source: LMDZ6/branches/Amaury_dev/libf/phylmd/lmdz_lscp_tools.F90 @ 5155

MODULE lmdz_lscp_tools

  IMPLICIT NONE

CONTAINS

  !+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
  SUBROUTINE FALLICE_VELOCITY(klon, iwc, temp, rho, pres, ptconv, velo)

    ! Ref:
    ! Stubenrauch, C. J., Bonazzola, M.,
    ! Protopapadaki, S. E., & Musat, I. (2019).
    ! New cloud system metrics to assess bulk
    ! ice cloud schemes in a GCM. Journal of
    ! Advances in Modeling Earth Systems, 11,
    ! 3212–3234. https://doi.org/10.1029/2019MS001642

    USE lmdz_lscp_ini, ONLY: iflag_vice, ffallv_con, ffallv_lsc
    USE lmdz_lscp_ini, ONLY: cice_velo, dice_velo

    IMPLICIT NONE

    INTEGER, INTENT(IN) :: klon
    REAL, INTENT(IN), DIMENSION(klon) :: iwc       ! specific ice water content [kg/m3]
    REAL, INTENT(IN), DIMENSION(klon) :: temp      ! temperature [K]
    REAL, INTENT(IN), DIMENSION(klon) :: rho       ! dry air density [kg/m3]
    REAL, INTENT(IN), DIMENSION(klon) :: pres      ! air pressure [Pa]
    LOGICAL, INTENT(IN), DIMENSION(klon) :: ptconv    ! convective point  [-]

    REAL, INTENT(OUT), DIMENSION(klon) :: velo    ! fallspeed velocity of crystals [m/s]

    INTEGER i
    REAL logvm, iwcg, tempc, phpa, fallv_tun
    REAL m2ice, m2snow, vmice, vmsnow
    REAL aice, bice, asnow, bsnow

    DO i = 1, klon

      IF (ptconv(i)) THEN
        fallv_tun = ffallv_con
      ELSE
        fallv_tun = ffallv_lsc
      ENDIF

      tempc = temp(i) - 273.15 ! celcius temp
      iwcg = MAX(iwc(i) * 1000., 1E-3) ! iwc in g/m3. We set a minimum value to prevent from division by 0
      phpa = pres(i) / 100.    ! pressure in hPa

      IF (iflag_vice == 1) THEN
        ! so-called 'empirical parameterization' in Stubenrauch et al. 2019
        IF (tempc >= -60.0) THEN
          logvm = -0.0000414122 * tempc * tempc * log(iwcg) - 0.00538922 * tempc * log(iwcg) &
                  - 0.0516344 * log(iwcg) + 0.00216078 * tempc + 1.9714
          velo(i) = exp(logvm)
        else
          velo(i) = 65.0 * (iwcg**0.2) * (150. / phpa)**0.15
        endif

        velo(i) = fallv_tun * velo(i) / 100.0 ! from cm/s to m/s

      ELSE IF (iflag_vice == 2) THEN
        ! so called  PSDM empirical coherent bulk ice scheme in Stubenrauch et al. 2019
        aice = 0.587
        bice = 2.45
        asnow = 0.0444
        bsnow = 2.1

        m2ice = ((iwcg * 0.001 / aice) / (exp(13.6 - bice * 7.76 + 0.479 * bice**2) * &
                exp((-0.0361 + bice * 0.0151 + 0.00149 * bice**2) * tempc)))   &
                **(1. / (0.807 + bice * 0.00581 + 0.0457 * bice**2))

        vmice = 100. * 1042.4 * exp(13.6 - (bice + 1) * 7.76 + 0.479 * (bice + 1.)**2) * exp((-0.0361 + &
                (bice + 1.) * 0.0151 + 0.00149 * (bice + 1.)**2) * tempc) &
                * (m2ice**(0.807 + (bice + 1.) * 0.00581 + 0.0457 * (bice + 1.)**2)) / (iwcg * 0.001 / aice)

        vmice = vmice * ((1000. / phpa)**0.2)

        m2snow = ((iwcg * 0.001 / asnow) / (exp(13.6 - bsnow * 7.76 + 0.479 * bsnow**2) * &
                exp((-0.0361 + bsnow * 0.0151 + 0.00149 * bsnow**2) * tempc)))         &
                **(1. / (0.807 + bsnow * 0.00581 + 0.0457 * bsnow**2))

        vmsnow = 100. * 14.3 * exp(13.6 - (bsnow + .416) * 7.76 + 0.479 * (bsnow + .416)**2)&
                * exp((-0.0361 + (bsnow + .416) * 0.0151 + 0.00149 * (bsnow + .416)**2) * tempc)&
                * (m2snow**(0.807 + (bsnow + .416) * 0.00581 + 0.0457 * (bsnow + .416)**2)) / (iwcg * 0.001 / asnow)

        vmsnow = vmsnow * ((1000. / phpa)**0.35)
        velo(i) = fallv_tun * min(vmsnow, vmice) / 100. ! to m/s

      ELSE
        ! By default, fallspeed velocity of ice crystals according to Heymsfield & Donner 1990
        velo(i) = fallv_tun * cice_velo * ((iwcg / 1000.)**dice_velo)
      ENDIF
    ENDDO

  END SUBROUTINE FALLICE_VELOCITY
  !+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++

  !+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
  SUBROUTINE ICEFRAC_LSCP(klon, temp, iflag_ice_thermo, distcltop, temp_cltop, icefrac, dicefracdT)
    !+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++

    ! Compute the ice fraction 1-xliq (see e.g.
    ! Doutriaux-Boucher & Quaas 2004, section 2.2.)
    ! as a function of temperature
    ! see also Fig 3 of Madeleine et al. 2020, JAMES
    !+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++

    USE lmdz_print_control, ONLY: lunout, prt_level
    USE lmdz_lscp_ini, ONLY: t_glace_min, t_glace_max, exposant_glace, iflag_t_glace
    USE lmdz_lscp_ini, ONLY: RTT, dist_liq, temp_nowater
    USE lmdz_abort_physic, ONLY: abort_physic

    IMPLICIT NONE

    INTEGER, INTENT(IN) :: klon              ! number of horizontal grid points
    REAL, INTENT(IN), DIMENSION(klon) :: temp              ! temperature
    REAL, INTENT(IN), DIMENSION(klon) :: distcltop         ! distance to cloud top
    REAL, INTENT(IN), DIMENSION(klon) :: temp_cltop        ! temperature of cloud top
    INTEGER, INTENT(IN) :: iflag_ice_thermo
    REAL, INTENT(OUT), DIMENSION(klon) :: icefrac
    REAL, INTENT(OUT), DIMENSION(klon) :: dicefracdT

    INTEGER i
    REAL    liqfrac_tmp, dicefrac_tmp
    REAL    Dv, denomdep, beta, qsi, dqsidt
    LOGICAL ice_thermo

    CHARACTER (len = 20) :: modname = 'lscp_tools'
    CHARACTER (len = 80) :: abort_message

    IF ((iflag_t_glace<2)) THEN !.OR. (iflag_t_glace.GT.6)) THEN
      abort_message = 'lscp cannot be used if iflag_t_glace<2 or >6'
      CALL abort_physic(modname, abort_message, 1)
    ENDIF

    IF (.NOT.((iflag_ice_thermo == 1).OR.(iflag_ice_thermo >= 3))) THEN
      abort_message = 'lscp cannot be used without ice thermodynamics'
      CALL abort_physic(modname, abort_message, 1)
    ENDIF

    DO i = 1, klon

      ! old function with sole dependence upon temperature
      IF (iflag_t_glace == 2) THEN
        liqfrac_tmp = (temp(i) - t_glace_min) / (t_glace_max - t_glace_min)
        liqfrac_tmp = MIN(MAX(liqfrac_tmp, 0.0), 1.0)
        icefrac(i) = (1.0 - liqfrac_tmp)**exposant_glace
        IF (icefrac(i) >0.) THEN
          dicefracdT(i) = exposant_glace * (icefrac(i)**(exposant_glace - 1.)) &
                  / (t_glace_min - t_glace_max)
        ENDIF

        IF ((icefrac(i)==0).OR.(icefrac(i)==1)) THEN
          dicefracdT(i) = 0.
        ENDIF

      ENDIF

      ! function of temperature used in CMIP6 physics
      IF (iflag_t_glace == 3) THEN
        liqfrac_tmp = (temp(i) - t_glace_min) / (t_glace_max - t_glace_min)
        liqfrac_tmp = MIN(MAX(liqfrac_tmp, 0.0), 1.0)
        icefrac(i) = 1.0 - liqfrac_tmp**exposant_glace
        IF ((icefrac(i) >0.) .AND. (liqfrac_tmp > 0.)) THEN
          dicefracdT(i) = exposant_glace * ((liqfrac_tmp)**(exposant_glace - 1.)) &
                  / (t_glace_min - t_glace_max)
        ELSE
          dicefracdT(i) = 0.
        ENDIF
      ENDIF

      ! for iflag_t_glace .GE. 4, the liquid fraction depends upon temperature at cloud top
      ! and then decreases with decreasing height

      !with linear function of temperature at cloud top
      IF (iflag_t_glace == 4) THEN
        liqfrac_tmp = (temp(i) - t_glace_min) / (t_glace_max - t_glace_min)
        liqfrac_tmp = MIN(MAX(liqfrac_tmp, 0.0), 1.0)
        icefrac(i) = MAX(MIN(1., 1.0 - liqfrac_tmp * exp(-distcltop(i) / dist_liq)), 0.)
        dicefrac_tmp = - temp(i) / (t_glace_max - t_glace_min)
        dicefracdT(i) = dicefrac_tmp * exp(-distcltop(i) / dist_liq)
        IF ((liqfrac_tmp <=0) .OR. (liqfrac_tmp >= 1)) THEN
          dicefracdT(i) = 0.
        ENDIF
      ENDIF

      ! with CMIP6 function of temperature at cloud top
      IF ((iflag_t_glace == 5) .OR. (iflag_t_glace == 7)) THEN
        liqfrac_tmp = (temp(i) - t_glace_min) / (t_glace_max - t_glace_min)
        liqfrac_tmp = MIN(MAX(liqfrac_tmp, 0.0), 1.0)
        liqfrac_tmp = liqfrac_tmp**exposant_glace
        icefrac(i) = MAX(MIN(1., 1.0 - liqfrac_tmp * exp(-distcltop(i) / dist_liq)), 0.)
        IF ((liqfrac_tmp <=0) .OR. (liqfrac_tmp >= 1)) THEN
          dicefracdT(i) = 0.
        ELSE
          dicefracdT(i) = exposant_glace * ((liqfrac_tmp)**(exposant_glace - 1.)) / (t_glace_min - t_glace_max) &
                  * exp(-distcltop(i) / dist_liq)
        ENDIF
      ENDIF

      ! with modified function of temperature at cloud top
      ! to get largere values around 260 K, works well with t_glace_min = 241K
      IF (iflag_t_glace == 6) THEN
        IF (temp(i) > t_glace_max) THEN
          liqfrac_tmp = 1.
        ELSE
          liqfrac_tmp = -((temp(i) - t_glace_max) / (t_glace_max - t_glace_min))**2 + 1.
        ENDIF
        liqfrac_tmp = MIN(MAX(liqfrac_tmp, 0.0), 1.0)
        icefrac(i) = MAX(MIN(1., 1.0 - liqfrac_tmp * exp(-distcltop(i) / dist_liq)), 0.)
        IF ((liqfrac_tmp <=0) .OR. (liqfrac_tmp >= 1)) THEN
          dicefracdT(i) = 0.
        ELSE
          dicefracdT(i) = 2 * ((temp(i) - t_glace_max) / (t_glace_max - t_glace_min)) / (t_glace_max - t_glace_min) &
                  * exp(-distcltop(i) / dist_liq)
        ENDIF
      ENDIF

      ! if temperature of cloud top <-40°C,
      IF (iflag_t_glace >= 4) THEN
        IF ((temp_cltop(i) <= temp_nowater) .AND. (temp(i) <= t_glace_max)) THEN
          icefrac(i) = 1.
          dicefracdT(i) = 0.
        ENDIF
      ENDIF

    ENDDO ! klon

  END SUBROUTINE ICEFRAC_LSCP
  !+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++

  SUBROUTINE ICEFRAC_LSCP_TURB(klon, dtime, temp, pplay, paprsdn, paprsup, qice_ini, snowcld, qtot_incl, cldfra, tke, tke_dissip, qliq, qvap_cld, qice, icefrac, dicefracdT, cldfraliq, sigma2_icefracturb, mean_icefracturb)
    !+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
    ! Compute the liquid, ice and vapour content (+ice fraction) based
    ! on turbulence (see Fields 2014, Furtado 2016)
    !+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++

    USE lmdz_lscp_ini, ONLY: prt_level, lunout
    USE lmdz_lscp_ini, ONLY: RCPD, RLSTT, RLVTT, RLMLT, RVTMP2, RTT, RD, RG, RV, RPI
    USE lmdz_lscp_ini, ONLY: seuil_neb, temp_nowater
    USE lmdz_lscp_ini, ONLY: tau_mixenv, lmix_mpc, naero5, gamma_snwretro, gamma_taud, capa_crystal
    USE lmdz_lscp_ini, ONLY: eps

    IMPLICIT NONE

    INTEGER, INTENT(IN) :: klon              !--number of horizontal grid points
    REAL, INTENT(IN) :: dtime             !--time step [s]

    REAL, INTENT(IN), DIMENSION(klon) :: temp              !--temperature
    REAL, INTENT(IN), DIMENSION(klon) :: pplay             !--pressure in the middle of the layer       [Pa]
    REAL, INTENT(IN), DIMENSION(klon) :: paprsdn           !--pressure at the bottom interface of the layer [Pa]
    REAL, INTENT(IN), DIMENSION(klon) :: paprsup           !--pressure at the top interface of the layer [Pa]
    REAL, INTENT(IN), DIMENSION(klon) :: qtot_incl         !--specific total cloud water content, in-cloud content [kg/kg]
    REAL, INTENT(IN), DIMENSION(klon) :: cldfra            !--cloud fraction in gridbox [-]
    REAL, INTENT(IN), DIMENSION(klon) :: tke               !--turbulent kinetic energy [m2/s2]
    REAL, INTENT(IN), DIMENSION(klon) :: tke_dissip        !--TKE dissipation [m2/s3]

    REAL, INTENT(IN), DIMENSION(klon) :: qice_ini          !--initial specific ice content gridbox-mean [kg/kg]
    REAL, INTENT(IN), DIMENSION(klon) :: snowcld
    REAL, INTENT(OUT), DIMENSION(klon) :: qliq              !--specific liquid content gridbox-mean [kg/kg]
    REAL, INTENT(OUT), DIMENSION(klon) :: qvap_cld          !--specific cloud vapor content, gridbox-mean [kg/kg]
    REAL, INTENT(OUT), DIMENSION(klon) :: qice              !--specific ice content gridbox-mean [kg/kg]
    REAL, INTENT(OUT), DIMENSION(klon) :: icefrac           !--fraction of ice in condensed water [-]
    REAL, INTENT(OUT), DIMENSION(klon) :: dicefracdT

    REAL, INTENT(OUT), DIMENSION(klon) :: cldfraliq         !--fraction of cldfra which is liquid only
    REAL, INTENT(OUT), DIMENSION(klon) :: sigma2_icefracturb     !--Temporary
    REAL, INTENT(OUT), DIMENSION(klon) :: mean_icefracturb      !--Temporary

    REAL, DIMENSION(klon) :: qzero, qsatl, dqsatl, qsati, dqsati         !--specific humidity saturation values
    INTEGER :: i

    REAL :: qvap_incl, qice_incl, qliq_incl, qiceini_incl                !--In-cloud specific quantities [kg/kg]
    REAL :: qsnowcld_incl
    !REAL :: capa_crystal                                                 !--Capacitance of ice crystals  [-]
    REAL :: water_vapor_diff                                             !--Water-vapour diffusion coefficient in air [m2/s] (function of T&P)
    REAL :: air_thermal_conduct                                          !--Thermal conductivity of air [J/m/K/s] (function of T)
    REAL :: C0                                                           !--Lagrangian structure function [-]
    REAL :: tau_mixingenv
    REAL :: tau_dissipturb
    REAL :: invtau_phaserelax
    REAL :: sigma2_pdf, mean_pdf
    REAL :: ai, bi, B0
    REAL :: sursat_iceliq
    REAL :: sursat_env
    REAL :: liqfra_max
    REAL :: sursat_iceext
    REAL :: nb_crystals                                                  !--number concentration of ice crystals [#/m3]
    REAL :: moment1_PSD                                                  !--1st moment of ice PSD
    REAL :: N0_PSD, lambda_PSD                                           !--parameters of the exponential PSD

    REAL :: rho_ice                                                      !--ice density [kg/m3]
    REAL :: cldfra1D
    REAL :: deltaz, rho_air
    REAL :: psati                                                        !--saturation vapor pressure wrt i [Pa]

    C0 = 10.                                                  !--value assumed in Field2014
    rho_ice = 950.
    sursat_iceext = -0.1
    !capa_crystal  = 1. !r_ice
    qzero(:) = 0.
    cldfraliq(:) = 0.
    icefrac(:) = 0.
    dicefracdT(:) = 0.

    sigma2_icefracturb(:) = 0.
    mean_icefracturb(:) = 0.

    !--wrt liquid water
    CALL calc_qsat_ecmwf(klon, temp(:), qzero(:), pplay(:), RTT, 1, .FALSE., qsatl(:), dqsatl(:))
    !--wrt ice
    CALL calc_qsat_ecmwf(klon, temp(:), qzero(:), pplay(:), RTT, 2, .FALSE., qsati(:), dqsati(:))

    DO i = 1, klon

      rho_air = pplay(i) / temp(i) / RD
      !deltaz   = ( paprsdn(i) - paprsup(i) ) / RG / rho_air(i)
      ! because cldfra is intent in, but can be locally modified due to test
      cldfra1D = cldfra(i)
      IF (cldfra(i) <= 0.) THEN
        qvap_cld(i) = 0.
        qliq(i) = 0.
        qice(i) = 0.
        cldfraliq(i) = 0.
        icefrac(i) = 0.
        dicefracdT(i) = 0.

        ! If there is a cloud
      ELSE
        IF (cldfra(i) >= 1.0) THEN
          cldfra1D = 1.0
        END IF

        ! T>0°C, no ice allowed
        IF (temp(i) >= RTT) THEN
          qvap_cld(i) = qsatl(i) * cldfra1D
          qliq(i) = MAX(0.0, qtot_incl(i) - qsatl(i)) * cldfra1D
          qice(i) = 0.
          cldfraliq(i) = 1.
          icefrac(i) = 0.
          dicefracdT(i) = 0.

          ! T<-38°C, no liquid allowed
        ELSE IF (temp(i) <= temp_nowater) THEN
          qvap_cld(i) = qsati(i) * cldfra1D
          qliq(i) = 0.
          qice(i) = MAX(0.0, qtot_incl(i) - qsati(i)) * cldfra1D
          cldfraliq(i) = 0.
          icefrac(i) = 1.
          dicefracdT(i) = 0.

          ! MPC temperature
        ELSE
          ! Not enough TKE
          IF (tke_dissip(i) <= eps)  THEN
            qvap_cld(i) = qsati(i) * cldfra1D
            qliq(i) = 0.
            qice(i) = MAX(0., qtot_incl(i) - qsati(i)) * cldfra1D
            cldfraliq(i) = 0.
            icefrac(i) = 1.
            dicefracdT(i) = 0.

            ! Enough TKE
          ELSE
            !---------------------------------------------------------
            !--               ICE SUPERSATURATION PDF
            !---------------------------------------------------------
            !--If -38°C< T <0°C and there is enough turbulence,
            !--we compute the cloud liquid properties with a Gaussian PDF
            !--of ice supersaturation F(Si) (Field2014, Furtado2016).
            !--Parameters of the PDF are function of turbulence and
            !--microphysics/existing ice.

            sursat_iceliq = qsatl(i) / qsati(i) - 1.
            psati = qsati(i) * pplay(i) / (RD / RV)

            !-------------- MICROPHYSICAL TERMS --------------
            !--We assume an exponential ice PSD whose parameters
            !--are computed following Morrison&Gettelman 2008
            !--Ice number density is assumed equals to INP density
            !--which is a function of temperature (DeMott 2010)
            !--bi and B0 are microphysical function characterizing
            !--vapor/ice interactions
            !--tau_phase_relax is the typical time of vapor deposition
            !--onto ice crystals

            qiceini_incl = qice_ini(i) / cldfra1D
            qsnowcld_incl = snowcld(i) * RG * dtime / (paprsdn(i) - paprsup(i)) / cldfra1D
            sursat_env = max(0., (qtot_incl(i) - qiceini_incl) / qsati(i) - 1.)
            IF (qiceini_incl > eps) THEN
              nb_crystals = 1.e3 * 5.94e-5 * (RTT - temp(i))**3.33 * naero5**(0.0264 * (RTT - temp(i)) + 0.0033)
              lambda_PSD = ((RPI * rho_ice * nb_crystals * 24.) / (6. * (qiceini_incl + gamma_snwretro * qsnowcld_incl))) ** (1. / 3.)
              N0_PSD = nb_crystals * lambda_PSD
              moment1_PSD = N0_PSD / 2. / lambda_PSD**2
            ELSE
              moment1_PSD = 0.
            ENDIF

            !--Formulae for air thermal conductivity and water vapor diffusivity
            !--comes respectively from Beard and Pruppacher (1971)
            !--and  Hall and Pruppacher (1976)

            air_thermal_conduct = (5.69 + 0.017 * (temp(i) - RTT)) * 1.e-3 * 4.184
            water_vapor_diff = 2.11 * 1e-5 * (temp(i) / RTT)**1.94 * (101325 / pplay(i))

            bi = 1. / ((qsati(i) + qsatl(i)) / 2.) + RLSTT**2 / RCPD / RV / temp(i)**2
            B0 = 4. * RPI * capa_crystal * 1. / (RLSTT**2 / air_thermal_conduct / RV / temp(i)**2  &
                    + RV * temp(i) / psati / water_vapor_diff)

            invtau_phaserelax = (bi * B0 * moment1_PSD)

            !             Old way of estimating moment1 : spherical crystals + monodisperse PSD
            !             nb_crystals = rho_air * qiceini_incl / ( 4. / 3. * RPI * r_ice**3. * rho_ice )
            !             moment1_PSD = nb_crystals * r_ice

            !----------------- TURBULENT SOURCE/SINK TERMS -----------------
            !--Tau_mixingenv is the time needed to homogeneize the parcel
            !--with its environment by turbulent diffusion over the parcel
            !--length scale
            !--if lmix_mpc <0, tau_mixigenv value is prescribed
            !--else tau_mixigenv value is derived from tke_dissip and lmix_mpc
            !--Tau_dissipturb is the time needed turbulence to decay due to
            !--viscosity

            ai = RG / RD / temp(i) * (RD * RLSTT / RCPD / RV / temp(i) - 1.)
            IF (lmix_mpc > 0) THEN
              tau_mixingenv = (lmix_mpc**2. / tke_dissip(i))**(1. / 3.)
            ELSE
              tau_mixingenv = tau_mixenv
            ENDIF

            tau_dissipturb = gamma_taud * 2. * 2. / 3. * tke(i) / tke_dissip(i) / C0

            !--------------------- PDF COMPUTATIONS ---------------------
            !--Formulae for sigma2_pdf (variance), mean of PDF in Furtado2016
            !--cloud liquid fraction and in-cloud liquid content are given
            !--by integrating resp. F(Si) and Si*F(Si)
            !--Liquid is limited by the available water vapor trough a
            !--maximal liquid fraction

            liqfra_max = MAX(0., (MIN (1., (qtot_incl(i) - qiceini_incl - qsati(i) * (1 + sursat_iceext)) / (qsatl(i) - qsati(i)))))
            sigma2_pdf = 1. / 2. * (ai**2) * 2. / 3. * tke(i) * tau_dissipturb / (invtau_phaserelax + 1. / tau_mixingenv)
            mean_pdf = sursat_env * 1. / tau_mixingenv / (invtau_phaserelax + 1. / tau_mixingenv)
            cldfraliq(i) = 0.5 * (1. - erf((sursat_iceliq - mean_pdf) / (SQRT(2. * sigma2_pdf))))
            !IF (cldfraliq(i) .GT. liqfra_max) THEN
            !    cldfraliq(i) = liqfra_max
            !ENDIF

            qliq_incl = qsati(i) * SQRT(sigma2_pdf) / SQRT(2. * RPI) * EXP(-1. * (sursat_iceliq - mean_pdf)**2. / (2. * sigma2_pdf))  &
                    - qsati(i) * cldfraliq(i) * (sursat_iceliq - mean_pdf)

            sigma2_icefracturb(i) = sigma2_pdf
            mean_icefracturb(i) = mean_pdf
            !------------ ICE AMOUNT AND WATER CONSERVATION  ------------

            IF ((qliq_incl <= eps) .OR. (cldfraliq(i) <= eps)) THEN
              qliq_incl = 0.
              cldfraliq(i) = 0.
            END IF

            !--Choice for in-cloud vapor :
            !--1.Weighted mean between qvap in MPC parts and in ice-only parts
            !--2.Always at ice saturation
            qvap_incl = MAX(qsati(i), (1. - cldfraliq(i)) * (sursat_iceext + 1.) * qsati(i) + cldfraliq(i) * qsatl(i))

            IF (qvap_incl  >= qtot_incl(i)) THEN
              qvap_incl = qsati(i)
              qliq_incl = qtot_incl(i) - qvap_incl
              qice_incl = 0.

            ELSEIF ((qvap_incl + qliq_incl) >= qtot_incl(i)) THEN
              qliq_incl = MAX(0.0, qtot_incl(i) - qvap_incl)
              qice_incl = 0.
            ELSE
              qice_incl = qtot_incl(i) - qvap_incl - qliq_incl
            END IF

            qvap_cld(i) = qvap_incl * cldfra1D
            qliq(i) = qliq_incl * cldfra1D
            qice(i) = qice_incl * cldfra1D
            icefrac(i) = qice(i) / (qice(i) + qliq(i))
            dicefracdT(i) = 0.
            !PRINT*,'MPC turb'

          END IF ! Enough TKE

        END IF ! MPC temperature

      END IF ! cldfra

    ENDDO ! klon
  END SUBROUTINE ICEFRAC_LSCP_TURB
  !+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++


  SUBROUTINE CALC_QSAT_ECMWF(klon, temp, qtot, pressure, tref, phase, flagth, qs, dqs)
    !+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
    ! Calculate qsat following ECMWF method
    !+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
    USE lmdz_yoethf

    USE lmdz_yomcst

    IMPLICIT NONE
 INCLUDE "FCTTRE.h"

    INTEGER, INTENT(IN) :: klon  ! number of horizontal grid points
    REAL, INTENT(IN), DIMENSION(klon) :: temp     ! temperature in K
    REAL, INTENT(IN), DIMENSION(klon) :: qtot     ! total specific water in kg/kg
    REAL, INTENT(IN), DIMENSION(klon) :: pressure ! pressure in Pa
    REAL, INTENT(IN) :: tref     ! reference temperature in K
    LOGICAL, INTENT(IN) :: flagth     ! flag for qsat calculation for thermals
    INTEGER, INTENT(IN) :: phase
    ! phase: 0=depend on temperature sign (temp>tref -> liquid, temp<tref, solid)
    !        1=liquid
    !        2=solid

    REAL, INTENT(OUT), DIMENSION(klon) :: qs      ! saturation specific humidity [kg/kg]
    REAL, INTENT(OUT), DIMENSION(klon) :: dqs     ! derivation of saturation specific humidity wrt T

    REAL delta, cor, cvm5
    INTEGER i

    DO i = 1, klon

      IF (phase == 1) THEN
        delta = 0.
      ELSEIF (phase == 2) THEN
        delta = 1.
      ELSE
        delta = MAX(0., SIGN(1., tref - temp(i)))
      ENDIF

      IF (flagth) THEN
        cvm5 = R5LES * (1. - delta) + R5IES * delta
      ELSE
        cvm5 = R5LES * RLVTT * (1. - delta) + R5IES * RLSTT * delta
        cvm5 = cvm5 / RCPD / (1.0 + RVTMP2 * (qtot(i)))
      ENDIF

      qs(i) = R2ES * FOEEW(temp(i), delta) / pressure(i)
      qs(i) = MIN(0.5, qs(i))
      cor = 1. / (1. - RETV * qs(i))
      qs(i) = qs(i) * cor
      dqs(i) = FOEDE(temp(i), delta, cvm5, qs(i), cor)

    END DO

  END SUBROUTINE CALC_QSAT_ECMWF
  !+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++


  !+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
  SUBROUTINE CALC_GAMMASAT(klon, temp, qtot, pressure, gammasat, dgammasatdt)

    !+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
    ! programme that calculates the gammasat parameter that determines the
    ! homogeneous condensation thresholds for cold (<0oC) clouds
    ! condensation at q>gammasat*qsat
    ! Etienne Vignon, March 2021
    !+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++

    USE lmdz_lscp_ini, ONLY: iflag_gammasat, t_glace_min, RTT

    IMPLICIT NONE

    INTEGER, INTENT(IN) :: klon                       ! number of horizontal grid points
    REAL, INTENT(IN), DIMENSION(klon) :: temp         ! temperature in K
    REAL, INTENT(IN), DIMENSION(klon) :: qtot         ! total specific water in kg/kg

    REAL, INTENT(IN), DIMENSION(klon) :: pressure     ! pressure in Pa

    REAL, INTENT(OUT), DIMENSION(klon) :: gammasat    ! coefficient to multiply qsat with to calculate saturation
    REAL, INTENT(OUT), DIMENSION(klon) :: dgammasatdt ! derivative of gammasat wrt temperature

    REAL, DIMENSION(klon) :: qsi, qsl, dqsl, dqsi
    REAL  fcirrus, fac
    REAL, PARAMETER :: acirrus = 2.349
    REAL, PARAMETER :: bcirrus = 259.0

    INTEGER i

    CALL CALC_QSAT_ECMWF(klon, temp, qtot, pressure, RTT, 1, .FALSE., qsl, dqsl)
    CALL CALC_QSAT_ECMWF(klon, temp, qtot, pressure, RTT, 2, .FALSE., qsi, dqsi)

    DO i = 1, klon

      IF (temp(i) >= RTT) THEN
        ! warm clouds: condensation at saturation wrt liquid
        gammasat(i) = 1.
        dgammasatdt(i) = 0.

      ELSEIF ((temp(i) < RTT) .AND. (temp(i) > t_glace_min)) THEN

        IF (iflag_gammasat >= 2) THEN
          gammasat(i) = qsl(i) / qsi(i)
          dgammasatdt(i) = (dqsl(i) * qsi(i) - dqsi(i) * qsl(i)) / qsi(i) / qsi(i)
        ELSE
          gammasat(i) = 1.
          dgammasatdt(i) = 0.
        ENDIF

      ELSE

        IF (iflag_gammasat >=1) THEN
          ! homogeneous freezing of aerosols, according to
          ! Koop, 2000 and Karcher 2008, QJRMS
          ! 'Cirrus regime'
          fcirrus = acirrus - temp(i) / bcirrus
          IF (fcirrus > qsl(i) / qsi(i)) THEN
            gammasat(i) = qsl(i) / qsi(i)
            dgammasatdt(i) = (dqsl(i) * qsi(i) - dqsi(i) * qsl(i)) / qsi(i) / qsi(i)
          ELSE
            gammasat(i) = fcirrus
            dgammasatdt(i) = -1.0 / bcirrus
          ENDIF

        ELSE

          gammasat(i) = 1.
          dgammasatdt(i) = 0.

        ENDIF

      ENDIF

    END DO

  END SUBROUTINE CALC_GAMMASAT
  !+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++


  !++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
  SUBROUTINE DISTANCE_TO_CLOUD_TOP(klon, klev, k, temp, pplay, paprs, rneb, distcltop1D, temp_cltop)
    !++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++

    USE lmdz_lscp_ini, ONLY: rd, rg, tresh_cl

    IMPLICIT NONE

    INTEGER, INTENT(IN) :: klon, klev                !number of horizontal and vertical grid points
    INTEGER, INTENT(IN) :: k                        ! vertical index
    REAL, INTENT(IN), DIMENSION(klon, klev) :: temp  ! temperature in K
    REAL, INTENT(IN), DIMENSION(klon, klev) :: pplay ! pressure middle layer in Pa
    REAL, INTENT(IN), DIMENSION(klon, klev + 1) :: paprs ! pressure interfaces in Pa
    REAL, INTENT(IN), DIMENSION(klon, klev) :: rneb  ! cloud fraction

    REAL, INTENT(OUT), DIMENSION(klon) :: distcltop1D  ! distance from cloud top
    REAL, INTENT(OUT), DIMENSION(klon) :: temp_cltop     ! temperature of cloud top

    REAL dzlay(klon, klev)
    REAL zlay(klon, klev)
    REAL dzinterf
    INTEGER i, k_top, kvert
    LOGICAL bool_cl

    DO i = 1, klon
      ! Initialization height middle of first layer
      dzlay(i, 1) = Rd * temp(i, 1) / rg * log(paprs(i, 1) / paprs(i, 2))
      zlay(i, 1) = dzlay(i, 1) / 2

      DO kvert = 2, klev
        IF (kvert==klev) THEN
          dzlay(i, kvert) = 2 * (rd * temp(i, kvert) / rg * log(paprs(i, kvert) / pplay(i, kvert)))
        ELSE
          dzlay(i, kvert) = rd * temp(i, kvert) / rg * log(paprs(i, kvert) / paprs(i, kvert + 1))
        ENDIF
        dzinterf = rd * temp(i, kvert) / rg * log(pplay(i, kvert - 1) / pplay(i, kvert))
        zlay(i, kvert) = zlay(i, kvert - 1) + dzinterf
      ENDDO
    ENDDO

    DO i = 1, klon
      k_top = k
      IF (rneb(i, k) <= tresh_cl) THEN
        bool_cl = .FALSE.
      ELSE
        bool_cl = .TRUE.
      ENDIF

      DO WHILE ((bool_cl) .AND. (k_top <= klev))
        ! find cloud top
        IF (rneb(i, k_top) > tresh_cl) THEN
          k_top = k_top + 1
        ELSE
          bool_cl = .FALSE.
          k_top = k_top - 1
        ENDIF
      ENDDO
      k_top = min(k_top, klev)

      !dist to top is dist between current layer and layer of cloud top (from middle to middle) + dist middle to
      !interf for layer of cloud top
      distcltop1D(i) = zlay(i, k_top) - zlay(i, k) + dzlay(i, k_top) / 2
      temp_cltop(i) = temp(i, k_top)
    ENDDO ! klon

  END SUBROUTINE DISTANCE_TO_CLOUD_TOP
  !++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++

END MODULE lmdz_lscp_tools