from thinner and current categories
!OLI_CODE        ! aicetl - area of each snow depth in this layer
!OLI_CODE        
!OLI_CODE        hitl(:) = z0
!OLI_CODE        aicetl(:) = z0
!OLI_CODE        DO n = 1, m_index
!OLI_CODE           hitl(n)   = max(min(hsnon(n) + alfan(n) - alfan(m_index), &
!OLI_CODE                                  alfan(m_index+1) - alfan(m_index)), z0)
!OLI_CODE           aicetl(n) = asnon(n)
!OLI_CODE           
!OLI_CODE           aicetl(0) = aicetl(0) + (aicen(n) - asnon(n))
!OLI_CODE        END DO
!OLI_CODE        hitl(m_index+1) = alfan(m_index+1) - alfan(m_index)
!OLI_CODE        aicetl(m_index+1) = z0
!OLI_CODE        
!OLI_CODE        !----------------------------------------------------------------
!OLI_CODE        ! reorder array according to hitl 
!OLI_CODE        ! snow heights not necessarily in height order
!OLI_CODE        !----------------------------------------------------------------
!OLI_CODE        
!OLI_CODE        DO ns = 1, m_index+1
!OLI_CODE           DO n = 0, m_index - ns + 1
!OLI_CODE              IF (hitl(n) > hitl(n+1)) THEN ! swap order
!OLI_CODE                 tmp = hitl(n)
!OLI_CODE                 hitl(n) = hitl(n+1)
!OLI_CODE                 hitl(n+1) = tmp
!OLI_CODE                 tmp = aicetl(n)
!OLI_CODE                 aicetl(n) = aicetl(n+1)
!OLI_CODE                 aicetl(n+1) = tmp
!OLI_CODE              END IF
!OLI_CODE           END DO
!OLI_CODE        END DO
!OLI_CODE        
!OLI_CODE        !----------------------------------------------------------------
!OLI_CODE        ! divide semi-filled layer into set of sublayers each vertically homogenous
!OLI_CODE        !----------------------------------------------------------------
!OLI_CODE        
!OLI_CODE        !hitl(3)----------------------------------------------------------------
!OLI_CODE        !                                                       | * * * * * * * *  
!OLI_CODE        !                                                       |* * * * * * * * * 
!OLI_CODE        !hitl(2)----------------------------------------------------------------
!OLI_CODE        !                                    | * * * * * * * *  | * * * * * * * *  
!OLI_CODE        !                                    |* * * * * * * * * |* * * * * * * * * 
!OLI_CODE        !hitl(1)----------------------------------------------------------------
!OLI_CODE        !                 | * * * * * * * *  | * * * * * * * *  | * * * * * * * *  
!OLI_CODE        !                 |* * * * * * * * * |* * * * * * * * * |* * * * * * * * * 
!OLI_CODE        !hitl(0)----------------------------------------------------------------
!OLI_CODE        !    aicetl(0)         aicetl(1)           aicetl(2)          aicetl(3)            
!OLI_CODE        
!OLI_CODE        ! move up over layers incrementing volume
!OLI_CODE        DO n = 1, m_index+1
!OLI_CODE           
!OLI_CODE           area = sum(aicetl(:)) - &                 ! total area of sub-layer
!OLI_CODE                (rhos(n)/rau0) * sum(aicetl(n:jpl+1)) ! area of sub-layer occupied by snow
!OLI_CODE           
!OLI_CODE           vol = (hitl(n) - hitl(n-1)) * area      ! thickness of sub-layer times area
!OLI_CODE           
!OLI_CODE           IF (vol >= rem_vol) THEN  ! have reached the sub-layer with the depth within
!OLI_CODE              hpond = rem_vol / area + hitl(n-1) + alfan(m_index) - &
!OLI_CODE                           alfan(1)
!OLI_CODE              exit
!OLI_CODE           ELSE  ! still in sub-layer below the sub-layer with the depth
!OLI_CODE              rem_vol = rem_vol - vol
!OLI_CODE           END IF
!OLI_CODE           
!OLI_CODE        END DO
!OLI_CODE        
!OLI_CODE       END IF
!OLI_CODE     
!OLI_CODE    END SUBROUTINE calc_hpond
!OLI_CODE   
!OLI_CODE 
!OLI_CODE    SUBROUTINE permeability_phi(ticen, salin, vicen, perm)
!OLI_CODE       !!-------------------------------------------------------------------
!OLI_CODE       !!                ***  ROUTINE permeability_phi  ***
!OLI_CODE       !!
!OLI_CODE       !! ** Purpose :   Determine the liquid fraction of brine in the ice
!OLI_CODE       !!                and its permeability
!OLI_CODE       !!-------------------------------------------------------------------
!OLI_CODE       REAL (wp), DIMENSION(nlay_i), INTENT(IN) :: &
!OLI_CODE          ticen,  & ! energy of melting for each ice layer (J/m2)
!OLI_CODE          salin
!OLI_CODE 
!OLI_CODE       REAL (wp), INTENT(IN) :: &
!OLI_CODE          vicen     ! ice volume
!OLI_CODE     
!OLI_CODE       REAL (wp), INTENT(OUT) :: &
!OLI_CODE          perm      ! permeability
!OLI_CODE 
!OLI_CODE       REAL (wp) ::   &
!OLI_CODE          Sbr        ! brine salinity
!OLI_CODE 
!OLI_CODE       REAL (wp), DIMENSION(nlay_i) ::   &
!OLI_CODE          Tin, &    ! ice temperature
!OLI_CODE          phi       ! liquid fraction
!OLI_CODE 
!OLI_CODE       INTEGER :: k
!OLI_CODE     
!OLI_CODE       REAL (wp) :: &
!OLI_CODE          c2    = 2.0_wp
!OLI_CODE  
!OLI_CODE       !-----------------------------------------------------------------
!OLI_CODE       ! Compute ice temperatures from enthalpies using quadratic formula
!OLI_CODE       !-----------------------------------------------------------------
!OLI_CODE 
!OLI_CODE       DO k = 1,nlay_i
!OLI_CODE          Tin(k) = ticen(k) 
!OLI_CODE       END DO
!OLI_CODE 
!OLI_CODE       !-----------------------------------------------------------------
!OLI_CODE       ! brine salinity and liquid fraction
!OLI_CODE       !-----------------------------------------------------------------
!OLI_CODE 
!OLI_CODE       IF (maxval(Tin-rtt) <= -c2) THEN
!OLI_CODE 
!OLI_CODE          DO k = 1,nlay_i
!OLI_CODE             Sbr = - 1.2_wp                 &
!OLI_CODE                   -21.8_wp     * (Tin(k)-rtt)    &
!OLI_CODE                   - 0.919_wp   * (Tin(k)-rtt)**2 &
!OLI_CODE                   - 0.01878_wp * (Tin(k)-rtt)**3
!OLI_CODE             phi(k) = salin(k)/Sbr ! liquid fraction
!OLI_CODE          END DO ! k
!OLI_CODE        
!OLI_CODE       ELSE
!OLI_CODE 
!OLI_CODE          DO k = 1,nlay_i
!OLI_CODE             Sbr = -17.6_wp    * (Tin(k)-rtt)    &
!OLI_CODE                   - 0.389_wp  * (Tin(k)-rtt)**2 &
!OLI_CODE                   - 0.00362_wp* (Tin(k)-rtt)**3
!OLI_CODE             phi(k) = salin(k)/Sbr ! liquid fraction
!OLI_CODE          END DO
!OLI_CODE 
!OLI_CODE       END IF
!OLI_CODE     
!OLI_CODE       !-----------------------------------------------------------------
!OLI_CODE       ! permeability
!OLI_CODE       !-----------------------------------------------------------------
!OLI_CODE 
!OLI_CODE       perm = 3.0e-08_wp * (minval(phi))**3
!OLI_CODE     
!OLI_CODE    END SUBROUTINE permeability_phi
!OLI_CODE   
!OLI_CODE #else
!OLI_CODE    !!----------------------------------------------------------------------
!OLI_CODE    !!   Default option         Dummy Module          No LIM-3 sea-ice model
!OLI_CODE    !!----------------------------------------------------------------------
!OLI_CODE CONTAINS
!OLI_CODE    SUBROUTINE lim_mp_init          ! Empty routine
!OLI_CODE    END SUBROUTINE lim_mp_init   
!OLI_CODE    SUBROUTINE lim_mp               ! Empty routine
!OLI_CODE    END SUBROUTINE lim_mp
!OLI_CODE    SUBROUTINE compute_mp_topo      ! Empty routine
!OLI_CODE    END SUBROUTINE compute_mp_topo        
!OLI_CODE    SUBROUTINE pond_area            ! Empty routine
!OLI_CODE    END SUBROUTINE pond_area   
!OLI_CODE    SUBROUTINE calc_hpond           ! Empty routine
!OLI_CODE    END SUBROUTINE calc_hpond   
!OLI_CODE    SUBROUTINE permeability_phy     ! Empty routine
!OLI_CODE    END SUBROUTINE permeability_phy   
!OLI_CODE #endif
!OLI_CODE    !!======================================================================
!OLI_CODE END MODULE limmp_topo
!OLI_CODE 
#else
   !!----------------------------------------------------------------------
   !!   Default option          Empty module           NO LIM sea-ice model
   !!----------------------------------------------------------------------
CONTAINS
   SUBROUTINE lim_mp_init     ! Empty routine
   END SUBROUTINE lim_mp_init
   SUBROUTINE lim_mp          ! Empty routine
   END SUBROUTINE lim_mp     
   SUBROUTINE lim_mp_topo     ! Empty routine
   END SUBROUTINE lim_mp_topo
   SUBROUTINE lim_mp_cesm     ! Empty routine
   END SUBROUTINE lim_mp_cesm
   SUBROUTINE lim_mp_area     ! Empty routine
   END SUBROUTINE lim_mp_area
   SUBROUTINE lim_mp_perm     ! Empty routine
   END SUBROUTINE lim_mp_perm
#endif 

   !!======================================================================
END MODULE limmp