source: trunk/LMDZ.COMMON/libf/evolution/ice_table_mod.F90 @ 3210

module ice_table_mod

  implicit none

!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
!!!
!!! Purpose: Ice table (pore-filling) variables and methods to compute it (dynamic and static)
!!! Author:  LL, 02/2023
!!!
!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!

  LOGICAL,SAVE :: icetable_equilibrium                    ! Boolean to say if the PEM needs to recompute the icetable depth when at  equilibrium
  LOGICAL,SAVE :: icetable_dynamic                        ! Boolean to say if the PEM needs to recompute the icetable depth (dynamic method)
  real,save,allocatable  :: porefillingice_depth(:,:)    ! ngrid x nslope: Depth of the ice table [m]
  real,save,allocatable  :: porefillingice_thickness(:,:)    ! ngrid x nslope: Thickness of the ice table [m]

  contains


  subroutine ini_ice_table_porefilling(ngrid,nslope)
  
    implicit none
    integer,intent(in) :: ngrid ! number of atmospheric columns
    integer,intent(in) :: nslope ! number of slope within a mesh 

    allocate(porefillingice_depth(ngrid,nslope))
    allocate(porefillingice_thickness(ngrid,nslope))

  end subroutine ini_ice_table_porefilling

  subroutine end_ice_table_porefilling

    implicit none
    if (allocated(porefillingice_depth)) deallocate(porefillingice_depth)
    if (allocated(porefillingice_thickness)) deallocate(porefillingice_thickness)

  end subroutine end_ice_table_porefilling

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

   SUBROUTINE computeice_table_equilibrium(ngrid,nslope,nsoil_PEM,watercaptag,rhowatersurf_ave,rhowatersoil_ave,regolith_inertia,ice_table_beg,ice_table_thickness)
!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
!!!
!!! Purpose: Compute the ice table depth (pore-filling) knowing the yearly average water
!!! density at the surface and at depth.
!!! Computations are made following the methods in Schorgofer et al., 2005
!!! This subroutine only gives the ice table at equilibrium and does not consider exchange with the atmosphere
!!! 
!!! Author: LL
!!!
!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
    use math_mod,only: findroot
    USE comsoil_h_PEM, only: mlayer_PEM,layer_PEM                  ! Depth of the vertical grid 
    USE soil_thermalproperties_mod, only: ice_thermal_properties
    implicit none 
!   inputs
! -----------
    integer,intent(in) :: ngrid,nslope,nsoil_PEM                   ! Size of the physical grid, number of subslope, number of soil layer in the PEM 
    logical,intent(in) :: watercaptag(ngrid)                       ! Boolean to check the presence of a perennial glacier
    real,intent(in) :: rhowatersurf_ave(ngrid,nslope)              ! Water density at the surface, yearly averaged [kg/m^3]
    real,intent(in) :: rhowatersoil_ave(ngrid,nsoil_PEM,nslope)    ! Water density at depth, computed from clapeyron law's (Murchy and Koop 2005), yearly averaged  [kg/m^3]
    real,intent(in) :: regolith_inertia(ngrid,nslope)              ! Thermal inertia of the regolith layer [SI]
!   Ouputs
! -----------
    real,intent(out) :: ice_table_beg(ngrid,nslope)               ! ice table depth [m]
    real,intent(out) :: ice_table_thickness(ngrid,nslope)         ! ice table thickness [m]
!   Local
! -----------
    integer ig, islope,isoil,isoilend                              ! loop variables
    real :: diff_rho(nsoil_PEM)                                    ! difference of water vapor density between the surface and at depth [kg/m^3]
    real  :: ice_table_end                                         ! depth of the end of the ice table  [m]
    real :: previous_icetable_depth(ngrid,nslope)                  ! Ice table computed at previous ice depth [m]
    real :: stretch                                                ! stretch factor to improve the convergence of the ice table
    real :: wice_inertia                                           ! Water Ice thermal Inertia [USI]    
!   Code
! -----------

     previous_icetable_depth(:,:) = ice_table_beg(:,:)
     do ig = 1,ngrid
      if(watercaptag(ig)) then
         ice_table_beg(ig,:) = 0.
         ice_table_thickness(ig,:) = layer_PEM(nsoil_PEM) ! Let's assume an infinite ice table (true when geothermal flux is set to 0.)
      else
        do islope = 1,nslope
           ice_table_beg(ig,islope) = -1.
           ice_table_thickness(ig,islope) = 0.
         do isoil = 1,nsoil_PEM
           diff_rho(isoil) = rhowatersurf_ave(ig,islope) - rhowatersoil_ave(ig,isoil,islope)
         enddo
         if(diff_rho(1) > 0) then                                   ! ice is at the surface
           ice_table_beg(ig,islope) = 0.
               do isoilend = 2,nsoil_PEM-1
                 if((diff_rho(isoilend).gt.0).and.(diff_rho(isoilend+1).lt.0.)) then
                  call findroot(diff_rho(isoilend),diff_rho(isoilend+1),mlayer_PEM(isoilend),mlayer_PEM(isoilend+1),ice_table_end)
                  ice_table_thickness(ig,islope) = ice_table_end - ice_table_beg(ig,islope)
                  exit
                 endif
               enddo
         else
           do isoil = 1,nsoil_PEM -1                                ! general case, we find the ice table depth by doing a linear approximation between the two depth, and then solve the first degree equation to find the root
             if((diff_rho(isoil).lt.0).and.(diff_rho(isoil+1).gt.0.)) then
               call findroot(diff_rho(isoil),diff_rho(isoil+1),mlayer_PEM(isoil),mlayer_PEM(isoil+1),ice_table_beg(ig,islope))
               ! Now let's find the end of the ice table
               ice_table_thickness(ig,islope) = layer_PEM(nsoil_PEM) ! Let's assume an infinite ice table (true when geothermal flux is set to 0.)
               do isoilend = isoil+1,nsoil_PEM-1
                 if((diff_rho(isoilend).gt.0).and.(diff_rho(isoilend+1).lt.0.)) then
                  call findroot(diff_rho(isoilend),diff_rho(isoilend+1),mlayer_PEM(isoilend),mlayer_PEM(isoilend+1),ice_table_end)
                  ice_table_thickness(ig,islope) = ice_table_end - ice_table_beg(ig,islope)
                  exit
                 endif
               enddo
             endif !diff_rho(z) <0 & diff_rho(z+1) > 0
           enddo
          endif ! diff_rho(1) > 0
        enddo
       endif ! watercaptag
      enddo

! Small trick to speed up the convergence, Oded's idea.
      do islope = 1,nslope
        do ig = 1,ngrid
         if((ice_table_beg(ig,islope).gt.previous_icetable_depth(ig,islope)).and.(previous_icetable_depth(ig,islope).ge.0)) then
            call ice_thermal_properties(.false.,1.,regolith_inertia(ig,islope),wice_inertia)
            stretch = (regolith_inertia(ig,islope)/wice_inertia)**2

            ice_table_thickness(ig,islope) = ice_table_thickness(ig,islope) + (ice_table_beg(ig,islope) - &
            previous_icetable_depth(ig,islope)+(ice_table_beg(ig,islope) - previous_icetable_depth(ig,islope))/stretch)
            ice_table_beg(ig,islope) = previous_icetable_depth(ig,islope)+(ice_table_beg(ig,islope) - previous_icetable_depth(ig,islope))/stretch
         endif
        enddo
      enddo

      RETURN
      END

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


   SUBROUTINE compute_massh2o_exchange_ssi(ngrid,nslope,nsoil_PEM,former_ice_table_thickness,new_ice_table_thickness,ice_table_depth,tsoil,delta_m_h2o)
!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
!!!
!!! Purpose: Compute the mass of H2O that has sublimated from the ice table / condensed 
!!! 
!!! Author: LL
!!!
!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
    use comsoil_h_PEM, only: mlayer_PEM
    use comslope_mod, only: subslope_dist,def_slope_mean
    use constants_marspem_mod,only:porosity
#ifndef CPP_STD
    use comcstfi_h,   only: pi
#else
    use comcstfi_mod, only: pi
#endif

    implicit none 
!   inputs
! -----------
    integer,intent(in) :: ngrid,nslope,nsoil_PEM                   ! Size of the physical grid, number of subslope, number of soil layer in the PEM 
    real,intent(in) :: former_ice_table_thickness(ngrid,nslope)    ! ice table thickness at the former iteration [m]
    real,intent(in) :: new_ice_table_thickness(ngrid,nslope)       ! ice table thickness at the current iteration [m]
    real,intent(out) :: ice_table_depth(ngrid,nslope)              ! ice table depth [m]
    real,intent(in) :: tsoil(ngrid,nsoil_PEM,nslope)               ! Soil temperature [K]
!   outputs
! -----------
    real,intent(out) :: delta_m_h2o(ngrid)                         ! Mass of H2O ice that has been condensed on the ice table / sublimates from the ice table [kg/m^2]

! local
    real :: rho(ngrid,nslope)                                      ! density of water ice [kg/m^3]
    integer :: ig,islope,ilay,iref                                 ! loop index  
    real :: Tice(ngrid,nslope)                                     ! ice temperature [k]
!   Code
! -----------
   rho(:,:) = 0.
   Tice(:,:) = 0.
!1. First let's compute Tice using a linear interpolation between the mlayer level
   do ig = 1,ngrid
      do islope = 1,nslope
         if(ice_table_depth(ig,islope).gt.0.) then
            if (ice_table_depth(ig,islope).lt. 1e-10) then
               Tice(ig,islope) = tsoil(ig,1,islope)
            else
               iref=0 ! initialize iref
               do ilay=1,nsoil_PEM ! loop on layers to find the beginning of the ice table
                  if (ice_table_depth(ig,islope).ge.mlayer_PEM(ilay)) then
                     iref=ilay ! pure regolith layer up to here
                  else
                  ! correct iref was obtained in previous cycle
                     exit
                  endif
               enddo
               if(iref.eq.nsoil_PEM) then
                  Tice(ig,islope) = tsoil(ig,nsoil_PEM,islope)
               else
                  Tice(ig,islope) = (tsoil(ig,iref+1,islope) - tsoil(ig,iref,islope))/(mlayer_PEM(iref+1) - mlayer_PEM(iref))* &
                                    (ice_table_depth(ig,islope) - mlayer_PEM(iref)) +  tsoil(ig,iref,islope)           
               endif         
               rho(ig,islope) = -3.5353e-4*Tice(ig,islope)**2+   0.0351* Tice(ig,islope) +  933.5030 ! Rottgers, 2012
            endif
         endif
      enddo
   enddo      

          
!2. Let's compute the amount of ice that has sublimated in each subslope
   do ig = 1,ngrid
      do islope = 1,nslope
        delta_m_h2o(ig)  = delta_m_h2o(ig) +  porosity*rho(ig,islope)*(new_ice_table_thickness(ig,islope) - former_ice_table_thickness(ig,islope)) & ! convention > 0. <=> it condenses  
                           *subslope_dist(ig,islope)/cos(def_slope_mean(islope)*pi/180.)
      enddo
   enddo

   return
end subroutine 

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

   SUBROUTINE find_layering_icetable(porefill,psat_soil,psat_surf,pwat_surf,psat_bottom,B,index_IS,depth_filling,index_filling,index_geothermal,depth_geothermal,dz_etadz_rho)
!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
!!!
!!! Purpose: Compute layering between dry soil, pore filling ice, and ice sheet based on Schorgofer, Icarus (2010). Adapted from NS MSIM 
!!! 
!!! Author: LL
!!!
!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
use comsoil_h_PEM,only: nsoilmx_PEM,mlayer_PEM 
use math_mod, only: deriv1,deriv1_onesided,colint,findroot,deriv2_simple
implicit none
! inputs
! ------

real,intent(in) :: porefill(nsoilmx_PEM) ! Fraction of pore space filled with ice [Unitless] 0 <= f <= 1 for pore ice
real,intent(in) :: psat_soil(nsoilmx_PEM) ! Soil water pressure at saturation, yearly averaged [Pa]
real,intent(in) :: psat_surf ! surface water pressure at saturation, yearly averaged [Pa]
real,intent(in) :: pwat_surf ! Water vapor pressure  at the surface, not necesseraly at saturation, yearly averaged [Pa]
real,intent(in) :: psat_bottom ! Boundary conditions for soil vapor pressure [Pa]
real,intent(in) :: B ! constant (Eq. 8 from  Schorgofer, Icarus (2010).) 
integer, intent(in) :: index_IS ! index of the soil layer where the ice sheet begins [1]
real, intent(inout) :: depth_filling ! depth where pore filling begins [m]

! outputs
! -------
integer,intent(out) :: index_filling ! index where the pore filling begins [1]
integer, intent(out) :: index_geothermal ! index where the ice table stops [1]
real, intent(out) :: depth_geothermal ! depth where the ice table stops [m]
real, intent(out) :: dz_etadz_rho(nsoilmx_PEM) ! \partial z(eta \partial z rho), eta is the constriction, used later for pore filling increase

! local

real :: eta(nsoilmx_PEM)  ! constriction
integer :: ilay ! index for loop
real :: old_depth_filling ! depth_filling saved
real :: dz_psat(nsoilmx_PEM) ! first derivative of the vapor pressure at saturationn
integer :: index_tmp ! for loop 
real :: Jdry ! flux trought the dry layer
real :: Jsat ! flux trought the ice layer
real :: Jdry_prevlay,Jsat_prevlay ! same but for the previous ice layer
integer :: index_firstice ! first index where ice appears (i.e., f > 0)
real :: dz_eta(nsoilmx_PEM) ! \partial z \eta
real :: dzz_psat(nsoilmx_PEM) ! \partial \partial psat
real :: massfillabove,massfillafter ! h2O mass above and after index_geothermal

! constant
real :: pvap2rho = 18.e-3/8.314
!
  
! 0. Compute constriction over the layer
! Within the ice sheet, constriction is set to 0. Elsewhere, constriction =  (1-porefilling)**2
if (index_IS.lt.0) then
   index_tmp = nsoilmx_PEM
   do ilay = 1,nsoilmx_PEM
       call constriction(porefill(ilay),eta(ilay))
   enddo
else
   index_tmp = index_IS
   do ilay = 1,index_IS-1
       call constriction(porefill(ilay),eta(ilay))
   enddo
   do ilay = index_IS,nsoilmx_PEM
       eta(ilay) = 0.
   enddo
endif

! 1. Depth at which pore filling occurs. We solve Eq. 9 from  Schorgofer, Icarus  (2010)    

old_depth_filling = depth_filling

call deriv1(mlayer_PEM,nsoilmx_PEM,psat_soil,psat_surf,psat_bottom,dz_psat)  

do ilay = 1,index_tmp
  Jdry = (psat_soil(ilay) - pwat_surf)/mlayer_PEM(ilay) ! left member of Eq. 9 from Schorgofer, Icarus  (2010)
  Jsat =  eta(ilay)*dz_psat(ilay) !right member of Eq. 9 from Schorgofer, Icarus (2010)
  if((Jdry - Jsat).le.0) then
     index_filling = ilay
     exit
   endif
enddo

if(index_filling.eq.1)  depth_filling = mlayer_PEM(1) 

if(index_filling.gt.1) then
    Jdry_prevlay = (psat_soil(index_filling-1) - pwat_surf)/mlayer_PEM(index_filling-1)
    Jsat_prevlay = eta(index_filling-1)*dz_psat(index_filling-1)
   call findroot(Jdry-Jsat,Jdry_prevlay-Jsat_prevlay,mlayer_PEM(index_filling),mlayer_PEM(index_filling-1),depth_filling)
endif


! 2. Compute d_z (eta* d_z(rho)) (last term in Eq. 13 of Schorgofer, Icarus (2010))


! 2.0 preliminary: depth to shallowest  ice (discontinuity at interface)

index_firstice = -1
do ilay = 1,nsoilmx_PEM
   if (porefill(ilay).le.0.) then
        index_firstice = ilay  ! first point with ice
        exit
    endif
enddo

! 2.1: now we can computeCompute d_z (eta* d_z(rho))

call deriv1(mlayer_PEM,nsoilmx_PEM,eta,1.,eta(nsoilmx_PEM-1),dz_eta)

if ((index_firstice.gt.0).and.(index_firstice.lt.nsoilmx_PEM-2)) then
     call deriv1_onesided(index_firstice,mlayer_PEM,nsoilmx_PEM,eta,dz_eta(index_firstice))
endif

call deriv2_simple(mlayer_PEM,nsoilmx_PEM,psat_soil,psat_surf,psat_bottom,dzz_psat)
dz_etadz_rho(:) = pvap2rho*(dz_eta(:)*dz_psat(:) + eta(:)*dzz_psat(:))

! 3. Ice table boundary due to geothermal heating

if(index_IS.gt.0) index_geothermal = -1
if(index_geothermal.lt.0) depth_geothermal = -1.
if((index_geothermal.gt.0).and.(index_IS.lt.0)) then ! Eq. 21 from Schorfoger, Icarus (2010)
   index_geothermal = -1
   do ilay=2,nsoilmx_PEM
        if (dz_psat(ilay).gt.0.) then  ! first point with reversed flux
           index_geothermal=ilay
           call findroot(dz_psat(ilay-1),dz_psat(ilay),mlayer_PEM(ilay-1),mlayer_PEM(ilay),depth_geothermal)
           exit
        endif
     enddo
  else
     index_geothermal = -1
  endif
 if ((index_geothermal.gt.0).and.(index_IS.lt.0)) then !  Eq. 24 from Schorgofer, Icarus (2010)
     call  colint(porefill(:)/eta(:),mlayer_PEM,nsoilmx_PEM,index_geothermal-1,nsoilmx_PEM,massfillabove) 
     index_tmp = -1
     do ilay=index_geothermal,nsoilmx_PEM
        if (minval(eta(ilay:nsoilmx_PEM)).le.0.) cycle  ! eta=0 means completely full
         call colint(porefill(:)/eta(:),mlayer_PEM,nsoilmx_PEM,ilay,nsoilmx_PEM,massfillafter)
        if (massfillafter<dz_psat(ilay)*pvap2rho*B) then  ! usually executes on i=typeG
           if (ilay>index_geothermal) then
!              write(34,*) '# adjustment to geotherm depth by',ilay-index_geothermal
              call findroot(dz_psat(ilay-1)*pvap2rho*B-massfillabove, &  
                   dz_psat(ilay)*pvap2rho*B-massfillafter,mlayer_PEM(ilay-1),mlayer_PEM(ilay),depth_geothermal)
!               if (depth_geothermal.gt.mlayer_PEM(ilay) .or. depth_geothermal.lt.<mlayer_PEM(ilay-1)) write(34,*) 
!                     '# WARNING: zdepthG interpolation failed',ilay,mlayer_PEM(ilay-1),depth_geothermal,mlayer_PEM(ilay)
              index_tmp=ilay
           endif
           ! otherwise leave depth_geothermal unchanged
           exit
        endif
        massfillabove = massfillafter
     enddo
     if (index_tmp.gt.0) index_geothermal = index_tmp
  end if
  return
end subroutine 

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

SUBROUTINE constriction(porefill,eta)

        !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
        !!!
        !!! Purpose: Compute the  constriction of vapor flux by pore ice 
        !!! 
        !!! Author: LL
        !!!
        !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
        implicit none
        real,intent(in) :: porefill ! pore filling fraction
        real,intent(out) :: eta ! constriction

        !!!

        if (porefill.le.0.) eta = 1.
        if ((porefill.gt.0.) .and.(porefill.lt.1.)) then
        eta = (1-porefill)**2  ! Hudson et al., JGR, 2009
        endif
        if (porefill.le.1.) eta = 0.
        return
        end subroutine

end module