MODULE module_mozcart_wetscav

   USE module_configure
   USE module_state_description

IMPLICIT NONE

private
public :: wetscav_mozcart_init
public :: wetscav_mozcart

save

! 20130716 acd_ck_vbsmoz start
! added OVOC washout
!   integer, parameter :: wetscav_tab_cnt = 37
   integer, parameter :: wetscav_tab_cnt = 37 + 10
! 20130716 acd_ck_vbsmoz end
   real, parameter :: zero = 0.
   real, parameter :: one  = 1.
   real, parameter :: four = 4.
   real(8), parameter :: oner8  = 1._8
   real(8), parameter :: fourr8 = 4._8
   real, parameter :: adj_factor = one + 10.*epsilon( one )
   real, parameter :: TICE = 273.
   real, parameter :: TMIX = 258.
   integer, parameter :: idiag = 0
   integer, parameter :: jdiag = 0
   integer, parameter :: kdiag = 18

   integer :: hetcnt
   integer :: hno3_ndx = 0
   integer, allocatable :: wrf2tab(:)
   REAL, allocatable    :: mol_wght(:)
   logical, allocatable :: ice_uptake(:)

   type wet_scav
     character(len=12) :: name
     integer :: p_ndx
     real    :: heff(6)
     real    :: molecw
     logical :: ice_uptake
!++mmb
     real    :: reteff
!--mmb
   end type wet_scav

   type(wet_scav), allocatable :: wet_scav_tab(:)

   LOGICAL, EXTERNAL  :: wrf_dm_on_monitor

CONTAINS

   subroutine wetscav_mozcart_init( id, numgas, config_flags )
!----------------------------------------------------------------------
!  Initialize the mozart, mozcart wet scavenging module
!----------------------------------------------------------------------
   use module_scalar_tables, only : chem_dname_table

!----------------------------------------------------------------------
!  dummy arguments
!----------------------------------------------------------------------
   integer, intent(in)                           :: id
   integer, intent(in)                           :: numgas
   TYPE(grid_config_rec_type),  INTENT(IN   )    :: config_flags

!----------------------------------------------------------------------
!  local variables
!----------------------------------------------------------------------
   integer :: m, m1, m2
   integer :: astat
   character(len=12) :: wrf_spc_name
   character(len=128) :: message

is_allocated : &
   if( .not. allocated( wet_scav_tab ) ) then
     write(*,*) ' '
     write(*,*) 'wetscav_mozcart_init: species names'
     write(*,'(6a12)') chem_dname_table(id,param_first_scalar:numgas)
     write(*,*) ' '

     allocate( wet_scav_tab(wetscav_tab_cnt),stat=astat )
     if( astat /= 0 ) then
       call wrf_error_fatal("mozcart_wetscav_init: failed to allocate wet_scav_tab")
     endif

! 20140707 acd_ck_comment start
! not true anymore, comment can be removed
!!----------------------------------------------------------------------
!!  NOTE: this table does NOT include an entry for SO4
!!----------------------------------------------------------------------
! 20140707 acd_ck_comment end
!++mmb h2o2 ice scavenging ON
!    wet_scav_tab(1) = wet_scav( 'h2o2', p_h2o2, (/8.33e+04, 7379., 2.2e-12, -3730., 0., 0./), 34.0135994, .false. )
    wet_scav_tab(1) = wet_scav( 'h2o2', p_h2o2, (/8.33e+04, 7379., 2.2e-12, -3730., 0., 0./), 34.0135994, .true., 0. )
!--mmb
     wet_scav_tab(2) = wet_scav( 'hno3', p_hno3, (/0., 0., 2.6e+06, 8700., 0., 0./), 63.0123405, .true., 0. )
!++mmb KH Sander et al. (2006)
!    wet_scav_tab(3) = wet_scav( 'hcho', p_hcho, (/6.30e+03, 6425., 0., 0., 0., 0./), 30.0251999, .false. )
     wet_scav_tab(3) = wet_scav( 'hcho', p_hcho, (/3.23e+03, 7100., 0., 0., 0., 0./), 30.0251999, .true., 0. )
!--mmb
     wet_scav_tab(4) = wet_scav( 'ch3ooh', p_ch3ooh, (/3.11e+02, 5241., 0., 0., 0., 0./), 48.0393982, .true., 0.0 )
     wet_scav_tab(5) = wet_scav( 'c3h6ooh', p_c3h6ooh, (/2.20e+02, 5653., 0., 0., 0., 0./), 75.0835953, .false., 0. )
     wet_scav_tab(6) = wet_scav( 'paa', p_paa, (/8.37e+02, 5308., 1.8e-04, -1510., 0., 0./), 76.0498047, .false., 0. )
     wet_scav_tab(7) = wet_scav( 'hno4', p_hno4, (/0., 0., 3.2e+01, 0., 0., 0./), 79.0117416, .false., 0. )
     wet_scav_tab(8) = wet_scav( 'onit', p_onit, (/1.00e+03, 6000., 0., 0., 0., 0./), 119.074341, .false., 0. )
     wet_scav_tab(9) = wet_scav( 'mvk', p_mvk, (/1.7e-03, 0., 0., 0., 0., 0./), 70.0878067, .false., 0. )
     wet_scav_tab(10) = wet_scav( 'macr', p_macr, (/1.70e-03, 0., 0., 0., 0., 0./), 70.0878067, .false., 0. )
     wet_scav_tab(11) = wet_scav( 'etooh', p_etooh, (/3.36e+02, 5995., 0., 0., 0., 0./), 62.065197, .false., 0. )
     wet_scav_tab(12) = wet_scav( 'prooh', p_prooh, (/3.36e+02, 5995., 0., 0., 0., 0./), 76.0909958, .false., 0. )
     wet_scav_tab(13) = wet_scav( 'acetp', p_acetp, (/3.36e+02, 5995., 0., 0., 0., 0./), 90.0755997, .false., 0. )
     wet_scav_tab(14) = wet_scav( 'mgly', p_mgly, (/3.71e+03, 7541., 0., 0., 0., 0./), 72.0614014, .false., 0. )
     wet_scav_tab(15) = wet_scav( 'mvkooh', p_mvkooh, (/0., 0., 2.6e+06, 8700., 0., 0./), 120.1008, .false., 0. )
     wet_scav_tab(16) = wet_scav( 'onitr', p_onitr, (/7.51e+03, 6485., 0., 0., 0., 0./), 147.125946, .false., 0. )
     wet_scav_tab(17) = wet_scav( 'isooh', p_isooh, (/0., 0., 2.6e+06, 8700., 0., 0./), 118.127205, .false., 0. )
     wet_scav_tab(18) = wet_scav( 'ch3oh', p_ch3oh, (/2.20e+02, 4934., 0., 0., 0., 0./), 32.0400009, .false., 0. )
     wet_scav_tab(19) = wet_scav( 'c2h5oh', p_c2h5oh, (/2.00e+02, 6500., 0., 0., 0., 0./), 46.0657997, .false., 0. )
     wet_scav_tab(20) = wet_scav( 'glyald', p_glyald, (/4.14e+04, 4630., 0., 0., 0., 0./), 60.0504036, .false., 0. )
     wet_scav_tab(21) = wet_scav( 'hydrald', p_hydrald, (/7.00e+01, 6000., 0., 0., 0., 0./), 100.113007, .false., 0. )
     wet_scav_tab(22) = wet_scav( 'ald', p_ald, (/1.14e+01, 6267., 0., 0., 0., 0./), 44.0510025, .false., 0. )
     wet_scav_tab(23) = wet_scav( 'isopn', p_isopn, (/1.00e+01, 0., 0., 0., 0., 0./), 162.117935, .false., 0. )
     wet_scav_tab(24) = wet_scav( 'alkooh', p_alkooh, (/3.11e+02, 5241., 0., 0., 0., 0./), 104.142501, .false., 0. )
     wet_scav_tab(25) = wet_scav( 'mekooh', p_mekooh, (/3.11e+02, 5241., 0., 0., 0., 0./), 104.101395, .false., 0. )
     wet_scav_tab(26) = wet_scav( 'tolooh', p_tolooh, (/3.11e+02, 5241., 0., 0., 0., 0./), 142.1492, .false., 0. )
     wet_scav_tab(27) = wet_scav( 'terpooh', p_terpooh, (/3.11e+02, 5241., 0., 0., 0., 0./), 186.241394, .false., 0. )
     wet_scav_tab(28) = wet_scav( 'xhno3', -1, (/0., 0., 2.6e+06, 8700., 0., 0./), 63.0123405, .true., 0. )
     wet_scav_tab(29) = wet_scav( 'nh3', p_nh3, (/7.40e+01, 3400., 1.7e-05, -450., 1.0e-14, -6716./), 17.0289402, .false., 0. )
     wet_scav_tab(30) = wet_scav( 'xho2no2', -1, (/0., 0., 3.2e+01, 0., 0., 0./), 79.0117416, .false., 0. )
     wet_scav_tab(31) = wet_scav( 'xisopno3', -1, (/1.00e+01, 0., 0., 0., 0., 0./), 162.117935, .false., 0. )
     wet_scav_tab(32) = wet_scav( 'xonit', -1, (/1.00e+03, 6000., 0., 0., 0., 0./), 119.074341, .false., 0. )
     wet_scav_tab(33) = wet_scav( 'xonitr', -1, (/7.51e+03, 6485., 0., 0., 0., 0./), 147.125946, .false., 0. )
     wet_scav_tab(34) = wet_scav( 'xooh', p_xooh, (/90.5, 5607., 0., 0., 0., 0./), 134.126602, .false., 0. )
     wet_scav_tab(35) = wet_scav( 'ch3cooh', p_ch3cooh, (/4.1e3, 6300., 0., 0., 0., 0./), 60.0503998, .false., 0. )
! 20131125 acd_ck_bugfix start
! 20140619 acd_mb_bugfix start
     wet_scav_tab(36) = wet_scav( 'so2', p_so2, (/1.2, 3100., 1.3e-02, 1965., 0., 0./), 63.961901, .true., 0.0 )
! 20140619 acd_mb_bugfix end
     wet_scav_tab(37) = wet_scav( 'sulf', p_sulf, (/1e+11, 0., 0., 0., 0., 0./), 98.078, .false., 0. ) ! order of magnitude approx. (Gmitro and Vermeulen, 1964)
! 20131125 acd_ck_bugfix end

! 20130729 acd_ck_vbsmoz start
! 20130911 acd_ck_vbsdep mark
     IF (config_flags%chem_opt == MOZART_MOSAIC_4BIN_AQ_KPP) THEN
       wet_scav_tab(38) = wet_scav( 'cvasoaX', p_cvasoaX, (/0.0e+00, 0., 0., 0., 0., 0./), 150.0, .false., 0. )
       wet_scav_tab(39) = wet_scav( 'cvasoa1', p_cvasoa1, (/1.06E+08, 6014., 0., 0., 0., 0./), 150.0, .false., 0. )
       wet_scav_tab(40) = wet_scav( 'cvasoa2', p_cvasoa2, (/1.84E+07, 6014., 0., 0., 0., 0./), 150.0, .false., 0. )
       wet_scav_tab(41) = wet_scav( 'cvasoa3', p_cvasoa3, (/3.18E+06, 6014., 0., 0., 0., 0./), 150.0, .false., 0. )
       wet_scav_tab(42) = wet_scav( 'cvasoa4', p_cvasoa4, (/5.50E+05, 6014., 0., 0., 0., 0./), 150.0, .false., 0. )
       wet_scav_tab(43) = wet_scav( 'cvbsoaX', p_cvbsoaX, (/0.0e+00, 0., 0., 0., 0., 0./), 180.0, .false., 0. )
       wet_scav_tab(44) = wet_scav( 'cvbsoa1', p_cvbsoa1, (/5.25E+09, 6014., 0., 0., 0., 0./), 180.0, .false., 0. )
       wet_scav_tab(45) = wet_scav( 'cvbsoa2', p_cvbsoa2, (/7.00E+08, 6014., 0., 0., 0., 0./), 180.0, .false., 0. )
       wet_scav_tab(46) = wet_scav( 'cvbsoa3', p_cvbsoa3, (/9.33E+07, 6014., 0., 0., 0., 0./), 180.0, .false., 0. )
       wet_scav_tab(47) = wet_scav( 'cvbsoa4', p_cvbsoa4, (/1.24E+07, 6014., 0., 0., 0., 0./), 180.0, .false., 0. )
     ENDIF
 ! 20130729 acd_ck_vbsmoz end
  
   hetcnt = 0
   do m = param_first_scalar,numgas
     wrf_spc_name = chem_dname_table(id,m)
     do m1 = 1,wetscav_tab_cnt
       if( trim(wrf_spc_name) == trim(wet_scav_tab(m1)%name) .and. &
           wet_scav_tab(m1)%p_ndx >= param_first_scalar ) then
         hetcnt = hetcnt + 1
         exit
       endif
     end do
   end do

   m2 = 0
   if( hetcnt > 0 ) then
     allocate( wrf2tab(hetcnt),mol_wght(hetcnt),ice_uptake(hetcnt),stat=astat )
     if( astat /= 0 ) then
       call wrf_error_fatal("mozcart_wetscav_init: failed to allocate wrf2tab,mol_wght,ice_uptake")
     endif
     do m = param_first_scalar,numgas
       wrf_spc_name = chem_dname_table(id,m)
       do m1 = 1,wetscav_tab_cnt
         if( trim(wrf_spc_name) == trim(wet_scav_tab(m1)%name) .and. &
             wet_scav_tab(m1)%p_ndx >= param_first_scalar ) then
           m2 = m2 + 1
           wrf2tab(m2) = m1
           mol_wght(m2) = wet_scav_tab(m1)%molecw
           ice_uptake(m2) = wet_scav_tab(m1)%ice_uptake
           if( wet_scav_tab(m1)%p_ndx == p_hno3 ) then
             hno3_ndx = m2
           endif
           exit
         endif
       end do
     end do
   else
     write(*,*) ' '
     write(*,*) 'wetscav_mozcart_init: There are no wet scavenging mozcart species'
     write(*,*) ' '
     return
   endif

   write(*,*) 'wetscav_mozcart_init: Wet scavenging mozcart species'
   do m = 1,hetcnt
     write(*,*) m,wrf2tab(m),trim(wet_scav_tab(wrf2tab(m))%name),mol_wght(m),ice_uptake(m)
   end do

   if( wrf_dm_on_monitor() ) then
     write(*,*) ' '
     write(message,*) 'wetscav_mozcart_init: hetcnt = ',hetcnt
     call wrf_debug( 100, trim(message) )
     write(message,*) 'wetscav_mozcart_init: hno3_ndx = ',hno3_ndx
     call wrf_debug( 100, trim(message) )
     write(*,*) ' '
   endif
   endif is_allocated

   end subroutine wetscav_mozcart_init

   subroutine wetscav_mozcart( id, ktau, dtstep, ktauc, config_flags,                      &
                               dtstepc, t_phy, p8w, t8w, p_phy,                            &
                               chem, rho_phy, cldfra, rainprod, evapprod,                  &
                               qv_b4mp, qc_b4mp, qi_b4mp, qs_b4mp,                         &
                               gas_aqfrac, numgas_aqfrac, dz8w, dx, dy,                    &
                               qv, qc, qi, qs,                                             &
! 20131125 acd_ck_washout start
!                               hno3_col_mdel,                                              &
                               delta_mass_col,                                             &
! 20131125 acd_ck_washout end
                               ids,ide, jds,jde, kds,kde,                                  &
                               ims,ime, jms,jme, kms,kme,                                  &
                               its,ite, jts,jte, kts,kte                                   )

   USE module_configure, only: grid_config_rec_type
   USE module_state_description
   USE module_model_constants, only: g, mwdry

!----------------------------------------------------------------------
!  dummy arguments
!----------------------------------------------------------------------
   TYPE(grid_config_rec_type),  INTENT(IN   )    :: config_flags

   INTEGER,      INTENT(IN   )    ::                                &
                                      ids,ide, jds,jde, kds,kde,    &
                                      ims,ime, jms,jme, kms,kme,    &
                                      its,ite, jts,jte, kts,kte,    &
                                      id, ktau, ktauc, numgas_aqfrac
   REAL, INTENT(IN   ) :: dtstep, dtstepc
   REAL, INTENT(IN   ) :: dx, dy
!----------------------------------------------------------------------
! all advected chemical species
!----------------------------------------------------------------------
   REAL, DIMENSION( ims:ime, kms:kme, jms:jme, num_chem ),          &
         INTENT(INOUT ) ::                                chem
!----------------------------------------------------------------------
! fraction of gas species in cloud water
!----------------------------------------------------------------------
   REAL, DIMENSION( ims:ime, kms:kme, jms:jme, numgas_aqfrac ),     &
         INTENT(IN ) ::                                   gas_aqfrac
!----------------------------------------------------------------------
! input from meteorology
!----------------------------------------------------------------------
   REAL,  DIMENSION( ims:ime , kms:kme , jms:jme )         ,        &
         INTENT(IN   ) ::                                           &
                                                      t_phy,        &
                                                      p_phy,        &
                                                      t8w,          &
                                                      p8w,          &
                                                      dz8w,         &
                                                    rho_phy

   REAL, DIMENSION( ims:ime, kms:kme, jms:jme ), INTENT(IN   ) ::    &
                                                                 QV, &
                                                                 QI, &
                                                                 QC, &
                                                                 QS
   REAL, DIMENSION( ims:ime, kms:kme, jms:jme ), INTENT(IN   ) ::    &
                                                                 rainprod, &
                                                                 evapprod
   REAL, DIMENSION( ims:ime, kms:kme, jms:jme ), INTENT(IN   ) ::    &
                                                                 qv_b4mp, &
                                                                 qc_b4mp, &
                                                                 qi_b4mp, &
                                                                 qs_b4mp

   REAL,  DIMENSION( ims:ime , kms:kme , jms:jme )         ,        &
         INTENT(INOUT ) ::                                cldfra

! 20131125 acd_ck_washout start
!   REAL,  DIMENSION( ims:ime , jms:jme )         ,                  &
!         INTENT(INOUT ) ::                                hno3_col_mdel

   REAL,  DIMENSION( ims:ime , jms:jme, num_chem )         ,           &
         INTENT(OUT ) ::                                delta_mass_col
! 20131125 acd_ck_washout end

!----------------------------------------------------------------------
!  local variables
!----------------------------------------------------------------------
   real, parameter    :: t0 = 298.
   real, parameter    :: ph = 1.e-5
   real, parameter    :: ph_inv = 1./ph
   real, parameter    :: henry_thres = 1.e4

   integer :: i, j, k, ktem1, m, m1
   integer :: pndx
   integer :: cld_col_cnt
   integer :: precip_col_cnt
   integer :: max_ndx(3)
   integer :: wrk_ndx(3)
   REAL :: area
   REAL :: e298, dhr
   REAL :: percent_cld
   REAL :: percent_precip
   REAL :: max_rls
   REAL :: layer_mass(kts:kte)
   REAL :: delp(kts:kte)
   REAL :: p(kts:kte)
   REAL :: t(kts:kte)
   REAL :: rls(kts:kte)
   REAL :: evaprate(kts:kte)
   REAL :: totprec(kts:kte)
   REAL :: totevap(kts:kte)
   REAL :: wrk(kts:kte)
   REAL :: tfac(kts:kte)
   REAL :: dk1s(kts:kte)
   REAL :: dk2s(kts:kte)
   REAL :: diff(its:ite,kts:kte,jts:jte)
   REAL :: hno3(kts:kte)
   REAL :: wrk_mass(hetcnt)
   REAL :: trc_mass(kts:kte,hetcnt)
   REAL :: heff(kts:kte,hetcnt)

   logical :: is_hno3
   logical :: tckaqb(hetcnt)

!++mmb
   REAL :: reteff(hetcnt)
!--mmb

   character(len=128) :: message

has_wet_scav : &
   if( hetcnt > 0 ) then
!----------------------------------------------------------------------
!  form cloud fraction
!----------------------------------------------------------------------
     CALL cal_cldfra3( CLDFRA, qc_b4mp, qi_b4mp, qs_b4mp,         &
                      ids,ide, jds,jde, kds,kde,                  &
                      ims,ime, jms,jme, kms,kme,                  &
                      its,ite, jts,jte, kts,kte                   )

!----------------------------------------------------------------------
!  washout soluble species
!----------------------------------------------------------------------
     ktem1 = kte - 1
     area = dx * dy
     diff(:,:,:) = 0.
     cld_col_cnt = 0
     precip_col_cnt = 0
! 20131125 acd_ck_washout start
!     hno3_col_mdel(:,:) = 0.
     delta_mass_col(:,:,:) = 0.
! 20131125 acd_ck_washout end
     max_rls       = 0.
jloop : &
     do j = jts,jte
iloop : &
       do i = its,ite
           t(kts:kte)      = t_phy(i,kts:kte,j)
           tfac(kts:ktem1) = (t0 - t(kts:ktem1))/(t0*t(kts:ktem1))
           p(kts:kte)      = p_phy(i,kts:kte,j)*.01
           delp(kts:ktem1) = p8w(i,kts:ktem1,j) - p8w(i,kts+1:kte,j)
           layer_mass(kts:ktem1) = area*delp(kts:ktem1)/g
           totprec(kts:ktem1) = rainprod(i,kts:ktem1,j)*layer_mass(kts:ktem1)
           totevap(kts:ktem1) = evapprod(i,kts:ktem1,j)*layer_mass(kts:ktem1)
           rls(kte)      = 0.
           evaprate(kte) = 0.
           do k = ktem1,kts,-1
             rls(k) = max( 0.,totprec(k)-totevap(k)+rls(k+1) )
             evaprate(k) = min( 1.,totevap(k)/(rls(k+1)+1.e-20) )
           end do
column_has_precip : &
         if( any( rls(kts:ktem1) > 0. ) ) then
           if( maxval(rls(kts:ktem1)) >= max_rls ) then
             max_rls = max( max_rls,maxval(rls(kts:ktem1)) )
             max_ndx(3:3) = maxloc(rls(kts:ktem1))
             max_ndx(1:2) = (/ i,j /)
             if( max_ndx(3) /= kts ) then
               write(message,'(''wetscav: max rls not at srf; time,i,j,k = '',4i6)') ktau,max_ndx(:)
               call wrf_debug( 100,trim(message) )
             endif
           endif
           precip_col_cnt = precip_col_cnt + 1
species_loop : &
           do m = 1,hetcnt
             m1 = wrf2tab(m)
             pndx = wet_scav_tab(m1)%p_ndx
             if( pndx == p_hno3 ) then
               hno3(kts:kte)   = chem(i,kts:kte,j,p_hno3)
             endif
             wrk(kts:ktem1)        = 1.e-6*mol_wght(m)*chem(i,kts:ktem1,j,pndx)/mwdry
             trc_mass(kts:ktem1,m) = wrk(kts:ktem1)*layer_mass(kts:ktem1)
             wrk_mass(m)    = sum( trc_mass(kts:ktem1,m) )
             e298 = wet_scav_tab(m1)%heff(1)
             dhr  = wet_scav_tab(m1)%heff(2)
             heff(kts:ktem1,m) = e298 * exp( dhr*tfac(kts:ktem1) )
             if( wet_scav_tab(m1)%heff(3) /= 0. .and. &
                 wet_scav_tab(m1)%heff(5) == 0. ) then
               e298 = wet_scav_tab(m1)%heff(3)
               dhr  = wet_scav_tab(m1)%heff(4)
               dk1s(kts:ktem1) = e298*exp( dhr*tfac(kts:ktem1) )
               where( heff(kts:ktem1,m) /= 0. )
                 heff(kts:ktem1,m) = heff(kts:ktem1,m)*(1. + dk1s(kts:ktem1)*ph_inv)
               elsewhere
                 heff(kts:ktem1,m) = dk1s(kts:ktem1)*ph_inv
               endwhere
             endif
!----------------------------------------------------------------------
!  special handling for nh3 and co2
!----------------------------------------------------------------------
             if( pndx == p_nh3 .or. pndx == p_co2 ) then
               if( wet_scav_tab(m1)%heff(5) /= 0. ) then
                 e298 = wet_scav_tab(m1)%heff(3)
                 dhr  = wet_scav_tab(m1)%heff(4)
                 dk1s(kts:ktem1) = e298*exp( dhr*tfac(kts:ktem1) )
                 e298 = wet_scav_tab(m1)%heff(5)
                 dhr  = wet_scav_tab(m1)%heff(6)
                 dk2s(kts:ktem1) = e298*exp( dhr*tfac(kts:ktem1) )
                 if( pndx == p_co2 ) then
                   heff(kts:ktem1,m) = heff(kts:ktem1,m)*(1. + dk1s(:)*ph_inv)*(1. + dk2s(:)*ph_inv)
                 elseif( pndx == p_nh3 ) then
                   heff(kts:ktem1,m) = heff(kts:ktem1,m)*(1. + dk1s(:)*ph/dk2s(:))
                 endif
               endif
             endif
             tckaqb(m) = any( heff(kts:ktem1,m) > henry_thres )
!++mmb
             reteff(m) = wet_scav_tab(m1)%reteff
!--mmb
           end do species_loop

!----------------------------------------------------------------------
!  jneu washout
!----------------------------------------------------------------------
           CALL washout( kte-kts+1, hetcnt, dtstep, trc_mass, layer_mass, &
                         p, dz8w(i,kts:kte,j), rls, qc_b4mp(i,kts:kte,j), qi_b4mp(i,kts:kte,j), &
                         cldfra(i,kts:kte,j), t, evaprate, area, heff, &
!++mmb
!                        mol_wght, tckaqb, ice_uptake, i, j )
                         mol_wght, tckaqb, ice_uptake, i, j, reteff )
!--mmb

species_loop1 : &
           do m = 1,hetcnt
             m1 = wrf2tab(m)
             pndx = wet_scav_tab(m1)%p_ndx
             is_hno3 = pndx == p_hno3
! 20131125 acd_ck_washout start
!             if( is_hno3 ) then
!              hno3_col_mdel(i,j) = sum( trc_mass(kts:ktem1,m) ) - wrk_mass(m)
!            endif
             delta_mass_col(i,j,pndx) = sum( trc_mass(kts:ktem1,m) ) - wrk_mass(m)
! 20131125 acd_ck_washout end

             wrk(kts:ktem1) = 1.e6*mwdry*trc_mass(kts:ktem1,m)/mol_wght(m)
             chem(i,kts:ktem1,j,pndx) = wrk(kts:ktem1)/layer_mass(kts:ktem1)
             if( is_hno3 ) then
               diff(i,kts:ktem1,j) = 100.*(chem(i,kts:ktem1,j,p_hno3) - hno3(kts:ktem1))/hno3(kts:ktem1)
             endif
           end do species_loop1
         endif column_has_precip
       end do iloop
     end do jloop

     write(message,'(''washout: max rls @ (i,j,k) '',3i4,'' = '',1pg15.7)') max_ndx(:),max_rls
     call wrf_debug( 100,trim(message) )

     percent_precip = 100.*real(precip_col_cnt)/real((ite-its+1)*(jte-jts+1)) 
     write(*,*) 'wetscav_mozcart: percent columns with precip = ',percent_precip,'%'
   endif has_wet_scav

   end subroutine wetscav_mozcart

   SUBROUTINE cal_cldfra( CLDFRA,QC,QI,                               &
                          ids,ide, jds,jde, kds,kde,                  &
                          ims,ime, jms,jme, kms,kme,                  &
                          its,ite, jts,jte, kts,kte                   )
!---------------------------------------------------------------------
! !DESCRIPTION:
! Compute cloud fraction from input ice and cloud water fields
! if provided.
!
! Whether QI or QC is active or not is determined from the indices of
! the fields into the 4D scalar arrays in WRF. These indices are
! P_QI and P_QC, respectively, and they are passed in to the routine
! to enable testing to see if QI and QC represent active fields in
! the moisture 4D scalar array carried by WRF.
!
! If a field is active its index will have a value greater than or
! equal to PARAM_FIRST_SCALAR, which is also an input argument to
! this routine.
!EOP
!---------------------------------------------------------------------

   IMPLICIT NONE

   INTEGER,  INTENT(IN   )   ::           ids,ide, jds,jde, kds,kde, &
                                          ims,ime, jms,jme, kms,kme, &
                                          its,ite, jts,jte, kts,kte

   REAL, DIMENSION( ims:ime, kms:kme, jms:jme ), INTENT(OUT  ) ::    &
                                                             CLDFRA

   REAL, DIMENSION( ims:ime, kms:kme, jms:jme ), INTENT(IN   ) ::    &
                                                                 QI, &
                                                                 QC
!----------------------------------------------------------------------
!  local variables
!----------------------------------------------------------------------
!  REAL, parameter :: thresh = 1.e-6
   REAL, parameter :: thresh = 1.e-9

   INTEGER :: j,k

   DO j = jts,jte
     DO k = kts,kte-1
       where( (qc(its:ite,k,j) + qi(its:ite,k,j)) > thresh )
         cldfra(its:ite,k,j) = one
       elsewhere
         cldfra(its:ite,k,j) = zero
       endwhere
     ENDDO
   ENDDO

   END SUBROUTINE cal_cldfra

   SUBROUTINE cal_cldfra3( CLDFRA,QC,QI, QS,                          &
                          ids,ide, jds,jde, kds,kde,                  &
                          ims,ime, jms,jme, kms,kme,                  &
                          its,ite, jts,jte, kts,kte                   )
!---------------------------------------------------------------------
! !DESCRIPTION:
! Compute cloud fraction from input ice and cloud water fields
! if provided.
!
! Whether QI or QC is active or not is determined from the indices of
! the fields into the 4D scalar arrays in WRF. These indices are
! P_QI and P_QC, respectively, and they are passed in to the routine
! to enable testing to see if QI and QC represent active fields in
! the moisture 4D scalar array carried by WRF.
!
! If a field is active its index will have a value greater than or
! equal to PARAM_FIRST_SCALAR, which is also an input argument to
! this routine.
!EOP
!---------------------------------------------------------------------

   IMPLICIT NONE

   INTEGER,  INTENT(IN   )   ::           ids,ide, jds,jde, kds,kde, &
                                          ims,ime, jms,jme, kms,kme, &
                                          its,ite, jts,jte, kts,kte

   REAL, DIMENSION( ims:ime, kms:kme, jms:jme ), INTENT(OUT  ) ::    &
                                                             CLDFRA

   REAL, DIMENSION( ims:ime, kms:kme, jms:jme ), INTENT(IN   ) ::    &
                                                                 QI, &
                                                                 QC, &
                                                                 QS
!----------------------------------------------------------------------
!  local variables
!----------------------------------------------------------------------
   REAL, parameter :: thresh = 1.e-9

   INTEGER :: j

   DO j = jts,jte
     where( (qc(its:ite,kts:kte,j) + qi(its:ite,kts:kte,j) + qs(its:ite,kts:kte,j)) > thresh )
       cldfra(its:ite,kts:kte,j) = one
     elsewhere
       cldfra(its:ite,kts:kte,j) = zero
     endwhere
   ENDDO

   END SUBROUTINE cal_cldfra3

   SUBROUTINE cal_cldfra2( CLDFRA, QV, QC, QI, QS,                     &
                           t_phy, p_phy,                               &
                           ids,ide, jds,jde, kds,kde,                  &
                           ims,ime, jms,jme, kms,kme,                  &
                           its,ite, jts,jte, kts,kte                   )

!----------------------------------------------------------------------
!  dummy arguments
!----------------------------------------------------------------------
   INTEGER,  INTENT(IN   )   ::           ids,ide, jds,jde, kds,kde, &
                                          ims,ime, jms,jme, kms,kme, &
                                          its,ite, jts,jte, kts,kte

   REAL, DIMENSION( ims:ime, kms:kme, jms:jme ), INTENT(OUT  ) ::    &
                                                             CLDFRA

   REAL, DIMENSION( ims:ime, kms:kme, jms:jme ), INTENT(IN   ) ::    &
                                                                 QV, &
                                                                 QI, &
                                                                 QC, &
                                                                 QS, &
                                                              t_phy, &
                                                              p_phy


!----------------------------------------------------------------------
!  local variables
!----------------------------------------------------------------------
   integer, parameter  :: idbg = 144, kdbg = 15, jdbg = 147
   REAL    , PARAMETER :: ALPHA0 = 100.
   REAL    , PARAMETER :: GAMMA = 0.49
   REAL    , PARAMETER :: QCLDMIN = 1.E-12
   REAL    , PARAMETER :: PEXP = 0.25
   REAL    , PARAMETER :: RHGRID =1.0
   REAL    , PARAMETER :: SVP1 = 0.61078
   REAL    , PARAMETER :: SVP2 = 17.2693882
   REAL    , PARAMETER :: SVPI2 = 21.8745584
   REAL    , PARAMETER :: SVP3 = 35.86
   REAL    , PARAMETER :: SVPI3 = 7.66
   REAL    , PARAMETER :: SVPT0 = 273.15
   REAL    , PARAMETER :: r_d = 287.
   REAL    , PARAMETER :: r_v = 461.6
   REAL    , PARAMETER :: ep_2 = r_d/r_v

   INTEGER :: i,j,k
   INTEGER :: imax, jmax, kmax
   REAL    :: RHUM, tc, esw, esi, weight, qvsw, qvsi, qvs_weight
   REAL    :: QCLD, DENOM, ARG, SUBSAT, wrk
   REAL    :: relhum_max, wrk_max


! !DESCRIPTION:
!----------------------------------------------------------------------
! Compute cloud fraction from input ice and cloud water fields
! if provided.
!
! Whether QI or QC is active or not is determined from the indices of
! the fields into the 4D scalar arrays in WRF. These indices are 
! P_QI and P_QC, respectively, and they are passed in to the routine
! to enable testing to see if QI and QC represent active fields in
! the moisture 4D scalar array carried by WRF.
! 
! If a field is active its index will have a value greater than or
! equal to PARAM_FIRST_SCALAR, which is also an input argument to 
! this routine.
!----------------------------------------------------------------------
!EOP


!-----------------------------------------------------------------------
!     COMPUTE GRID-SCALE CLOUD COVER FOR RADIATION
!     (modified by Ferrier, Feb '02)
!
!     Cloud fraction parameterization follows Randall, 1994
!     (see Hong et al., 1998)
!-----------------------------------------------------------------------
! Note: ep_2=287./461.6 Rd/Rv
! Note: R_D=287.

! Alternative calculation for critical RH for grid saturation
!     RHGRID=0.90+.08*((100.-DX)/95.)**.5

! Calculate saturation mixing ratio weighted according to the fractions of
! water and ice.
! Following:
! Murray, F.W. 1966. ``On the computation of Saturation Vapor Pressure''  J. Appl. Meteor.  6 p.204
!    es (in mb) = 6.1078 . exp[ a . (T-273.16)/ (T-b) ]
!
!       over ice        over water
! a =   21.8745584      17.2693882
! b =   7.66            35.86
!---------------------------------------------------------------------

    CLDFRA(its:ite,kts:kte,jts:jte) = 0.
    relhum_max = -100.
    wrk_max    = -10000.
    imax = 0; kmax = 0; jmax = 0

    DO j = jts,jte
      DO k = kts,kte
        DO i = its,ite
!---------------------------------------------------------------------
!    Determine cloud fraction (modified from original algorithm)
!---------------------------------------------------------------------
          QCLD = QI(i,k,j) + QC(i,k,j) + QS(i,k,j)
has_cloud : &
          IF( QCLD >= QCLDMIN ) THEN
            tc   = t_phy(i,k,j) - SVPT0
            esw  = 1000.0 * SVP1 * EXP( SVP2  * tc / ( t_phy(i,k,j) - SVP3  ) )
            esi  = 1000.0 * SVP1 * EXP( SVPI2 * tc / ( t_phy(i,k,j) - SVPI3 ) )
            QVSW = EP_2 * esw / ( p_phy(i,k,j) - esw )
            QVSI = EP_2 * esi / ( p_phy(i,k,j) - esi )

            weight     = (QI(i,k,j) + QS(i,k,j)) / QCLD
            QVS_WEIGHT = (1. - weight)*QVSW + weight*QVSI
            RHUM       = QV(i,k,j)/QVS_WEIGHT              !--- Relative humidity
!---------------------------------------------------------------------
!    Assume zero cloud fraction if there is no cloud mixing ratio
!---------------------------------------------------------------------
            IF( RHUM >= RHGRID )THEN
!---------------------------------------------------------------------
!    Assume cloud fraction of unity if near saturation and the cloud
!    mixing ratio is at or above the minimum threshold
!---------------------------------------------------------------------
              CLDFRA(i,k,j) = 1.
            ELSE
!---------------------------------------------------------------------
!    Adaptation of original algorithm (Randall, 1994; Zhao, 1995)
!    modified based on assumed grid-scale saturation at RH=RHgrid.
!---------------------------------------------------------------------
              SUBSAT = MAX( 1.E-10,RHGRID*QVS_WEIGHT - QV(i,k,j) )
              DENOM  = SUBSAT**GAMMA
              ARG    = MAX( -6.9,-ALPHA0*QCLD/DENOM )    ! <-- EXP(-6.9)=.001
!---------------------------------------------------------------------
!   prevent negative values  (new)
!---------------------------------------------------------------------
              RHUM = MAX( 1.E-10, RHUM )
              wrk  = (RHUM/RHGRID)**PEXP*(1. - EXP( ARG ))
              if( rhum >= relhum_max ) then
                relhum_max = rhum
                imax = i
                kmax = k
                jmax = j
              endif
              IF( wrk >= .01 ) then
                CLDFRA(i,k,j) = wrk
                if( wrk >= wrk_max ) then
                  wrk_max = wrk
                endif
              ENDIF
            ENDIF
          ENDIF has_cloud
        END DO
      END DO
    END DO

   END SUBROUTINE cal_cldfra2

   subroutine WASHOUT( LPAR, NTRACE, DTSCAV, QTTJFL, QM, &
                       POFL, DELZ, RLS, CLWC, CIWC, &
                       CFR, TEM, EVAPRATE, GAREA, HSTAR, &
!++mmb
!                      TCMASS, TCKAQB, TCNION, ii, jj )
                       TCMASS, TCKAQB, TCNION, ii, jj, RETEFF )
!--mmb
!-----------------------------------------------------------------------
!---p-conde 5.4 (2007)   -----called from main-----
!---called from pmain to calculate rainout and washout of tracers
!---revised by JNEU 8/2007
!---
!-LAER has been removed - no scavenging for aerosols
!-LAER could be used as LWASHTYP
!---WILL THIS WORK FOR T42->T21???????????
!-----------------------------------------------------------------------
      
!-----------------------------------------------------------------------
!  dummy arguments
!-----------------------------------------------------------------------
      integer, intent(in)  :: LPAR
      integer, intent(in)  :: NTRACE
      integer, intent(in)  :: ii, jj
      real,  intent(in)    :: DTSCAV
      real,  intent(in)    :: GAREA
      real,  intent(in)    :: QM(LPAR)
      real,  intent(in)    :: POFL(LPAR)
      real,  intent(in)    :: DELZ(LPAR)
      real,  intent(in)    :: RLS(LPAR)
      real,  intent(in)    :: CLWC(LPAR)
      real,  intent(in)    :: CIWC(LPAR)
      real,  intent(in)    :: CFR(LPAR)
      real,  intent(in)    :: TEM(LPAR)
      real,  intent(in)    :: EVAPRATE(LPAR)
      real,  intent(in)    :: TCMASS(NTRACE)
      real,  intent(in)    :: HSTAR(LPAR,NTRACE)
      real,  intent(inout) :: QTTJFL(LPAR,NTRACE)
      logical, intent(in)  :: TCKAQB(NTRACE)
      logical, intent(in)  :: TCNION(NTRACE)
!++mmb
      real,  intent(in)    :: RETEFF(NTRACE)
!--mmb

!-----------------------------------------------------------------------
!  local variables
!-----------------------------------------------------------------------
      integer  :: I, J, L, LE, LM1, N
      integer  :: LWASHTYP, LICETYP

      real :: WRK, RNEW_TST
      real :: CLWX
      real :: RNEW, RPRECIP, DELTARIMEMASS, DELTARIME, RAMPCT
      real :: MASSLOSS
      real :: DOR, DNEW, DEMP, COLEFFSNOW, RHOSNOW
      real :: WEMP, REMP, RRAIN, RWASH
      real :: QTPRECIP, QTRAIN, QTCXA, QTAX

      real :: FAMA, RAMA, DAMA, FCA, RCA, DCA
      real :: FAX, RAX, DAX, FCXA, RCXA, DCXA, FCXB, RCXB, DCXB
      real :: RAXADJ, FAXADJ, RAXADJF
      real :: QTDISCF, QTDISRIME, QTDISCXA
      real :: QTEVAPAXP, QTEVAPAXW, QTEVAPAX
      real :: QTWASHAX
      real :: QTEVAPCXAP, QTEVAPCXAW, QTEVAPCXA
      real :: QTWASHCXA, QTRIMECXA
      real :: QTRAINCXA, QTRAINCXB
      real :: QTTOPCA, QTTOPAA, QTTOPCAX, QTTOPAAX

      real :: AMPCT, AMCLPCT, CLNEWPCT, CLNEWAMPCT, CLOLDPCT, CLOLDAMPCT
      real :: RAXLOC, RCXALOC, RCXBLOC, RCALOC, RAMALOC, RCXPCT

      real :: QTNETLCXA, QTNETLCXB, QTNETLAX, QTNETL
      real :: QTDISSTAR

      real :: CFXX(lpar)
      real :: QTT(lpar)
      real :: QTTNEW(lpar)
      real :: rls_wrk(lpar)
      real :: rnew_wrk(lpar)
      real :: rca_wrk(lpar)
      real :: fca_wrk(lpar)
      real :: rcxa_wrk(lpar)
      real :: fcxa_wrk(lpar)
      real :: rcxb_wrk(lpar)
      real :: fcxb_wrk(lpar)
      real :: rax_wrk(lpar,2)
      real :: fax_wrk(lpar,2)
      real :: rama_wrk(lpar)
      real :: fama_wrk(lpar)
      real :: deltarime_wrk(lpar)
      real :: clwx_wrk(lpar)
      real :: frc(lpar,3)
      real :: rlsog(lpar)

      logical :: is_hno3
      logical :: rls_flag(lpar)
      logical :: rnew_flag(lpar)
      logical :: cf_trigger(lpar)
      logical :: freezing(lpar)

      character(len=132) :: message
      

      real, parameter  :: TFROZ      = 240.
      real, parameter  :: CFMIN      = 1.0
      real, parameter  :: CWMIN      = 1.0e-9
      real, parameter  :: DMIN       = 1.0e-1    !mm
      real, parameter  :: VOLPOW     = 1./3.
      real, parameter  :: RHORAIN    = 1.0e3     !kg/m3
      real, parameter  :: RHOSNOWFIX = 1.0e2     !kg/m3
      real, parameter  :: COLEFFRAIN = 0.7
      real, parameter  :: COLEFFAER  = 0.05

!-----------------------------------------------------------------------
!  Note: LE must be less than LPAR
!-----------------------------------------------------------------------
      LE = LPAR - 1   
      rls_flag(1:le) = rls(1:le) > zero
      freezing(1:le) = tem(1:le) < tice
      rlsog(1:le) = rls(1:le)/garea

species_loop : &
     do N = 1,NTRACE
       QTT(:lpar)    = QTTJFL(:lpar,N)
       QTTNEW(:lpar) = QTTJFL(:lpar,N)
       is_hno3 = n == hno3_ndx
       if( is_hno3 ) then
         rca_wrk(:lpar) = zero
         fca_wrk(:lpar) = zero
         rcxa_wrk(:lpar) = zero
         fcxa_wrk(:lpar) = zero
         rcxb_wrk(:lpar) = zero
         fcxb_wrk(:lpar) = zero
         rls_wrk(:lpar) = zero
         rnew_wrk(:lpar) = zero
         cf_trigger(:lpar) = .false.
         clwx_wrk(:lpar) = -9999.
         deltarime_wrk(:lpar) = -9999.
         rax_wrk(:lpar,:) = zero
         fax_wrk(:lpar,:) = zero
       endif
!-----------------------------------------------------------------------
!  calculate scavenging by large-scale stratiform precipitation
!  check whether mass-limited or henry's law
!-----------------------------------------------------------------------
       if( TCKAQB(N) ) then
         LWASHTYP = 1
       else
         LWASHTYP = 2
       end if
!-----------------------------------------------------------------------
!  check whether soluble in ice
!-----------------------------------------------------------------------
       if( TCNION(N) ) then
         LICETYP = 1
       else
         LICETYP = 2
       end if

!-----------------------------------------------------------------------
!  initialization
!-----------------------------------------------------------------------
       QTTOPAA = zero
       QTTOPCA = zero

       RCA  = zero
       FCA  = zero
       DCA  = zero
       RAMA = zero
       FAMA = zero
       DAMA = zero

       AMPCT      = zero
       AMCLPCT    = zero
       CLNEWPCT   = zero
       CLNEWAMPCT = zero
       CLOLDPCT   = zero
       CLOLDAMPCT = zero
!-----------------------------------------------------------------------
!  Check whether precip in top layer - if so, require CF ge 0.2
!-----------------------------------------------------------------------
       if( RLS(LE) > zero ) then
         CFXX(LE) = max( CFMIN,CFR(LE) )
       else
         CFXX(LE) = CFR(LE)
       endif

       rnew_flag(1:le) = .false.

level_loop : &
       do L = LE,1,-1
         LM1  = L - 1
         FAX  = zero
         RAX  = zero
         DAX  = zero
         FCXA = zero
         FCXB = zero
         DCXA = zero
         DCXB = zero
         RCXA = zero
         RCXB = zero

         QTDISCF   = zero
         QTDISRIME = zero
         QTDISCXA  = zero

         QTEVAPAXP = zero
         QTEVAPAXW = zero
         QTEVAPAX  = zero
         QTWASHAX  = zero

         QTEVAPCXAP = zero
         QTEVAPCXAW = zero
         QTEVAPCXA  = zero
         QTRIMECXA  = zero
         QTWASHCXA  = zero
         QTRAINCXA  = zero
         QTRAINCXB  = zero
         
         RAMPCT = zero
         RCXPCT = zero

         RCXALOC = zero
         RCXBLOC = zero
         RAXLOC  = zero
         RAMALOC = zero
         RCALOC  = zero

         RPRECIP       = zero
         DELTARIMEMASS = zero
         DELTARIME     = zero
         DOR           = zero
         DNEW          = zero

         QTTOPAAX = zero
         QTTOPCAX = zero

has_rls : &
         if( rls_flag(l) ) then
!-----------------------------------------------------------------------
!-----Evaporate ambient precip and decrease area-------------------------
!-----If ice, diam=diam falling from above  If rain, diam=4mm (not used)
!-----Evaporate tracer contained in evaporated precip
!-----Can't evaporate more than we start with-----------------------------
!-----Don't do washout until we adjust ambient precip to match Rbot if needed
!------(after RNEW if statements)
!-----------------------------------------------------------------------
           FAX = max( zero,FAMA*(one - evaprate(l)) )
           RAX = RAMA								     !kg/m2/s
           if( FAMA > zero ) then
             if( freezing(l) ) then
               DAX = DAMA      !mm
             else
               DAX = four    !mm - not necessary
             endif
           else
             DAX = zero
           endif

           if( RAMA > zero ) then
             QTEVAPAXP = min( QTTOPAA,EVAPRATE(L)*QTTOPAA )
           else
             QTEVAPAXP = zero
           endif
           if( is_hno3 ) then
             rax_wrk(l,1) = rax
             fax_wrk(l,1) = fax
           endif


!-----------------------------------------------------------------------
!  Determine how much the in-cloud precip rate has increased------
!-----------------------------------------------------------------------
           WRK = RAX*FAX + RCA*FCA
           if( WRK > 0. ) then
             RNEW_TST = RLS(L)/(GAREA * WRK)
           else
             RNEW_TST = 10.
           endif
           RNEW = RLSOG(L) - (RAX*FAX + RCA*FCA)     !GBA*CF
           rnew_wrk(l) = rnew_tst
!-----------------------------------------------------------------------
!  if RNEW>0, there is growth and/or new precip formation
!-----------------------------------------------------------------------
has_rnew:  if( rlsog(l) > adj_factor*(rax*fax + rca*fca) ) then
!-----------------------------------------------------------------------
!  Min cloudwater requirement for cloud with new precip
!  Min CF is set at top for LE, at end for other levels
!  CWMIN is only needed for new precip formation - do not need for RNEW<0
!-----------------------------------------------------------------------
             if( cfxx(l) == zero ) then
               write(*,*) 'offline inputs'
               write(*,*) qttjfl(:,n)
               write(*,*) qm(:)
               write(*,*) pofl(:)
               write(*,*) delz(:)
               write(*,*) rls(:)
               write(*,*) clwc(:)
               write(*,*) ciwc(:)
               write(*,*) cfr(:)
               write(*,*) tem(:)
               write(*,*) evaprate(:)
               write(*,*) hstar(:,n)
               write(message,'('' washout: cloud fraction == 0 @ i,j,l,n = '',4i4)') ii,jj,l,n
               call wrf_debug( 15, trim(message) )
               QTTJFL(:lpar,N) = QTT(:lpar)
               cycle species_loop
             endif
             rnew_flag(l) = .true.
             CLWX = max( CLWC(L)+CIWC(L),CWMIN*CFXX(L) )
             if( is_hno3 ) then
               clwx_wrk(l) = clwx
             endif
!-----------------------------------------------------------------------
!  Area of old cloud and new cloud
!-----------------------------------------------------------------------
             FCXA = FCA
             FCXB = max( zero,CFXX(L)-FCXA )
!-----------------------------------------------------------------------
!                           ICE
!  For ice and mixed phase, grow precip in old cloud by riming
!  Use only portion of cloudwater in old cloud fraction
!  and rain above old cloud fraction
!  COLEFF from Lohmann and Roeckner (1996), Loss rate from Rotstayn (1997)
!-----------------------------------------------------------------------
is_freezing : &
             if( freezing(l) ) then
               COLEFFSNOW = exp( 2.5e-2*(TEM(L) - TICE) )
               if( TEM(L) <= TFROZ ) then
                 RHOSNOW = RHOSNOWFIX
               else
                 RHOSNOW = 0.303*(TEM(L) - TFROZ)*RHOSNOWFIX
               endif
               if( FCXA > zero ) then
                 if( DCA > zero ) then
                   DELTARIMEMASS = CLWX*QM(L)*(FCXA/CFXX(L))* &
                     (one - exp( (-COLEFFSNOW/(DCA*1.e-3))*((RCA)/(2.*RHOSNOW))*DTSCAV ))   !uses GBA R
                 else
                   DELTARIMEMASS = zero
                 endif
               else
                 DELTARIMEMASS = zero
               endif
!-----------------------------------------------------------------------
!  Increase in precip rate due to riming (kg/m2/s):
!  Limit to total increase in R in cloud
!-----------------------------------------------------------------------
               if( FCXA > zero ) then
                 DELTARIME = min( RNEW/FCXA,DELTARIMEMASS/(FCXA*GAREA*DTSCAV) ) !GBA
               else
                 DELTARIME = zero
               endif
               if( is_hno3 ) then
                 deltarime_wrk(l) = deltarime
               endif
!-----------------------------------------------------------------------
!  Find diameter of rimed precip, must be at least .1mm
!-----------------------------------------------------------------------
               if( RCA > zero ) then
                 DOR = max( DMIN,(((RCA+DELTARIME)/RCA)**VOLPOW)*DCA )
               else
                 DOR = zero
               endif
!-----------------------------------------------------------------------
!  If there is some in-cloud precip left, we have new precip formation
!  Will be spread over whole cloud fraction 
!-----------------------------------------------------------------------
!  Calculate precip rate in old and new cloud fractions
!-----------------------------------------------------------------------
               RPRECIP = (RNEW-(DELTARIME*FCXA))/CFXX(L) !kg/m2/s    !GBA
!-----------------------------------------------------------------------
!  Calculate precip rate in old and new cloud fractions
!-----------------------------------------------------------------------
               RCXA = RCA + DELTARIME + RPRECIP          !kg/m2/s GBA
               RCXB = RPRECIP                            !kg/m2/s GBA

!-----------------------------------------------------------------------
!  Find diameter of new precip from empirical relation using Rprecip
!  in given area of box- use density of water, not snow, to convert kg/s
!  to mm/s -> as given in Field and Heymsfield
!  Also calculate diameter of mixed precip,DCXA, from empirical relation
!  using total R in FCXA - this will give larger particles than averaging DOR and
!  DNEW in the next level
!  DNEW and DCXA must be at least .1mm
!-----------------------------------------------------------------------
               if( RPRECIP > zero ) then
                 WEMP = (CLWX*QM(L))/(GAREA*CFXX(L)*DELZ(L)) !kg/m3
                 REMP = RPRECIP/((RHORAIN/1.e3))             !mm/s local
                 DNEW = DEMPIRICAL( WEMP, REMP )
                 DNEW = max( DMIN,DNEW )
                 if( FCXB > zero ) then
                   DCXB = DNEW
                 else
                   DCXB = zero
                 endif
               else
                 DCXB = zero
               endif

               if( FCXA > zero ) then
                 WEMP = (CLWX*QM(L)*(FCXA/CFXX(L)))/(GAREA*FCXA*DELZ(L)) !kg/m3
                 REMP = RCXA/((RHORAIN/1.e3))                         !mm/s local
                 DEMP = DEMPIRICAL( WEMP, REMP )
                 DCXA = ((RCA+DELTARIME)/RCXA)*DOR + (RPRECIP/RCXA)*DNEW
                 DCXA = max( DEMP,DCXA )
                 DCXA = max( DMIN,DCXA )
               else
                 DCXA = zero
               endif

               if( QTT(L) > zero ) then   
!-----------------------------------------------------------------------
!                       ICE SCAVENGING
!-----------------------------------------------------------------------
!  For ice, rainout only hno3/aerosols using new precip
!  Tracer dissolved given by Kaercher and Voigt (2006) for T<258K
!  For T>258K, use Henry's Law with Retention coefficient
!  Rain out in whole CF
!-----------------------------------------------------------------------
                 if( RPRECIP > zero ) then
                   if( LICETYP == 1 ) then
                     RRAIN = RPRECIP*GAREA                                  !kg/s local
                     call DISGAS( CLWX, CFXX(L), TCMASS(N), HSTAR(L,N), &
                                  TEM(L),POFL(L),QM(L),                 &
!++mmb
!                                 QTT(L)*CFXX(L),QTDISCF )
                                  QTT(L)*CFXX(L),QTDISCF, is_hno3, RETEFF(N) )
!--mmb
                     call RAINGAS( RRAIN, DTSCAV, CLWX, CFXX(L),        &
                                   QM(L), QTT(L), QTDISCF, QTRAIN )
                     WRK       = QTRAIN/CFXX(L)
                     QTRAINCXA = FCXA*WRK
                     QTRAINCXB = FCXB*WRK
                   elseif( LICETYP == 2 ) then
                     QTRAINCXA = zero
                     QTRAINCXB = zero
                   endif
                 endif
!-----------------------------------------------------------------------
!  For ice, accretion removal for hno3 and aerosols is propotional to riming, 
!  no accretion removal for gases
!  remove only in mixed portion of cloud
!  Limit DELTARIMEMASS to RNEW*DTSCAV for ice - evaporation of rimed ice to match
!  RNEW precip rate would result in HNO3 escaping from ice (no trapping) 
!-----------------------------------------------------------------------
                 if( DELTARIME > zero ) then
                   if( LICETYP == 1 ) then
                     if( TEM(L) <= TFROZ ) then
                       RHOSNOW = RHOSNOWFIX
                     else
                       RHOSNOW = 0.303*(TEM(L) - TFROZ)*RHOSNOWFIX
                     endif
                     QTCXA = QTT(L)*FCXA
                     call DISGAS( CLWX*(FCXA/CFXX(L)), FCXA, TCMASS(N),   &
                                  HSTAR(L,N), TEM(L), POFL(L),            &
!++mmb
!                                 QM(L), QTCXA, QTDISRIME )       
                                  QM(L), QTCXA, QTDISRIME, is_hno3, RETEFF(N) )       
!--mmb
                     QTDISSTAR = (QTDISRIME*QTCXA)/(QTDISRIME + QTCXA)
                     QTRIMECXA = QTCXA*                             &
                        (one - exp((-COLEFFSNOW/(DCA*1.e-3))*       &
                        (RCA/(2.*RHOSNOW))*                         &  !uses GBA R    
                        (QTDISSTAR/QTCXA)*DTSCAV))
                     QTRIMECXA = min( QTRIMECXA, &               
                        ((RNEW*GAREA*DTSCAV)/(CLWX*QM(L)*(FCXA/CFXX(L))))*QTDISSTAR)
                   elseif( LICETYP == 2 ) then
                     QTRIMECXA = zero
                   endif
                 endif
               else
                 QTRAINCXA = zero
                 QTRAINCXB = zero
                 QTRIMECXA = zero
               endif
!-----------------------------------------------------------------------
!  For ice, no washout in interstitial cloud air
!-----------------------------------------------------------------------
               QTWASHCXA = zero
               QTEVAPCXA = zero

!-----------------------------------------------------------------------
!                      RAIN
!  For rain, accretion increases rain rate but diameter remains constant
!  Diameter is 4mm (not used)
!-----------------------------------------------------------------------
             else is_freezing
               if( FCXA > zero ) then
                 DELTARIMEMASS = (CLWX*QM(L))*(FCXA/CFXX(L))*           &
                   (one - exp( -0.24*COLEFFRAIN*((RCA)**0.75)*DTSCAV ))  !local
               else
                 DELTARIMEMASS = zero
               endif
!-----------------------------------------------------------------------
!  Increase in precip rate due to riming (kg/m2/s):
!  Limit to total increase in R in cloud
!-----------------------------------------------------------------------
               if( FCXA > zero ) then
                 DELTARIME = min( RNEW/FCXA,DELTARIMEMASS/(FCXA*GAREA*DTSCAV) ) !GBA
               else
                 DELTARIME = zero
               endif
!-----------------------------------------------------------------------
!  If there is some in-cloud precip left, we have new precip formation 
!-----------------------------------------------------------------------
               RPRECIP = (RNEW-(DELTARIME*FCXA))/CFXX(L)       !GBA

               RCXA = RCA + DELTARIME + RPRECIP            !kg/m2/s GBA
               RCXB = RPRECIP                              !kg/m2/s GBA
               DCXA = FOUR  
               if( FCXB > zero ) then
                 DCXB = FOUR
               else
                 DCXB = zero
               endif
!-----------------------------------------------------------------------
!                         RAIN SCAVENGING
!  For rain, rainout both hno3/aerosols and gases using new precip
!-----------------------------------------------------------------------
               if( QTT(L) > zero ) then
                 if( RPRECIP > zero ) then
                   RRAIN = (RPRECIP*GAREA) !kg/s local
                   call DISGAS( CLWX, CFXX(L), TCMASS(N), HSTAR(L,N), &
                                TEM(L), POFL(L), QM(L),               &
!++mmb
!                               QTT(L)*CFXX(L), QTDISCF )
                                QTT(L)*CFXX(L), QTDISCF, is_hno3, RETEFF(N) )
!--mmb
                   call RAINGAS( RRAIN, DTSCAV, CLWX, CFXX(L),        &
                                 QM(L), QTT(L), QTDISCF, QTRAIN )
                   WRK       = QTRAIN/CFXX(L)
                   QTRAINCXA = FCXA*WRK
                   QTRAINCXB = FCXB*WRK
                 endif
!-----------------------------------------------------------------------
!  For rain, accretion removal is propotional to riming
!  caclulate for hno3/aerosols and gases
!  Remove only in mixed portion of cloud
!  Limit DELTARIMEMASS to RNEW*DTSCAV
!-----------------------------------------------------------------------
                 if( DELTARIME > zero ) then
                   QTCXA = QTT(L)*FCXA
                   call DISGAS( CLWX*(FCXA/CFXX(L)), FCXA, TCMASS(N),    &
                                HSTAR(L,N), TEM(L), POFL(L),             &
!++mmb
!                               QM(L), QTCXA, QTDISRIME )
                                QM(L), QTCXA, QTDISRIME, is_hno3, RETEFF(N) )
!--mmb
                   QTDISSTAR = (QTDISRIME*QTCXA)/(QTDISRIME + QTCXA)
                   QTRIMECXA = QTCXA*                              &
                      (one - exp(-0.24*COLEFFRAIN*                 &
                      ((RCA)**0.75)*                               & !local 
                      (QTDISSTAR/QTCXA)*DTSCAV))               
                   QTRIMECXA = min( QTRIMECXA, &
                      ((RNEW*GAREA*DTSCAV)/(CLWX*QM(L)*(FCXA/CFXX(L))))*QTDISSTAR)
                 else
                   QTRIMECXA = zero
                 endif
               else
                 QTRAINCXA = zero
                 QTRAINCXB = zero
                 QTRIMECXA = zero
               endif
!-----------------------------------------------------------------------
!  For rain, washout gases and HNO3/aerosols using rain from above old cloud
!  Washout for HNO3/aerosols is only on non-dissolved portion, impaction-style
!  Washout for gases is on non-dissolved portion, limited by QTTOP+QTRIME
!-----------------------------------------------------------------------
               if( RCA > zero ) then
                 QTPRECIP = FCXA*QTT(L) - QTDISRIME
                 if( LWASHTYP == 1 ) then
                   if( QTPRECIP > zero ) then
                     QTWASHCXA = QTPRECIP*(one - exp( -0.24*COLEFFAER*((RCA)**0.75)*DTSCAV ))   !local
                   else
                     QTWASHCXA = zero
                   endif
                   QTEVAPCXA = zero
                 elseif( LWASHTYP == 2 ) then
                   RWASH = RCA*GAREA                                !kg/s local
                   if( QTPRECIP > zero ) then
                     call WASHGAS( RWASH, FCA, DTSCAV, QTTOPCA+QTRIMECXA, &
                                   HSTAR(L,N), TEM(L), POFL(L),           &
                                   QM(L), QTPRECIP, QTWASHCXA, QTEVAPCXA )
                   else
                     QTWASHCXA = zero
                     QTEVAPCXA = zero
                   endif
                 endif
               endif
             endif is_freezing
!-----------------------------------------------------------------------
!  If RNEW<O, confine precip to area of cloud above
!  FCXA does not require a minimum (could be zero if R(L).le.what
!  evaporated in ambient)
!-----------------------------------------------------------------------
           else has_rnew
             CLWX = CLWC(L) + CIWC(L)
             if( is_hno3 ) then
               clwx_wrk(l) = clwx
             endif
             FCXA = FCA
             FCXB = max( zero,CFXX(L)-FCXA )
             RCXB = zero
             DCXB = zero
             QTRAINCXA = zero
             QTRAINCXB = zero
             QTRIMECXA = zero

!-----------------------------------------------------------------------
!  Put rain into cloud up to RCA so that we evaporate
!  from ambient first
!  Adjust ambient to try to match RLS(L)
!  If no cloud, RAX=R(L)
!-----------------------------------------------------------------------
             if( FCXA > zero ) then
               RCXA = min( RCA,RLS(L)/(GAREA*FCXA) )     !kg/m2/s  GBA
               if( FAX > zero .and. ((RCXA+1.e-12) < RLS(L)/(GAREA*FCXA)) ) then
                 RAXADJF = RLS(L)/GAREA - RCXA*FCXA
                 RAMPCT = RAXADJF/(RAX*FAX)
                 FAXADJ = RAMPCT*FAX
                 if( FAXADJ > zero ) then
                   RAXADJ = RAXADJF/FAXADJ
                 else
                   RAXADJ = zero
                 endif
               else
                 RAXADJ = zero
                 RAMPCT = zero
                 FAXADJ = zero
               endif
             else
               RCXA = zero
               if( FAX > zero ) then
                 RAXADJF = RLS(L)/GAREA
                 RAMPCT = RAXADJF/(RAX*FAX)
                 FAXADJ = RAMPCT*FAX
                 if( FAXADJ > zero ) then
                   RAXADJ = RAXADJF/FAXADJ
                 else
                   RAXADJ = zero
                 endif              
               else
                 RAXADJ = zero
                 RAMPCT = zero
                 FAXADJ = zero
               endif
             endif
  
             QTEVAPAXP = min( QTTOPAA,QTTOPAA - (RAMPCT*(QTTOPAA-QTEVAPAXP)) )
             FAX = FAXADJ
             RAX = RAXADJ

!-----------------------------------------------------------------------
!                IN-CLOUD EVAPORATION/WASHOUT
!  If precip out the bottom of the cloud is 0, evaporate everything
!  If there is no cloud, QTTOPCA=0, so nothing happens
!-----------------------------------------------------------------------
             if( RCXA <= zero ) then
               QTEVAPCXA = QTTOPCA
               RCXA = zero
               DCXA = zero
             else
!-----------------------------------------------------------------------
!  If rain out the bottom of the cloud is >0 (but .le. RCA):
!  For ice, decrease particle size,
!  no washout
!  no evap for non-ice gases (b/c there is nothing in ice)
!  T<Tmix,release hno3& aerosols
!  release is amount dissolved in ice mass released
!  T>Tmix, hno3&aerosols are incorporated into ice structure:
!  do not release
!  For rain, assume full evaporation of some raindrops
!  proportional evaporation for all species 
!  washout for gases using Rbot 
!  impact washout for hno3/aerosol portion in gas phase              
!-----------------------------------------------------------------------
!              if (TEM(L) < TICE ) then
is_freezing_a : &
               if( freezing(l) ) then
                 QTWASHCXA = zero
                 DCXA = ((RCXA/RCA)**VOLPOW)*DCA
                 if( LICETYP == 1 ) then
                   if( TEM(L) <= TMIX ) then
                     MASSLOSS = (RCA-RCXA)*FCXA*GAREA*DTSCAV
!-----------------------------------------------------------------------
!  note-QTT doesn't matter b/c T<258K
!-----------------------------------------------------------------------
                     call DISGAS( (MASSLOSS/QM(L)), FCXA, TCMASS(N),   &
                                   HSTAR(L,N), TEM(L), POFL(L),        &
!++mmb
!                                  QM(L), QTT(L), QTEVAPCXA )
                                   QM(L), QTT(L), QTEVAPCXA, is_hno3, RETEFF(N) )
!--mmb
                     QTEVAPCXA = min( QTTOPCA,QTEVAPCXA )
                   else
                     QTEVAPCXA = zero
                   endif
                 elseif( LICETYP == 2 ) then   
                   QTEVAPCXA = zero
                 endif
               else is_freezing_a
                 QTEVAPCXAP = (RCA - RCXA)/RCA*QTTOPCA
                 DCXA = FOUR
                 QTCXA = FCXA*QTT(L)
                 if( LWASHTYP == 1 ) then
                   if( QTT(L) > zero ) then
                     call DISGAS( CLWX*(FCXA/CFXX(L)), FCXA, TCMASS(N),   &
                                  HSTAR(L,N), TEM(L), POFL(L),            &
!++mmb
!                                 QM(L), QTCXA, QTDISCXA )
                                  QM(L), QTCXA, QTDISCXA, is_hno3, RETEFF(N) )
!--mmb
                     if( QTCXA > QTDISCXA ) then
                       QTWASHCXA = (QTCXA - QTDISCXA)*(one - exp( -0.24*COLEFFAER*((RCXA)**0.75)*DTSCAV )) !local
                     else
                       QTWASHCXA = zero
                     endif
                     QTEVAPCXAW = zero
                   else
                     QTWASHCXA  = zero
                     QTEVAPCXAW = zero
                   endif
                 elseif (LWASHTYP == 2 ) then
                   RWASH = RCXA*GAREA                         !kg/s local
                   call WASHGAS( RWASH, FCXA, DTSCAV, QTTOPCA, HSTAR(L,N), &
                                 TEM(L), POFL(L), QM(L),                   &
                                 QTCXA-QTDISCXA, QTWASHCXA, QTEVAPCXAW )
                 endif
                 QTEVAPCXA = QTEVAPCXAP + QTEVAPCXAW
               endif is_freezing_a
             endif
           endif has_rnew

!-----------------------------------------------------------------------
!                 AMBIENT WASHOUT
!  Ambient precip is finalized - if it is rain, washout
!  no ambient washout for ice, since gases are in vapor phase
!-----------------------------------------------------------------------
           if( RAX > zero ) then
!            if( TEM(L) >= TICE ) then
             if( .not. freezing(l) ) then
               QTAX = FAX*QTT(L)
               if( LWASHTYP == 1 ) then
                 QTWASHAX = QTAX*                        &
                    (one - exp(-0.24*COLEFFAER*       &
                   ((RAX)**0.75)*DTSCAV))  !local
                 QTEVAPAXW = zero
               elseif( LWASHTYP == 2 ) then
                 RWASH = RAX*GAREA   !kg/s local
                 call WASHGAS( RWASH, FAX, DTSCAV, QTTOPAA, HSTAR(L,N), &
                               TEM(L), POFL(L), QM(L), QTAX,            &
                               QTWASHAX, QTEVAPAXW )
               endif
             else
               QTEVAPAXW = zero
               QTWASHAX  = zero
             endif
           else
             QTEVAPAXW = zero
             QTWASHAX  = zero
           endif
           QTEVAPAX = QTEVAPAXP + QTEVAPAXW

!-----------------------------------------------------------------------
!                  END SCAVENGING
!  Require CF if our ambient evaporation rate would give less 
!  precip than R from model.
!-----------------------------------------------------------------------
           if( is_hno3 ) then
             rls_wrk(l) = rls(l)/garea
             rca_wrk(l) = rca
             fca_wrk(l) = fca
             rcxa_wrk(l) = rcxa
             fcxa_wrk(l) = fcxa
             rcxb_wrk(l) = rcxb
             fcxb_wrk(l) = fcxb
             rax_wrk(l,2) = rax
             fax_wrk(l,2) = fax
           endif
upper_level : &
           if( L > 1 ) then
             FAMA = max( FCXA + FCXB + FAX - CFR(LM1),zero )
             if( FAX > zero ) then
               RAXLOC = RAX/FAX
             else
               RAXLOC = zero
             endif
             if( FCXA > zero ) then
               RCXALOC = RCXA/FCXA
             else
               RCXALOC = zero
             endif
             if( FCXB > zero ) then
               RCXBLOC = RCXB/FCXB
             else
               RCXBLOC = zero
             endif

             if( CFR(LM1) >= CFMIN ) then
               CFXX(LM1) = CFR(LM1)
             else
               if( adj_factor*RLSOG(LM1) >= (RCXA*FCXA + RCXB*FCXB + RAX*FAX)*(one - EVAPRATE(LM1)) ) then
                 CFXX(LM1) = CFMIN
                 cf_trigger(lm1) = .true.
               else
                 CFXX(LM1) = CFR(LM1)
               endif
             endif
!-----------------------------------------------------------------------
!  Figure out what will go into ambient and cloud below
!  Don't do for lowest level
!-----------------------------------------------------------------------
             if( FAX > zero ) then
               RAXLOC = RAX/FAX
               AMPCT = max( zero,min( one,(CFXX(L) + FAX - CFXX(LM1))/FAX ) )
               AMCLPCT = one - AMPCT
             else
               RAXLOC  = zero
               AMPCT   = zero
               AMCLPCT = zero
             endif
             if( FCXB > zero ) then
               RCXBLOC = RCXB/FCXB
               CLNEWPCT = max( zero,min( (CFXX(LM1) - FCXA)/FCXB,one ) )
               CLNEWAMPCT = one - CLNEWPCT
             else
               RCXBLOC    = zero
               CLNEWPCT   = zero
               CLNEWAMPCT = zero
             endif
             if( FCXA > zero ) then
               RCXALOC = RCXA/FCXA
               CLOLDPCT = max( zero,min( CFXX(LM1)/FCXA,one ) )
               CLOLDAMPCT = one - CLOLDPCT
             else
               RCXALOC    = zero
               CLOLDPCT   = zero
               CLOLDAMPCT = zero
             endif
!-----------------------------------------------------------------------
!  Remix everything for the next level
!-----------------------------------------------------------------------
             FCA = min( CFXX(LM1),FCXA*CLOLDPCT + CLNEWPCT*FCXB + AMCLPCT*FAX )
             if( FCA > zero ) then
!-----------------------------------------------------------------------
!  Maintain cloud core by reducing NC and AM area going into cloud below
!-----------------------------------------------------------------------
               RCA = (RCXA*FCXA*CLOLDPCT + RCXB*FCXB*CLNEWPCT + RAX*FAX*AMCLPCT)/FCA
               if( RCA > zero ) then
                 DCA = (RCXA*FCXA*CLOLDPCT)/(RCA*FCA)*DCXA + & 
                       (RCXB*FCXB*CLNEWPCT)/(RCA*FCA)*DCXB + &
                       (RAX*FAX*AMCLPCT)/(RCA*FCA)*DAX
               else
                 DCA = zero
               endif
             else
               FCA = zero
               DCA = zero
               RCA = zero
             endif

             FAMA = FCXA + FCXB + FAX - CFXX(LM1)
             if( FAMA > zero ) then
               RAMA = (RCXA*FCXA*CLOLDAMPCT + RCXB*FCXB*CLNEWAMPCT + RAX*FAX*AMPCT)/FAMA
	       if( RAMA > zero ) then
                 DAMA = (RCXA*FCXA*CLOLDAMPCT)/(RAMA*FAMA)*DCXA +  &
                        (RCXB*FCXB*CLNEWAMPCT)/(RAMA*FAMA)*DCXB +  &
                        (RAX*FAX*AMPCT)/(RAMA*FAMA)*DAX
	       else
		  FAMA = zero
                  DAMA = zero
	       endif
             else
               FAMA = zero
               DAMA = zero
               RAMA = zero
             endif
           else upper_level
             AMPCT      = zero
             AMCLPCT    = zero
             CLNEWPCT   = zero
             CLNEWAMPCT = zero
             CLOLDPCT   = zero
             CLOLDAMPCT = zero
           endif upper_level
         else has_rls
	   RNEW = zero
           QTEVAPCXA = QTTOPCA
           QTEVAPAX = QTTOPAA
           if( L > 1 ) then
             if( RLS(LM1) > zero ) then
               CFXX(LM1) = max( CFMIN,CFR(LM1) )
!              if( CFR(LM1) >= CFMIN ) then
!                CFXX(LM1) = CFR(LM1)
!              else
!                CFXX(LM1) = CFMIN
!              endif
             else
               CFXX(LM1) = CFR(LM1)
             endif
           endif
           AMPCT      = zero
           AMCLPCT    = zero
           CLNEWPCT   = zero
           CLNEWAMPCT = zero
           CLOLDPCT   = zero
           CLOLDAMPCT = zero
           RCA        = zero
           RAMA       = zero
           FCA        = zero
           FAMA       = zero
           DCA        = zero
           DAMA       = zero
         endif has_rls

         if( is_hno3 ) then
           fama_wrk(l) = fama
           rama_wrk(l) = rama
         endif
!-----------------------------------------------------------------------
!  Net loss can not exceed QTT in each region
!-----------------------------------------------------------------------
         QTNETLCXA = QTRAINCXA + QTRIMECXA + QTWASHCXA - QTEVAPCXA
         QTNETLCXA = min( QTT(L)*FCXA,QTNETLCXA )
   
         QTNETLCXB =QTRAINCXB
         QTNETLCXB = min( QTT(L)*FCXB,QTNETLCXB )

         QTNETLAX = QTWASHAX - QTEVAPAX
         QTNETLAX = min( QTT(L)*FAX,QTNETLAX )
              
         QTTNEW(L) = QTT(L) - (QTNETLCXA + QTNETLCXB + QTNETLAX)


         QTTOPCAX = (QTTOPCA + QTNETLCXA)*CLOLDPCT + QTNETLCXB*CLNEWPCT + (QTTOPAA + QTNETLAX)*AMCLPCT
         QTTOPAAX = (QTTOPCA + QTNETLCXA)*CLOLDAMPCT + QTNETLCXB*CLNEWAMPCT + (QTTOPAA + QTNETLAX)*AMPCT
         QTTOPCA = QTTOPCAX
         QTTOPAA = QTTOPAAX
       end do level_loop

!-----------------------------------------------------------------------
!  reload new tracer mass and rescale moments: check upper limits (LE) 
!-----------------------------------------------------------------------
       QTTJFL(:le,N) = QTTNEW(:le)
     end do species_loop

end subroutine WASHOUT

subroutine DISGAS( CLWX, CFX, MOLMASS, HSTAR, &
                   TM, PR, QM, &
!++mmb
!                  QT, QTDIS )
                   QT, QTDIS, is_hno3, RETEFF )
!--mmb

!-----------------------------------------------------------------------
!  dummy arguments
!-----------------------------------------------------------------------
      real, intent(in) :: CLWX,CFX    !cloud water,cloud fraction 
      real, intent(in) :: MOLMASS     !molecular mass of tracer
      real, intent(in) :: HSTAR       !Henry's Law coeffs A*exp(-B/T)
      real, intent(in) :: TM          !temperature of box (K)
      real, intent(in) :: PR          !pressure of box (hPa)
      real, intent(in) :: QM          !air mass in box (kg)
      real, intent(in) :: QT          !tracer in box (kg)
      real, intent(out) :: QTDIS      !tracer dissolved in aqueous phase 

!++mmb      
      logical, intent(in) :: is_hno3
      real, intent(in) :: RETEFF      !Ice retention parameter
!--mmb
 
!-----------------------------------------------------------------------
!  local variables
!-----------------------------------------------------------------------

!++mmb
!     real, parameter  :: RETEFF = 0.5
!     real, parameter  :: RETEFF = 1.0
!--mmb

      real  :: MUEMP

!-----------------------------------------------------------------------
!  calculate rate of uptake of tracer
!-----------------------------------------------------------------------

!-----------------------------------------------------------------------
!  effective Henry's Law constant: H* = moles-T / liter-precip / press(atm-T)
!  p(atm of tracer-T) = (QT/QM) * (.029/MolWt-T) * pressr(hPa)/1000
!  limit temperature effects to T above freezing
!  MU from fit to Kaercher and Voigt (2006)
!-----------------------------------------------------------------------
      if( TM >= TICE ) then
        QTDIS = (HSTAR*(QT/(QM*CFX))*0.029*(PR/1.0e3))*(CLWX*QM)
!++mmb
!     elseif( TM <= TMIX ) then
      elseif( TM <= TMIX .and. is_hno3 ) then
!--mmb
        MUEMP = exp( -14.2252 + TM*(1.55704e-1 - 7.1929e-4*TM) )
        QTDIS = MUEMP*(MOLMASS/18.)*(CLWX*QM)
      else
        QTDIS = RETEFF*((HSTAR*(QT/(QM*CFX))*0.029*(PR/1.0e3))*(CLWX*QM))
      endif

end subroutine DISGAS

subroutine RAINGAS( RRAIN, DTSCAV, CLWX, CFX, QM, QT, QTDIS, QTRAIN )
!-----------------------------------------------------------------------
!---New trace-gas rainout from large-scale precip with two time scales,
!---one based on precip formation from cloud water and one based on 
!---Henry's Law solubility: correct limit for delta-t
!---    
!---NB this code does not consider the aqueous dissociation (eg, C-q) 
!---   that makes uptake of HNO3 and H2SO4 so complete.  To do so would
!---   require that we keep track of the pH of the falling rain.
!---THUS the Henry's Law coefficient KHA needs to be enhanced to incldue this!
!---ALSO the possible formation of other soluble species from, eg, CH2O, H2O2
!---   can be considered with enhanced values of KHA.
!---
!---Does NOT now use RMC (moist conv rain) but could, assuming 30% coverage
!-----------------------------------------------------------------------

!-----------------------------------------------------------------------
!  dummy arguments
!-----------------------------------------------------------------------
      real, intent(in) :: RRAIN       !new rain formation in box (kg/s)
      real, intent(in) :: DTSCAV      !time step (s)
      real, intent(in) :: CLWX,CFX    !cloud water and cloud fraction
      real, intent(in) :: QM          !air mass in box (kg)
      real, intent(in) :: QT          !tracer in box (kg) 
      real, intent(in) :: QTDIS       !tracer in aqueous phase (kg) 
      real, intent(out) :: QTRAIN     !tracer picked up by new rain  

!-----------------------------------------------------------------------
!  local variables
!-----------------------------------------------------------------------
      real ::  QTLF, QTDISSTAR

      QTDISSTAR = (QTDIS*(QT*CFX))/(QTDIS+(QT*CFX))
 
!-----------------------------------------------------------------------
!  Tracer Loss frequency (1/s) within cloud fraction:
!-----------------------------------------------------------------------
      QTLF = (RRAIN*QTDISSTAR)/(CLWX*QM*QT*CFX)

!-----------------------------------------------------------------------
!  in time = DTSCAV, the amount of QTT scavenged is calculated 
!  from CF*AMOUNT OF UPTAKE 
!-----------------------------------------------------------------------
      QTRAIN = QT*CFX*(one - exp( -DTSCAV*QTLF ))

end subroutine RAINGAS

subroutine WASHGAS( RWASH, BOXF, DTSCAV, QTRTOP, HSTAR, TM, PR, QM, &
                    QT, QTWASH, QTEVAP )
!-----------------------------------------------------------------------
!---for most gases below-cloud washout assume Henry-Law equilib with precip
!---assumes that precip is liquid, if frozen, do not call this sub
!---since solubility is moderate, fraction of box with rain does not matter
!---NB this code does not consider the aqueous dissociation (eg, C-q) 
!---   that makes uptake of HNO3 and H2SO4 so complete.  To do so would
!---   require that we keep track of the pH of the falling rain.
!---THUS the Henry's Law coefficient KHA needs to be enhanced to incldue this!
!---ALSO the possible formation of other soluble species from, eg, CH2O, H2O2
!---   can be considered with enhanced values of KHA.
!-----------------------------------------------------------------------

!-----------------------------------------------------------------------
!  dummy arguments
!-----------------------------------------------------------------------
      real, intent(in)  :: RWASH   ! precip leaving bottom of box (kg/s)
      real, intent(in)  :: BOXF    ! fraction of box with washout
      real, intent(in)  :: DTSCAV  ! time step (s)
      real, intent(in)  :: QTRTOP  ! tracer-T in rain entering top of box over time step (kg)
      real, intent(in)  :: HSTAR   ! Henry's Law coeffs A*exp(-B/T)
      real, intent(in)  :: TM      ! temperature of box (K)
      real, intent(in)  :: PR      ! pressure of box (hPa)
      real, intent(in)  :: QT      ! tracer in box (kg)
      real, intent(in)  :: QM      ! air mass in box (kg)
      real, intent(out) :: QTWASH  ! tracer picked up by precip (kg)
      real, intent(out) :: QTEVAP  ! tracer evaporated from precip (kg)
      
!-----------------------------------------------------------------------
!  local variables
!-----------------------------------------------------------------------
      real            :: FWASH, QTMAX, QTDIF

!-----------------------------------------------------------------------
!  effective Henry's Law constant: H* = moles-T / liter-precip / press(atm-T)
!  p(atm of tracer-T) = (QT/QM) * (.029/MolWt-T) * pressr(hPa)/1000
!  limit temperature effects to T above freezing
!-----------------------------------------------------------------------

!-----------------------------------------------------------------------
!  effective washout frequency (1/s):
!-----------------------------------------------------------------------
      FWASH = (RWASH*HSTAR*29.e-6*PR)/(QM*BOXF)
!-----------------------------------------------------------------------
!  equilib amount of T (kg) in rain thru bottom of box over time step
!-----------------------------------------------------------------------
      QTMAX = QT*FWASH*DTSCAV
      if( QTMAX > QTRTOP ) then
!-----------------------------------------------------------------------
!  more of tracer T can go into rain
!-----------------------------------------------------------------------
         QTDIF = min( QT,QTMAX-QTRTOP )
         QTWASH = QTDIF * (one - exp( -DTSCAV*FWASH ))
         QTEVAP = zero
      else
!-----------------------------------------------------------------------
!  too much of T in rain, must degas/evap T
!-----------------------------------------------------------------------
         QTWASH = zero
         QTEVAP = QTRTOP - QTMAX
      endif
     
end subroutine WASHGAS

function DEMPIRICAL( CWATER, RRATE )

!-----------------------------------------------------------------------
!  dummy arguments
!-----------------------------------------------------------------------
      real, intent(in)  :: CWATER   
      real, intent(in)  :: RRATE

!-----------------------------------------------------------------------
!  local variables
!-----------------------------------------------------------------------
      real(8), parameter :: big_diameter = 100._8            ! mm
      real(8), parameter :: const0       = .638_8
      real(8), parameter :: const1       = oner8 + const0

      real(8) :: RRATEX, WX, THETA, PHI, ETA, BETA, ALPHA, BEE
      real(8) :: GAMTHETA, GAMBETA
      real(8) :: numer, denom
      real(8) :: diameter                      ! mm

      real :: DEMPIRICAL

      if( cwater > 0._8 ) then
        RRATEX = real(RRATE,kind=8)*3600._8       !mm/hr
        WX     = real(CWATER,kind=8)*1.0e3_8      !g/m3

        if( RRATEX > 0.04_8 ) then
           THETA = exp( -1.43_8*log10( 7._8*RRATEX ) ) + 2.8_8
        else
           THETA = 5._8
        endif

        PHI = RRATEX/(3600._8*10._8) !cgs units
        ETA = exp( 3.01_8*THETA - 10.5_8 )
        BETA  = THETA/const1
        ALPHA = exp( FOURR8*(BETA - 3.5_8) )
        BEE   = const0*BETA - ONER8
        GAMTHETA = real( GAMMA( real(THETA,kind=4) ),kind=8 )
        GAMBETA  = real( GAMMA( real(BETA + ONER8,kind=4) ),kind=8 )

        numer = WX*ETA*GAMTHETA
        denom = 1.0e6_8*ALPHA*PHI*GAMBETA
        diameter = ((numer/denom)**(-oner8/BEE))*10._8
        diameter = min( big_diameter,diameter )
        DEMPIRICAL = real( diameter )
!     DEMPIRICAL = (((WX*ETA*GAMTHETA)/(1.0e6*ALPHA*PHI*GAMBETA))** (-one/BEE))*10.  ! in mm (wx/1e6 for cgs)
      else
        DEMPIRICAL = 0.
      endif

end function DEMPIRICAL

function GAMMA( X )
!-----------------------------------------------------------------------
!       Purpose: Compute the gamma function â(x)
!       Input :  x  --- Argument of â(x)
!                       ( x is not equal to 0,-1,-2,úúú )
!       Output:  GA --- â(x)
!-----------------------------------------------------------------------

!-----------------------------------------------------------------------
!  dummy arguments
!-----------------------------------------------------------------------
        real, intent(in)  :: X

!-----------------------------------------------------------------------
!  local variables
!-----------------------------------------------------------------------
        real, parameter :: PI = 3.141592653589793e0

        integer :: k, M, M1
        real    :: GR, R, Z 
        real    :: G(26)

!-----------------------------------------------------------------------
!  function definition
!-----------------------------------------------------------------------
        real :: GAMMA

        DATA G/1.0e0,0.5772156649015329,                     &
            -0.6558780715202538e0, -0.420026350340952e-1,    &
            0.1665386113822915e0,-.421977345555443e-1,       &
            -.96219715278770e-2, .72189432466630e-2,         &
            -.11651675918591e-2, -.2152416741149e-3,         &
            .1280502823882e-3, -.201348547807e-4,            &
            -.12504934821e-5, .11330272320e-5,               &
            -.2056338417e-6, .61160950e-8,                   &
            .50020075e-8, -.11812746e-8,                     &
            .1043427e-9, .77823e-11,                         &
            -.36968e-11, .51e-12,                            &
            -.206e-13, -.54e-14, .14e-14, .1e-15/

is_integer : &
        IF( x == real( int(x) ) ) then
          IF( X > zero ) THEN
            GAMMA = ONE
            M1 = INT(X) - 1
            DO K = 2,M1
              GAMMA = GAMMA*real(K)
            END DO
          ELSE
            GAMMA = 1.0e36
          ENDIF
        ELSE is_integer
          IF( ABS(X) > ONE ) THEN
            Z = ABS(X)
            M = INT(Z)
            R = ONE
            DO K = 1,M
              R = R*(Z - real(k))
            END DO
            Z = Z - real(M)
          ELSE
            Z = X
          ENDIF
          GR = G(26)
          DO K = 25,1,-1
            GR = GR*Z + G(K)
          end DO
          GAMMA = ONE/(GR*Z)
          IF( ABS(X) > ONE ) THEN
            GAMMA = GAMMA*R
            IF( X < zero ) then
              GAMMA = -PI/(X*GAMMA*SIN( PI*X ))
            ENDIF
          ENDIF
        ENDIF is_integer

END function GAMMA

END MODULE module_mozcart_wetscav