bling/pkg/bling_dvm.F

C $Header: /u/gcmpack/MITgcm_contrib/bling/pkg/bling_dvm.F,v 1.3 2016/05/19 16:30:00 mmazloff Exp $
C $Name:  $

#include "BLING_OPTIONS.h"

CBOP
      subroutine BLING_DVM(
     I           N_dvm,P_dvm,Fe_dvm, 
     I           PTR_O2, mld,
     O           N_remindvm, P_remindvm, Fe_remindvm,
     I           bi, bj, imin, imax, jmin, jmax,
     I           myIter, myTime, myThid )

C     =================================================================
C     | subroutine bling_prod
C     | o Nutrient uptake and partitioning between organic pools.
C     | - Phytoplankton biomass-specific growth rate is calculated 
C     |   as a function of light, nutrient limitation, and  
C     |   temperature. 
C     | - Biomass growth xxx
C     | o Organic matter export, remineralization, and recycling.
C     | - Sinking particulate flux and diel migration contribute to 
C     |   export. 
C     | - Denitrification xxx
C     =================================================================

      implicit none
      
C     === Global variables ===
C     P_sm          :: Small phytoplankton biomass
C     P_lg          :: Large phytoplankton biomass
C     P_diaz        :: Diazotroph phytoplankton biomass
C     irr_mem       :: Phyto irradiance memory

#include "SIZE.h"
#include "DYNVARS.h"
#include "EEPARAMS.h"
#include "PARAMS.h"
#include "GRID.h"
#include "BLING_VARS.h"
#include "PTRACERS_SIZE.h"
#include "PTRACERS_PARAMS.h"
#ifdef ALLOW_AUTODIFF
# include "tamc.h"
#endif

C     === Routine arguments ===
C     bi,bj         :: tile indices
C     iMin,iMax     :: computation domain: 1rst index range
C     jMin,jMax     :: computation domain: 2nd  index range
C     myTime        :: current time
C     myIter        :: current timestep
C     myThid        :: thread Id. number
      INTEGER bi, bj, imin, imax, jmin, jmax
      _RL     myTime
      INTEGER myIter
      INTEGER myThid
C     === Input ===
C     PTR_NO3       :: nitrate concentration
C     PTR_PO4       :: phosphate concentration
C     PTR_FE        :: iron concentration
C     PTR_DON       :: dissolved organic nitrogen concentration
C     PTR_DOP       :: dissolved organic phosphorus concentration
C     PTR_O2        :: oxygen concentration
      _RL     PTR_NO3(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL     PTR_PO4(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL     PTR_FE (1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL     PTR_DON(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL     PTR_DOP(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL     PTR_O2 (1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
C     === Output ===
C     G_xxx         :: Tendency of xxx
      _RL     G_NO3     (1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL     G_PO4     (1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL     G_FE      (1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL     G_O2      (1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL     G_DON     (1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL     G_DOP     (1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL     G_CACO3   (1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
 
#ifdef ALLOW_BLING
C     === Local variables ===
C     i,j,k         :: loop indices
C     irr_eff       :: effective irradiance
C     NO3_lim       :: nitrate limitation 
C     PO4_lim       :: phosphate limitation           
C     Fe_lim        :: iron limitation for phytoplankton    
C     Fe_lim_diaz   :: iron limitation for diazotrophs
C     alpha_Fe      :: initial slope of the P-I curve
C     theta_Fe      :: Chl:C ratio 
C     theta_Fe_max  :: Fe-replete maximum Chl:C ratio  
C     irrk          :: nut-limited efficiency of algal photosystems
C     Pc_m          :: light-saturated max photosynthesis rate for phyt
C     Pc_m_diaz     :: light-saturated max photosynthesis rate for diaz
C     Pc_tot        :: carbon-specific photosynthesis rate
C     expkT         :: temperature function
C     mu            :: net carbon-specific growth rate for phyt
C     mu_diaz       :: net carbon-specific growth rate for diaz
C     biomass_sm    :: nitrogen concentration in small phyto biomass
C     biomass_lg    :: nitrogen concentration in large phyto biomass 
C     N_uptake      :: nitrogen uptake 
C     N_fix         :: nitrogen fixation
C     P_uptake      :: phosphorus uptake
C     POC_flux      :: carbon export flux 3d field 
C     PtoN          :: variable ratio of phosphorus to nitrogen
C     FetoN         :: variable ratio of iron to nitrogen
C     N_spm         :: particulate sinking of nitrogen 
C     P_spm         :: particulate sinking of phosphorus
C     Fe_spm        :: particulate sinking of iron  
C     N_dvm         :: vertical transport of nitrogen by DVM 
C     P_dvm         :: vertical transport of phosphorus by DVM 
C     Fe_dvm        :: vertical transport of iron by DVM 
C     N_recycle     :: recycling of newly-produced organic nitrogen
C     P_recycle     :: recycling of newly-produced organic phosphorus
C     Fe_recycle    :: recycling of newly-produced organic iron
c xxx to be completed
      INTEGER i,j,k        
      INTEGER tmp
      _RL irr_eff(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL NO3_lim                  
      _RL PO4_lim
      _RL Fe_lim
      _RL Fe_lim_diaz                  
      _RL expkT
      _RL Pc_m
      _RL Pc_m_diaz
      _RL theta_Fe_max       
      _RL theta_Fe
      _RL irrk  
      _RL mu(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL mu_diaz(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL PtoN(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL FetoN(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL N_uptake(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL N_fix(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL P_uptake(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL Fe_uptake(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL frac_exp
      _RL N_spm(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL P_spm(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL Fe_spm(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL N_dvm(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL P_dvm(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL Fe_dvm(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL DON_prod(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL DOP_prod(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL N_recycle(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL P_recycle(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL Fe_recycle(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL POC_flux(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL NPP(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL NCP(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL CaCO3_prod(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL PONflux_u
      _RL POPflux_u
      _RL PFEflux_u
      _RL CaCO3flux_u
      _RL PONflux_l
      _RL POPflux_l
      _RL PFEflux_l
      _RL CaCO3flux_l
      _RL depth_l
      _RL zremin
      _RL zremin_caco3
      _RL wsink
      _RL POC_sed
      _RL Fe_sed(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL NO3_sed(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
      _RL PO4_sed(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
      _RL O2_sed(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
      _RL lig_stability
      _RL FreeFe
      _RL Fe_ads_inorg(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL Fe_ads_org(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL N_den_pelag(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL N_den_benthic(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL log_btm_flx
      _RL N_reminp(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL P_reminp(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL Fe_reminp(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL CacO3_diss(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL o2_upper
      _RL o2_lower 
      _RL dz_upper 
      _RL dz_lower 
      _RL temp_upper 
      _RL temp_lower 
      _RL z_dvm_regr 
      _RL frac_migr 
      _RL fdvm_migr 
      _RL fdvm_stat 
      _RL fdvmn_vint 
      _RL fdvmp_vint 
      _RL fdvmfe_vint 
      _RL z_dvm
      _RL N_remindvm(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL P_remindvm(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL Fe_remindvm(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL dvm(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
      _RL mld(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
      _RL Fe_burial(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
      _RL x_erfcc,z_erfcc,t_erfcc,erfcc
cxx order
CEOP
  
c ---------------------------------------------------------------------
c  Initialize output and diagnostics
       DO k=1,Nr
        DO j=jmin,jmax
          DO i=imin,imax
              G_NO3(i,j,k)        = 0. _d 0
              G_PO4(i,j,k)        = 0. _d 0
              G_FE(i,j,k)         = 0. _d 0
              G_O2(i,j,k)         = 0. _d 0
              G_DON(i,j,k)        = 0. _d 0
              G_DOP(i,j,k)        = 0. _d 0
              G_CaCO3(i,j,k)      = 0. _d 0
              N_uptake(i,j,k)     = 0. _d 0
              P_uptake(i,j,k)     = 0. _d 0
              Fe_uptake(i,j,k)    = 0. _d 0
              Fe_ads_org(i,j,k)   = 0. _d 0
              Fe_ads_inorg(i,j,k) = 0. _d 0
              mu(i,j,k)           = 0. _d 0
              mu_diaz(i,j,k)      = 0. _d 0
              irr_eff(i,j,k)      = 0. _d 0
              PtoN(i,j,k)         = 0. _d 0
              FetoN(i,j,k)        = 0. _d 0
              N_fix(i,j,k)        = 0. _d 0
              N_spm(i,j,k)        = 0. _d 0
              P_spm(i,j,k)        = 0. _d 0
              Fe_spm(i,j,k)       = 0. _d 0
              dvm(i,j,k)          = 0. _d 0
              N_reminp(i,j,k)     = 0. _d 0
              P_reminp(i,j,k)     = 0. _d 0
              Fe_reminp(i,j,k)    = 0. _d 0
              N_recycle(i,j,k)    = 0. _d 0
              P_recycle(i,j,k)    = 0. _d 0
              Fe_recycle(i,j,k)   = 0. _d 0
              N_remindvm(i,j,k)   = 0. _d 0
              P_remindvm(i,j,k)   = 0. _d 0
              Fe_remindvm(i,j,k)  = 0. _d 0
              N_den_benthic(i,j,k)= 0. _d 0
              N_den_pelag(i,j,k)  = 0. _d 0
              DON_prod(i,j,k)     = 0. _d 0
              DOP_prod(i,j,k)     = 0. _d 0
              CaCO3_prod(i,j,k)   = 0. _d 0
              CaCO3_diss(i,j,k)   = 0. _d 0
              POC_flux(i,j,k)     = 0. _d 0
              NPP(i,j,k)          = 0. _d 0
              NCP(i,j,k)          = 0. _d 0
          ENDDO
        ENDDO
       ENDDO
        DO j=jmin,jmax
          DO i=imin,imax
              Fe_burial(i,j)       = 0. _d 0
              NO3_sed(i,j)         = 0. _d 0
              PO4_sed(i,j)         = 0. _d 0
              O2_sed(i,j)          = 0. _d 0
          ENDDO
        ENDDO
cxx order


C  ---------------------------------------------------------------------
c DIEL VERTICAL MIGRATOR EXPORT
c The effect of vertically-migrating animals on the export flux of organic
c matter from the ocean surface is treated similarly to the scheme of
c Bianchi et al., Nature Geoscience 2013. 
c This involves calculating the stationary depth of vertical migrators, using
c an empirical multivariate regression, and ensuring that this remains 
c above the bottom as well as any suboxic waters.
c The total DVM export flux is partitioned between a swimming migratory 
c component and the stationary component, and these are summed.


C$TAF LOOP = parallel
      DO j=jmin,jmax
C$TAF LOOP = parallel
       DO i=imin,imax


C        ! Initialize the working variables to zero
        o2_upper = 0. 
        o2_lower = 0. 
        dz_upper = 0. 
        dz_lower = 0. 
        temp_upper = 0. 
        temp_lower = 0. 
        z_dvm_regr = 0. 
        frac_migr = 0.
        fdvm_migr = 0. 
        fdvm_stat = 0. 
        fdvmn_vint = 0. 
        fdvmp_vint = 0. 
        fdvmfe_vint = 0.

        DO k=1,Nr

         IF ( hFacC(i,j,k,bi,bj).gt.0. _d 0 ) THEN

      ! Calculate the depth of migration based on linear regression.

        depth_l=-rF(k+1)
  
        ! Average temperature and oxygen over upper 35 m, and 140-515m. Also convert O2 to mmol m-3.

          if ( abs(depth_l) .lt. 35.) then
            dz_upper = dz_upper + drf(k)
            temp_upper = temp_upper + theta(i,j,k,bi,bj)*drf(k)
            o2_upper = o2_upper + PTR_O2(i,j,k) * drf(k)*1.0 _d 3
          endif
          if ( (abs(depth_l) .gt. 140.0 _d 0) .and. 
     &          (abs(depth_l) .lt. 515. _d 0)) then
            dz_lower = dz_lower + drf(k)
            temp_lower = temp_lower + theta(i,j,k,bi,bj)*drf(k)
            o2_lower = o2_lower + PTR_O2(i,j,k) * drf(k)*1.0 _d 3
          endif

         ENDIF
        ENDDO
          
        o2_upper = o2_upper / (epsln + dz_upper)
        temp_upper = temp_upper / (epsln + dz_upper)
        o2_lower = o2_lower / (epsln + dz_lower)
        temp_lower = temp_lower / (epsln + dz_lower)

        ! Calculate the regression, using the constants given in Bianchi et al. (2013).
        ! The variable values are bounded to lie within reasonable ranges:
        ! O2 gradient   : [-10,300] mmol/m3 
        ! Log10 Chl     : [-1.8,0.85] log10(mg/m3)
        ! mld           : [0,500] m
        ! T gradient    : [-3,20] C

C!! I'm replacing hblt_depth(i,j) with mld... not sure what hblt_depth is

#ifdef BLING_ADJOINT_SAFE
        z_dvm = 300. _d 0

#else

        z_dvm_regr = 398. _d 0 
     &   - 0.56 _d 0*min(300. _d 0,max(-10. _d 0,(o2_upper - o2_lower)))
     &   - 115. _d 0*min(0.85 _d 0,max(-1.80 _d 0,
     &                            log10(max(chl(i,j,1,bi,bj),chl_min))))
     &   + 0.36 _d 0*min(500. _d 0,max(epsln,mld(i,j)))
     &   - 2.40 _d 0*min(20. _d 0,max(-3. _d 0,(temp_upper-temp_lower)))

c        ! Limit the depth of migration in polar winter.
c        ! Use irr_mem since this is averaged over multiple days, dampening the diurnal cycle.
c        ! Tapers Z_DVM to the minimum when surface irradince is below a given threshold (here 10 W/m2).

        if ( irr_mem(i,j,1,bi,bj) .lt. 10. ) then                       
          z_dvm_regr = 150. _d 0 + (z_dvm_regr - 150. _d 0) * 
     &       irr_mem(i,j,1,bi,bj) / 10. _d 0
        endif                                                           

C Check for suboxic water within the column. If found, set dvm  
C stationary depth to 2 layers above it. This is not meant to 
C represent a cessation of downward migration, but rather the 
C requirement for aerobic DVM respiration to occur above the suboxic 
C water, where O2 is available.
 
        tmp = 0
        DO k=1,Nr-2

         IF ( (hFacC(i,j,k,bi,bj).gt.0. _d 0) .and. (tmp.eq.0)) THEN

          z_dvm = -rf(k+1)
          if (PTR_O2(i,j,k+2) .lt. (5. _d 0*oxic_min)) tmp = 1
          
         ENDIF
          
        enddo  

C The stationary depth is constrained between 150 and 700, above any  
C anoxic waters found, and above the bottom.

        z_dvm = min(700. _d 0,max(150. _d 0,z_dvm_regr),z_dvm,-rf(k+1))
c!!           bling%zbot(i,j,grid_kmt(i,j))) * grid_tmask(i,j,1)
c!! what is grid_mkt??

#endif

        ! Calculate the fraction of migratory respiration that occurs during upwards
        ! and downwards swimming. The remainder is respired near the stationary depth.
        ! Constants for swimming speed and resting time are hard-coded after Bianchi 
        ! et al, Nature Geoscience 2013.

        frac_migr = max( 0.0 _d 0, min( 1.0 _d 0, (2.0 _d 0 * z_dvm) /
     &        (epsln + 0.05 _d 0 * 0.5 _d 0 * 86400. _d 0)))

        ! Calculate the vertical profile shapes of DVM fluxes. These are given as
        ! the downward organic flux due to migratory DVM remineralization, defined at  
        ! the bottom of each layer k. 


        tmp = 0
        DO k=1,Nr

         IF ( (hFacC(i,j,k,bi,bj).gt.0. _d 0) .and. (tmp.eq.0)) THEN

          ! First, calculate the part due to active migration above the stationary depth.
          if (-rf(k+1) .lt. z_dvm) then  
            fdvm_migr = frac_migr / (epsln + z_dvm - (-rf(2))) *      
     &            (z_dvm - (-rf(k+1)) )
          else  
            fdvm_migr  = 0.0
          endif  

          ! Then, calculate the part at the stationary depth.
c          fdvm_stat = (1. - frac_migr) / 2. * erfcc((-rf(k) - z_dvm) / 
c     &        ( (epsln + 2. * sigma_dvm**2.)**0.5))


c  ! Approximation of the complementary error function
c  ! From Numerical Recipes (F90, Ch. 6, p. 216)
c  ! Returns the complementary error function erfc(x)
c    with fractional error everywhere less than 1.2e-7     
           x_erfcc = (-rf(k) - z_dvm) / 
     &        ( (epsln + 2. _d 0 * sigma_dvm**2. _d 0)**0.5)

           z_erfcc = abs(x_erfcc)

           t_erfcc = 1. _d 0/(1. _d 0+0.5 _d 0*z_erfcc)

           erfcc = t_erfcc*exp(-z_erfcc*z_erfcc-1.26551223+t_erfcc*
     &       (1.00002368+t_erfcc*(0.37409196+t_erfcc*
     &       (.09678418+t_erfcc*(-.18628806+t_erfcc*(.27886807+
     &       t_erfcc*(-1.13520398+t_erfcc*(1.48851587+
     &       t_erfcc*(-0.82215223+t_erfcc*0.17087277)))))))))

          if (x_erfcc .lt. 0.0) then
            erfcc = 2.0 - erfcc
          endif
    
    
          fdvm_stat = (1. _d 0 - frac_migr) / 2. _d 0 * erfcc 
       
C Add the shapes, resulting in the 3-d DVM flux operator. If the 
C current layer is the bottom layer, or the layer beneath the 
C underlying layer is suboxic, all fluxes at and below the current 
C layer remain at the initialized value of zero. This will cause all 
C remaining DVM remineralization to occur in this layer.
          IF (k.LT.NR-1) THEN
            if (PTR_O2(i,j,k+2) .lt. (5. _d 0*oxic_min)) tmp = 1
          ENDIF
c!!          if (k .eq. grid_kmt(i,j)) exit
          dvm(i,j,k)  = fdvm_migr + fdvm_stat
          
         ENDIF
          
        enddo  

c Sum up the total organic flux to be transported by DVM 

        do k = 1, nr 
          fdvmn_vint  = fdvmn_vint  + N_dvm(i,j,k)  * drf(k)
          fdvmp_vint  = fdvmp_vint  + P_dvm(i,j,k)  * drf(k)
          fdvmfe_vint = fdvmfe_vint + Fe_dvm(i,j,k) * drf(k)
        enddo  

c Calculate the remineralization terms as the divergence of the flux

        N_remindvm(i,j,1)  = fdvmn_vint *  (1 - dvm(i,j,1)) /
     &     (epsln + drf(1))
        P_remindvm(i,j,1)  = fdvmp_vint *  (1 - dvm(i,j,1)) /
     &     (epsln + drf(1))
        Fe_remindvm(i,j,1) = fdvmfe_vint * (1 - dvm(i,j,1)) / 
     &     (epsln + drf(1))

        do k = 2, nr
          N_remindvm(i,j,k)  = fdvmn_vint  * 
     &       (dvm(i,j,k-1) - dvm(i,j,k)) / (epsln + drf(k))
          P_remindvm(i,j,k)  = fdvmp_vint  * 
     &       (dvm(i,j,k-1) - dvm(i,j,k)) / (epsln + drf(k))
          Fe_remindvm(i,j,k) = fdvmfe_vint *
     &       (dvm(i,j,k-1) - dvm(i,j,k)) / (epsln + drf(k))
        enddo  

       enddo 
      enddo

c ---------------------------------------------------------------------

#ifdef ALLOW_DIAGNOSTICS
      IF ( useDiagnostics ) THEN

        CALL DIAGNOSTICS_FILL(Fe_dvm,'BLGFEDVM',0,Nr,2,bi,bj,myThid)
        CALL DIAGNOSTICS_FILL(N_dvm,'BLGNDVM ',0,Nr,2,bi,bj,myThid)
        CALL DIAGNOSTICS_FILL(P_dvm,'BLGPDVM ',0,Nr,2,bi,bj,myThid)
        CALL DIAGNOSTICS_FILL(dvm,'BLGDVM  ',0,Nr,2,bi,bj,myThid)

      ENDIF
#endif /* ALLOW_DIAGNOSTICS */

#endif /* ALLOW_BLING */

      RETURN
      END
1	mmazloff	1.4	C $Header: /u/gcmpack/MITgcm_contrib/bling/pkg/bling_dvm.F,v 1.3 2016/05/19 16:30:00 mmazloff Exp $
2	mmazloff	1.2	C $Name: $
3	mmazloff	1.1
4			#include "BLING_OPTIONS.h"
5
6			CBOP
7			subroutine BLING_DVM(
8			I N_dvm,P_dvm,Fe_dvm,
9			I PTR_O2, mld,
10			O N_remindvm, P_remindvm, Fe_remindvm,
11			I bi, bj, imin, imax, jmin, jmax,
12			I myIter, myTime, myThid )
13
14			C =================================================================
15			C \| subroutine bling_prod
16			C \| o Nutrient uptake and partitioning between organic pools.
17			C \| - Phytoplankton biomass-specific growth rate is calculated
18			C \| as a function of light, nutrient limitation, and
19			C \| temperature.
20			C \| - Biomass growth xxx
21			C \| o Organic matter export, remineralization, and recycling.
22			C \| - Sinking particulate flux and diel migration contribute to
23			C \| export.
24			C \| - Denitrification xxx
25			C =================================================================
26
27			implicit none
28
29			C === Global variables ===
30			C P_sm :: Small phytoplankton biomass
31			C P_lg :: Large phytoplankton biomass
32			C P_diaz :: Diazotroph phytoplankton biomass
33			C irr_mem :: Phyto irradiance memory
34
35			#include "SIZE.h"
36			#include "DYNVARS.h"
37			#include "EEPARAMS.h"
38			#include "PARAMS.h"
39			#include "GRID.h"
40			#include "BLING_VARS.h"
41			#include "PTRACERS_SIZE.h"
42			#include "PTRACERS_PARAMS.h"
43			#ifdef ALLOW_AUTODIFF
44			# include "tamc.h"
45			#endif
46
47			C === Routine arguments ===
48			C bi,bj :: tile indices
49			C iMin,iMax :: computation domain: 1rst index range
50			C jMin,jMax :: computation domain: 2nd index range
51			C myTime :: current time
52			C myIter :: current timestep
53			C myThid :: thread Id. number
54			INTEGER bi, bj, imin, imax, jmin, jmax
55			_RL myTime
56			INTEGER myIter
57			INTEGER myThid
58			C === Input ===
59			C PTR_NO3 :: nitrate concentration
60			C PTR_PO4 :: phosphate concentration
61			C PTR_FE :: iron concentration
62			C PTR_DON :: dissolved organic nitrogen concentration
63			C PTR_DOP :: dissolved organic phosphorus concentration
64			C PTR_O2 :: oxygen concentration
65			_RL PTR_NO3(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
66			_RL PTR_PO4(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
67			_RL PTR_FE (1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
68			_RL PTR_DON(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
69			_RL PTR_DOP(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
70			_RL PTR_O2 (1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
71			C === Output ===
72			C G_xxx :: Tendency of xxx
73			_RL G_NO3 (1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
74			_RL G_PO4 (1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
75			_RL G_FE (1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
76			_RL G_O2 (1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
77			_RL G_DON (1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
78			_RL G_DOP (1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
79			_RL G_CACO3 (1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
80
81			#ifdef ALLOW_BLING
82			C === Local variables ===
83			C i,j,k :: loop indices
84			C irr_eff :: effective irradiance
85			C NO3_lim :: nitrate limitation
86			C PO4_lim :: phosphate limitation
87			C Fe_lim :: iron limitation for phytoplankton
88			C Fe_lim_diaz :: iron limitation for diazotrophs
89			C alpha_Fe :: initial slope of the P-I curve
90			C theta_Fe :: Chl:C ratio
91			C theta_Fe_max :: Fe-replete maximum Chl:C ratio
92			C irrk :: nut-limited efficiency of algal photosystems
93			C Pc_m :: light-saturated max photosynthesis rate for phyt
94			C Pc_m_diaz :: light-saturated max photosynthesis rate for diaz
95			C Pc_tot :: carbon-specific photosynthesis rate
96			C expkT :: temperature function
97			C mu :: net carbon-specific growth rate for phyt
98			C mu_diaz :: net carbon-specific growth rate for diaz
99			C biomass_sm :: nitrogen concentration in small phyto biomass
100			C biomass_lg :: nitrogen concentration in large phyto biomass
101			C N_uptake :: nitrogen uptake
102			C N_fix :: nitrogen fixation
103			C P_uptake :: phosphorus uptake
104			C POC_flux :: carbon export flux 3d field
105			C PtoN :: variable ratio of phosphorus to nitrogen
106			C FetoN :: variable ratio of iron to nitrogen
107			C N_spm :: particulate sinking of nitrogen
108			C P_spm :: particulate sinking of phosphorus
109			C Fe_spm :: particulate sinking of iron
110			C N_dvm :: vertical transport of nitrogen by DVM
111			C P_dvm :: vertical transport of phosphorus by DVM
112			C Fe_dvm :: vertical transport of iron by DVM
113			C N_recycle :: recycling of newly-produced organic nitrogen
114			C P_recycle :: recycling of newly-produced organic phosphorus
115			C Fe_recycle :: recycling of newly-produced organic iron
116			c xxx to be completed
117			INTEGER i,j,k
118			INTEGER tmp
119			_RL irr_eff(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
120			_RL NO3_lim
121			_RL PO4_lim
122			_RL Fe_lim
123			_RL Fe_lim_diaz
124			_RL expkT
125			_RL Pc_m
126			_RL Pc_m_diaz
127			_RL theta_Fe_max
128			_RL theta_Fe
129			_RL irrk
130			_RL mu(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
131			_RL mu_diaz(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
132			_RL PtoN(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
133			_RL FetoN(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
134			_RL N_uptake(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
135			_RL N_fix(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
136			_RL P_uptake(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
137			_RL Fe_uptake(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
138			_RL frac_exp
139			_RL N_spm(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
140			_RL P_spm(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
141			_RL Fe_spm(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
142			_RL N_dvm(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
143			_RL P_dvm(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
144			_RL Fe_dvm(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
145			_RL DON_prod(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
146			_RL DOP_prod(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
147			_RL N_recycle(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
148			_RL P_recycle(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
149			_RL Fe_recycle(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
150			_RL POC_flux(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
151			_RL NPP(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
152			_RL NCP(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
153			_RL CaCO3_prod(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
154			_RL PONflux_u
155			_RL POPflux_u
156			_RL PFEflux_u
157			_RL CaCO3flux_u
158			_RL PONflux_l
159			_RL POPflux_l
160			_RL PFEflux_l
161			_RL CaCO3flux_l
162			_RL depth_l
163			_RL zremin
164			_RL zremin_caco3
165			_RL wsink
166			_RL POC_sed
167			_RL Fe_sed(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
168			_RL NO3_sed(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
169			_RL PO4_sed(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
170			_RL O2_sed(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
171			_RL lig_stability
172			_RL FreeFe
173			_RL Fe_ads_inorg(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
174			_RL Fe_ads_org(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
175			_RL N_den_pelag(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
176			_RL N_den_benthic(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
177			_RL log_btm_flx
178			_RL N_reminp(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
179			_RL P_reminp(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
180			_RL Fe_reminp(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
181			_RL CacO3_diss(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
182			_RL o2_upper
183			_RL o2_lower
184			_RL dz_upper
185			_RL dz_lower
186			_RL temp_upper
187			_RL temp_lower
188			_RL z_dvm_regr
189			_RL frac_migr
190			_RL fdvm_migr
191			_RL fdvm_stat
192			_RL fdvmn_vint
193			_RL fdvmp_vint
194			_RL fdvmfe_vint
195			_RL z_dvm
196			_RL N_remindvm(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
197			_RL P_remindvm(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
198			_RL Fe_remindvm(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
199			_RL dvm(1-OLx:sNx+OLx,1-OLy:sNy+OLy,Nr)
200			_RL mld(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
201			_RL Fe_burial(1-OLx:sNx+OLx,1-OLy:sNy+OLy)
202			_RL x_erfcc,z_erfcc,t_erfcc,erfcc
203			cxx order
204			CEOP
205
206			c ---------------------------------------------------------------------
207			c Initialize output and diagnostics
208			DO k=1,Nr
209			DO j=jmin,jmax
210			DO i=imin,imax
211			G_NO3(i,j,k) = 0. _d 0
212			G_PO4(i,j,k) = 0. _d 0
213			G_FE(i,j,k) = 0. _d 0
214			G_O2(i,j,k) = 0. _d 0
215			G_DON(i,j,k) = 0. _d 0
216			G_DOP(i,j,k) = 0. _d 0
217			G_CaCO3(i,j,k) = 0. _d 0
218			N_uptake(i,j,k) = 0. _d 0
219			P_uptake(i,j,k) = 0. _d 0
220			Fe_uptake(i,j,k) = 0. _d 0
221			Fe_ads_org(i,j,k) = 0. _d 0
222			Fe_ads_inorg(i,j,k) = 0. _d 0
223			mu(i,j,k) = 0. _d 0
224			mu_diaz(i,j,k) = 0. _d 0
225			irr_eff(i,j,k) = 0. _d 0
226			PtoN(i,j,k) = 0. _d 0
227			FetoN(i,j,k) = 0. _d 0
228			N_fix(i,j,k) = 0. _d 0
229			N_spm(i,j,k) = 0. _d 0
230			P_spm(i,j,k) = 0. _d 0
231			Fe_spm(i,j,k) = 0. _d 0
232			dvm(i,j,k) = 0. _d 0
233			N_reminp(i,j,k) = 0. _d 0
234			P_reminp(i,j,k) = 0. _d 0
235			Fe_reminp(i,j,k) = 0. _d 0
236			N_recycle(i,j,k) = 0. _d 0
237			P_recycle(i,j,k) = 0. _d 0
238			Fe_recycle(i,j,k) = 0. _d 0
239			N_remindvm(i,j,k) = 0. _d 0
240			P_remindvm(i,j,k) = 0. _d 0
241			Fe_remindvm(i,j,k) = 0. _d 0
242			N_den_benthic(i,j,k)= 0. _d 0
243			N_den_pelag(i,j,k) = 0. _d 0
244			DON_prod(i,j,k) = 0. _d 0
245			DOP_prod(i,j,k) = 0. _d 0
246			CaCO3_prod(i,j,k) = 0. _d 0
247			CaCO3_diss(i,j,k) = 0. _d 0
248			POC_flux(i,j,k) = 0. _d 0
249			NPP(i,j,k) = 0. _d 0
250			NCP(i,j,k) = 0. _d 0
251			ENDDO
252			ENDDO
253			ENDDO
254			DO j=jmin,jmax
255			DO i=imin,imax
256			Fe_burial(i,j) = 0. _d 0
257			NO3_sed(i,j) = 0. _d 0
258			PO4_sed(i,j) = 0. _d 0
259			O2_sed(i,j) = 0. _d 0
260			ENDDO
261			ENDDO
262			cxx order
263
264
265			C ---------------------------------------------------------------------
266			c DIEL VERTICAL MIGRATOR EXPORT
267			c The effect of vertically-migrating animals on the export flux of organic
268			c matter from the ocean surface is treated similarly to the scheme of
269			c Bianchi et al., Nature Geoscience 2013.
270			c This involves calculating the stationary depth of vertical migrators, using
271			c an empirical multivariate regression, and ensuring that this remains
272			c above the bottom as well as any suboxic waters.
273			c The total DVM export flux is partitioned between a swimming migratory
274			c component and the stationary component, and these are summed.
275
276
277
278			C$TAF LOOP = parallel
279			DO j=jmin,jmax
280			C$TAF LOOP = parallel
281			DO i=imin,imax
282
283
284			C ! Initialize the working variables to zero
285			o2_upper = 0.
286			o2_lower = 0.
287			dz_upper = 0.
288			dz_lower = 0.
289			temp_upper = 0.
290			temp_lower = 0.
291			z_dvm_regr = 0.
292			frac_migr = 0.
293			fdvm_migr = 0.
294			fdvm_stat = 0.
295			fdvmn_vint = 0.
296			fdvmp_vint = 0.
297			fdvmfe_vint = 0.
298
299			DO k=1,Nr
300
301			IF ( hFacC(i,j,k,bi,bj).gt.0. _d 0 ) THEN
302
303			! Calculate the depth of migration based on linear regression.
304
305			depth_l=-rF(k+1)
306
307			! Average temperature and oxygen over upper 35 m, and 140-515m. Also convert O2 to mmol m-3.
308
309			if ( abs(depth_l) .lt. 35.) then
310			dz_upper = dz_upper + drf(k)
311			temp_upper = temp_upper + theta(i,j,k,bi,bj)*drf(k)
312			o2_upper = o2_upper + PTR_O2(i,j,k) * drf(k)*1.0 _d 3
313			endif
314			if ( (abs(depth_l) .gt. 140.0 _d 0) .and.
315			& (abs(depth_l) .lt. 515. _d 0)) then
316			dz_lower = dz_lower + drf(k)
317			temp_lower = temp_lower + theta(i,j,k,bi,bj)*drf(k)
318			o2_lower = o2_lower + PTR_O2(i,j,k) * drf(k)*1.0 _d 3
319			endif
320
321			ENDIF
322			ENDDO
323
324			o2_upper = o2_upper / (epsln + dz_upper)
325			temp_upper = temp_upper / (epsln + dz_upper)
326			o2_lower = o2_lower / (epsln + dz_lower)
327			temp_lower = temp_lower / (epsln + dz_lower)
328
329			! Calculate the regression, using the constants given in Bianchi et al. (2013).
330			! The variable values are bounded to lie within reasonable ranges:
331			! O2 gradient : [-10,300] mmol/m3
332			! Log10 Chl : [-1.8,0.85] log10(mg/m3)
333			! mld : [0,500] m
334			! T gradient : [-3,20] C
335
336			C!! I'm replacing hblt_depth(i,j) with mld... not sure what hblt_depth is
337
338			#ifdef BLING_ADJOINT_SAFE
339			z_dvm = 300. _d 0
340
341			#else
342
343	mmazloff	1.4	z_dvm_regr = 398. _d 0
344			& - 0.56 _d 0*min(300. _d 0,max(-10. _d 0,(o2_upper - o2_lower)))
345			& - 115. _d 0*min(0.85 _d 0,max(-1.80 _d 0,
346			& log10(max(chl(i,j,1,bi,bj),chl_min))))
347			& + 0.36 _d 0*min(500. _d 0,max(epsln,mld(i,j)))
348			& - 2.40 _d 0*min(20. _d 0,max(-3. _d 0,(temp_upper-temp_lower)))
349
350			c ! Limit the depth of migration in polar winter.
351			c ! Use irr_mem since this is averaged over multiple days, dampening the diurnal cycle.
352			c ! Tapers Z_DVM to the minimum when surface irradince is below a given threshold (here 10 W/m2).
353	mmazloff	1.1
354			if ( irr_mem(i,j,1,bi,bj) .lt. 10. ) then
355			z_dvm_regr = 150. _d 0 + (z_dvm_regr - 150. _d 0) *
356			& irr_mem(i,j,1,bi,bj) / 10. _d 0
357			endif
358
359			C Check for suboxic water within the column. If found, set dvm
360			C stationary depth to 2 layers above it. This is not meant to
361			C represent a cessation of downward migration, but rather the
362			C requirement for aerobic DVM respiration to occur above the suboxic
363			C water, where O2 is available.
364
365			tmp = 0
366	mmazloff	1.3	DO k=1,Nr-2
367	mmazloff	1.1
368			IF ( (hFacC(i,j,k,bi,bj).gt.0. _d 0) .and. (tmp.eq.0)) THEN
369
370			z_dvm = -rf(k+1)
371			if (PTR_O2(i,j,k+2) .lt. (5. _d 0*oxic_min)) tmp = 1
372
373			ENDIF
374
375			enddo
376
377			C The stationary depth is constrained between 150 and 700, above any
378			C anoxic waters found, and above the bottom.
379
380			z_dvm = min(700. _d 0,max(150. _d 0,z_dvm_regr),z_dvm,-rf(k+1))
381			c!! bling%zbot(i,j,grid_kmt(i,j))) * grid_tmask(i,j,1)
382			c!! what is grid_mkt??
383
384			#endif
385
386			! Calculate the fraction of migratory respiration that occurs during upwards
387			! and downwards swimming. The remainder is respired near the stationary depth.
388			! Constants for swimming speed and resting time are hard-coded after Bianchi
389			! et al, Nature Geoscience 2013.
390
391			frac_migr = max( 0.0 _d 0, min( 1.0 _d 0, (2.0 _d 0 * z_dvm) /
392			& (epsln + 0.05 _d 0 * 0.5 _d 0 * 86400. _d 0)))
393
394			! Calculate the vertical profile shapes of DVM fluxes. These are given as
395			! the downward organic flux due to migratory DVM remineralization, defined at
396			! the bottom of each layer k.
397
398
399			tmp = 0
400			DO k=1,Nr
401
402			IF ( (hFacC(i,j,k,bi,bj).gt.0. _d 0) .and. (tmp.eq.0)) THEN
403
404			! First, calculate the part due to active migration above the stationary depth.
405			if (-rf(k+1) .lt. z_dvm) then
406			fdvm_migr = frac_migr / (epsln + z_dvm - (-rf(2))) *
407			& (z_dvm - (-rf(k+1)) )
408			else
409			fdvm_migr = 0.0
410			endif
411
412			! Then, calculate the part at the stationary depth.
413			c fdvm_stat = (1. - frac_migr) / 2. * erfcc((-rf(k) - z_dvm) /
414			c & ( (epsln + 2. * sigma_dvm2.)0.5))
415
416
417	mmazloff	1.3	c ! Approximation of the complementary error function
418			c ! From Numerical Recipes (F90, Ch. 6, p. 216)
419			c ! Returns the complementary error function erfc(x)
420			c with fractional error everywhere less than 1.2e-7
421	mmazloff	1.1	x_erfcc = (-rf(k) - z_dvm) /
422			& ( (epsln + 2. _d 0 * sigma_dvm2. _d 0)0.5)
423
424			z_erfcc = abs(x_erfcc)
425
426			t_erfcc = 1. _d 0/(1. _d 0+0.5 _d 0*z_erfcc)
427
428			erfcc = t_erfccexp(-z_erfccz_erfcc-1.26551223+t_erfcc*
429			& (1.00002368+t_erfcc(0.37409196+t_erfcc
430			& (.09678418+t_erfcc(-.18628806+t_erfcc(.27886807+
431			& t_erfcc(-1.13520398+t_erfcc(1.48851587+
432			& t_erfcc(-0.82215223+t_erfcc0.17087277)))))))))
433
434			if (x_erfcc .lt. 0.0) then
435			erfcc = 2.0 - erfcc
436			endif
437
438
439			fdvm_stat = (1. _d 0 - frac_migr) / 2. _d 0 * erfcc
440
441			C Add the shapes, resulting in the 3-d DVM flux operator. If the
442			C current layer is the bottom layer, or the layer beneath the
443			C underlying layer is suboxic, all fluxes at and below the current
444			C layer remain at the initialized value of zero. This will cause all
445			C remaining DVM remineralization to occur in this layer.
446	mmazloff	1.3	IF (k.LT.NR-1) THEN
447			if (PTR_O2(i,j,k+2) .lt. (5. _d 0*oxic_min)) tmp = 1
448			ENDIF
449	mmazloff	1.1	c!! if (k .eq. grid_kmt(i,j)) exit
450			dvm(i,j,k) = fdvm_migr + fdvm_stat
451
452			ENDIF
453
454			enddo
455
456			c Sum up the total organic flux to be transported by DVM
457
458			do k = 1, nr
459			fdvmn_vint = fdvmn_vint + N_dvm(i,j,k) * drf(k)
460			fdvmp_vint = fdvmp_vint + P_dvm(i,j,k) * drf(k)
461			fdvmfe_vint = fdvmfe_vint + Fe_dvm(i,j,k) * drf(k)
462			enddo
463
464			c Calculate the remineralization terms as the divergence of the flux
465
466			N_remindvm(i,j,1) = fdvmn_vint * (1 - dvm(i,j,1)) /
467			& (epsln + drf(1))
468			P_remindvm(i,j,1) = fdvmp_vint * (1 - dvm(i,j,1)) /
469			& (epsln + drf(1))
470			Fe_remindvm(i,j,1) = fdvmfe_vint * (1 - dvm(i,j,1)) /
471			& (epsln + drf(1))
472
473			do k = 2, nr
474			N_remindvm(i,j,k) = fdvmn_vint *
475			& (dvm(i,j,k-1) - dvm(i,j,k)) / (epsln + drf(k))
476			P_remindvm(i,j,k) = fdvmp_vint *
477			& (dvm(i,j,k-1) - dvm(i,j,k)) / (epsln + drf(k))
478			Fe_remindvm(i,j,k) = fdvmfe_vint *
479			& (dvm(i,j,k-1) - dvm(i,j,k)) / (epsln + drf(k))
480			enddo
481
482			enddo
483			enddo
484
485			c ---------------------------------------------------------------------
486
487			#ifdef ALLOW_DIAGNOSTICS
488			IF ( useDiagnostics ) THEN
489
490			CALL DIAGNOSTICS_FILL(Fe_dvm,'BLGFEDVM',0,Nr,2,bi,bj,myThid)
491			CALL DIAGNOSTICS_FILL(N_dvm,'BLGNDVM ',0,Nr,2,bi,bj,myThid)
492			CALL DIAGNOSTICS_FILL(P_dvm,'BLGPDVM ',0,Nr,2,bi,bj,myThid)
493			CALL DIAGNOSTICS_FILL(dvm,'BLGDVM ',0,Nr,2,bi,bj,myThid)
494
495			ENDIF
496			#endif /* ALLOW_DIAGNOSTICS */
497
498			#endif /* ALLOW_BLING */
499
500			RETURN
501			END