MODULE zdfkpp !!====================================================================== !! *** MODULE zdfkpp *** !! Ocean physics: vertical mixing coefficient compute from the KPP !! turbulent closure parameterization !!===================================================================== !! History : OPA ! 2000-03 (W.G. Large, J. Chanut) Original code !! 8.1 ! 2002-06 (J.M. Molines) for real case CLIPPER !! 8.2 ! 2003-10 (Chanut J.) re-writting !! NEMO 1.0 ! 2005-01 (C. Ethe, G. Madec) Free form, F90 + creation of tra_kpp routine !! 3.3 ! 2010-10 (C. Ethe, G. Madec) reorganisation of initialisation phase + merge TRC-TRA !!---------------------------------------------------------------------- #if defined key_zdfkpp || defined key_esopa !!---------------------------------------------------------------------- !! 'key_zdfkpp' KPP scheme !!---------------------------------------------------------------------- !! zdf_kpp : update momentum and tracer Kz from a kpp scheme !! zdf_kpp_init : initialization, namelist read, and parameters control !! tra_kpp : compute and add to the T & S trend the non-local flux !! trc_kpp : compute and add to the passive tracer trend the non-local flux (lk_top=T) !!---------------------------------------------------------------------- USE oce ! ocean dynamics and active tracers USE dom_oce ! ocean space and time domain USE zdf_oce ! ocean vertical physics USE sbc_oce ! surface boundary condition: ocean USE phycst ! physical constants USE eosbn2 ! equation of state USE zdfddm ! double diffusion mixing (avs array) USE lib_mpp ! MPP library USE trd_oce ! ocean trends definition USE trdtra ! tracers trends ! USE in_out_manager ! I/O manager USE lbclnk ! ocean lateral boundary conditions (or mpp link) USE prtctl ! Print control USE wrk_nemo ! work arrays USE timing ! Timing USE lib_fortran ! Fortran utilities (allows no signed zero when 'key_nosignedzero' defined) IMPLICIT NONE PRIVATE PUBLIC zdf_kpp ! routine called by step.F90 PUBLIC zdf_kpp_init ! routine called by opa.F90 PUBLIC tra_kpp ! routine called by step.F90 PUBLIC trc_kpp ! routine called by trcstp.F90 LOGICAL , PUBLIC, PARAMETER :: lk_zdfkpp = .TRUE. !: KPP vertical mixing flag REAL(wp), PUBLIC, ALLOCATABLE, SAVE, DIMENSION(:,:,:) :: ghats !: non-local scalar mixing term (gamma/o) REAL(wp), PUBLIC, ALLOCATABLE, SAVE, DIMENSION(:,:) :: wt0 !: surface temperature flux for non local flux REAL(wp), PUBLIC, ALLOCATABLE, SAVE, DIMENSION(:,:) :: ws0 !: surface salinity flux for non local flux REAL(wp), PUBLIC, ALLOCATABLE, SAVE, DIMENSION(:,:) :: hkpp !: boundary layer depth ! !!* Namelist namzdf_kpp * REAL(wp) :: rn_difmiw ! constant internal wave viscosity (m2/s) REAL(wp) :: rn_difsiw ! constant internal wave diffusivity (m2/s) REAL(wp) :: rn_riinfty ! local Richardson Number limit for shear instability REAL(wp) :: rn_difri ! maximum shear mixing at Rig = 0 (m2/s) REAL(wp) :: rn_bvsqcon ! Brunt-Vaisala squared (1/s**2) for maximum convection REAL(wp) :: rn_difcon ! maximum mixing in interior convection (m2/s) INTEGER :: nn_ave ! = 0/1 flag for horizontal average on avt, avmu, avmv #if defined key_zdfddm ! !!! ** Double diffusion Mixing REAL(wp) :: difssf = 1.e-03_wp ! maximum salt fingering mixing REAL(wp) :: Rrho0 = 1.9_wp ! limit for salt fingering mixing REAL(wp) :: difsdc = 1.5e-06_wp ! maximum diffusive convection mixing #endif LOGICAL :: ln_kpprimix ! Shear instability mixing ! !!! ** General constants ** REAL(wp) :: epsln = 1.0e-20_wp ! a small positive number REAL(wp) :: pthird = 1._wp/3._wp ! 1/3 REAL(wp) :: pfourth = 1._wp/4._wp ! 1/4 ! !!! ** Boundary Layer Turbulence Parameters ** REAL(wp) :: vonk = 0.4_wp ! von Karman's constant REAL(wp) :: epsilon = 0.1_wp ! nondimensional extent of the surface layer REAL(wp) :: rconc1 = 5.0_wp ! standard flux profile function parmaeters REAL(wp) :: rconc2 = 16.0_wp ! " " REAL(wp) :: rconcm = 8.38_wp ! momentum flux profile fit REAL(wp) :: rconam = 1.26_wp ! " " REAL(wp) :: rzetam = -.20_wp ! " " REAL(wp) :: rconcs = 98.96_wp ! scalar flux profile fit REAL(wp) :: rconas = -28.86_wp ! " " REAL(wp) :: rzetas = -1.0_wp ! " " ! !!! ** Boundary Layer Depth Diagnostic ** REAL(wp) :: Ricr = 0.3_wp ! critical bulk Richardson Number REAL(wp) :: rcekman = 0.7_wp ! coefficient for ekman depth REAL(wp) :: rcmonob = 1.0_wp ! coefficient for Monin-Obukhov depth REAL(wp) :: rconcv = 1.7_wp ! ratio of interior buoyancy frequency to its value at entrainment depth REAL(wp) :: hbf = 1.0_wp ! fraction of bound. layer depth to which absorbed solar ! ! rad. and contributes to surf. buo. forcing REAL(wp) :: Vtc ! function of rconcv,rconcs,epsilon,vonk,Ricr ! !!! ** Nonlocal Boundary Layer Mixing ** REAL(wp) :: rcstar = 5.0_wp ! coefficient for convective nonlocal transport REAL(wp) :: rcs = 1.0e-3_wp ! conversion: mm/s ==> m/s REAL(wp) :: rcg ! non-dimensional coefficient for nonlocal transport #if ! defined key_kppcustom REAL(wp), ALLOCATABLE, SAVE, DIMENSION(:,:) :: del ! array for reference mean values of vertical integration #endif #if defined key_kpplktb ! !!! ** Parameters for lookup table for turbulent velocity scales ** INTEGER, PARAMETER :: nilktb = 892 ! number of values for zehat in KPP lookup table INTEGER, PARAMETER :: njlktb = 482 ! number of values for ustar in KPP lookup table INTEGER, PARAMETER :: nilktbm1 = nilktb-1 ! INTEGER, PARAMETER :: njlktbm1 = njlktb-1 ! REAL(wp), DIMENSION(nilktb,njlktb) :: wmlktb ! lookup table for the turbulent vertical velocity scale (momentum) REAL(wp), DIMENSION(nilktb,njlktb) :: wslktb ! lookup table for the turbulent vertical velocity scale (tracers) REAL(wp) :: dehatmin = -4.e-7_wp ! minimum limit for zhat in lookup table (m3/s3) REAL(wp) :: dehatmax = 0._wp ! maximum limit for zhat in lookup table (m3/s3) REAL(wp) :: ustmin = 0._wp ! minimum limit for ustar in lookup table (m/s) REAL(wp) :: ustmax = 0.04_wp ! maximum limit for ustar in lookup table (m/s) REAL(wp) :: dezehat ! delta zhat in lookup table REAL(wp) :: deustar ! delta ustar in lookup table #endif REAL(wp), ALLOCATABLE, SAVE, DIMENSION(:) :: ratt ! attenuation coef (already defines in module traqsr, ! ! but only if the solar radiation penetration is considered) ! !!! * penetrative solar radiation coefficient * REAL(wp) :: rabs = 0.58_wp ! fraction associated with xsi1 REAL(wp) :: xsi1 = 0.35_wp ! first depth of extinction REAL(wp) :: xsi2 = 23.0_wp ! second depth of extinction ! ! (default values: water type Ib) REAL(wp), ALLOCATABLE, SAVE, DIMENSION(:,:,:) :: etmean, eumean, evmean ! coeff. used for hor. smoothing at t-, u- & v-points #if defined key_c1d REAL(wp), PUBLIC, ALLOCATABLE, SAVE, DIMENSION(:,:,:) :: rig !: gradient Richardson number REAL(wp), PUBLIC, ALLOCATABLE, SAVE, DIMENSION(:,:,:) :: rib !: bulk Richardson number REAL(wp), PUBLIC, ALLOCATABLE, SAVE, DIMENSION(:,:,:) :: buof !: buoyancy forcing REAL(wp), PUBLIC, ALLOCATABLE, SAVE, DIMENSION(:,:,:) :: mols !: moning-Obukhov length scale REAL(wp), PUBLIC, ALLOCATABLE, SAVE, DIMENSION(:,:) :: ekdp !: Ekman depth #endif INTEGER :: jip = 62 , jjp = 111 !! * Substitutions # include "domzgr_substitute.h90" # include "vectopt_loop_substitute.h90" # include "zdfddm_substitute.h90" !!---------------------------------------------------------------------- !! NEMO/OPA 4.0 , NEMO Consortium (2011) !! $Id$ !! Software governed by the CeCILL licence (NEMOGCM/NEMO_CeCILL.txt) !!---------------------------------------------------------------------- CONTAINS INTEGER FUNCTION zdf_kpp_alloc() !!---------------------------------------------------------------------- !! *** FUNCTION zdf_kpp_alloc *** !!---------------------------------------------------------------------- ALLOCATE( ghats(jpi,jpj,jpk), wt0(jpi,jpj), ws0(jpi,jpj), hkpp(jpi,jpj), & #if ! defined key_kpplktb & del(jpk,jpk), & #endif & ratt(jpk), & & etmean(jpi,jpj,jpk), eumean(jpi,jpj,jpk), evmean(jpi,jpj,jpk), & #if defined key_c1d & rig (jpi,jpj,jpk), rib(jpi,jpj,jpk), buof(jpi,jpj,jpk), & & mols(jpi,jpj,jpk), ekdp(jpi,jpj), & #endif & STAT= zdf_kpp_alloc ) ! IF( lk_mpp ) CALL mpp_sum ( zdf_kpp_alloc ) IF( zdf_kpp_alloc /= 0 ) CALL ctl_warn('zdf_kpp_alloc: failed to allocate arrays') END FUNCTION zdf_kpp_alloc SUBROUTINE zdf_kpp( kt ) !!---------------------------------------------------------------------- !! *** ROUTINE zdf_kpp *** !! !! ** Purpose : Compute the vertical eddy viscosity and diffusivity !! coefficients and non local mixing using K-profile parameterization !! !! ** Method : The boundary layer depth hkpp is diagnosed at tracer points !! from profiles of buoyancy, and shear, and the surface forcing. !! Above hbl (sigma=-z/hbl <1) the mixing coefficients are computed from !! !! Kx = hkpp Wx(sigma) G(sigma) !! !! and the non local term ghat = Cs / Ws(sigma) / hkpp !! Below hkpp the coefficients are the sum of mixing due to internal waves !! shear instability and double diffusion. !! !! -1- Compute the now interior vertical mixing coefficients at all depths. !! -2- Diagnose the boundary layer depth. !! -3- Compute the now boundary layer vertical mixing coefficients. !! -4- Compute the now vertical eddy vicosity and diffusivity. !! -5- Smoothing !! !! N.B. The computation is done from jk=2 to jpkm1 !! Surface value of avt avmu avmv are set once a time to zero !! in routine zdf_kpp_init. !! !! ** Action : update the non-local terms ghats !! update avt, avmu, avmv (before vertical eddy coef.) !! !! References : Large W.G., Mc Williams J.C. and Doney S.C. !! Reviews of Geophysics, 32, 4, November 1994 !! Comments in the code refer to this paper, particularly !! the equation number. (LMD94, here after) !!---------------------------------------------------------------------- USE oce , zviscos => ua ! temp. array for viscosities use ua as workspace USE oce , zdiffut => va ! temp. array for diffusivities use sa as workspace !! INTEGER, INTENT( in ) :: kt ! ocean time step !! INTEGER :: ji, jj, jk ! dummy loop indices INTEGER :: ikbot, jkmax, jkm1, jkp2 ! REAL(wp) :: ztx, zty, zflageos, zstabl, zbuofdep,zucube ! REAL(wp) :: zrhos, zalbet, zbeta, zthermal, zhalin, zatt1 ! REAL(wp) :: zref, zt, zs, zh, zu, zv, zrh ! Bulk richardson number REAL(wp) :: zrib, zrinum, zdVsq, zVtsq ! REAL(wp) :: zehat, zeta, zhrib, zsig, zscale, zwst, zws, zwm ! Velocity scales #if defined key_kpplktb INTEGER :: il, jl ! Lookup table or Analytical functions REAL(wp) :: ud, zfrac, ufrac, zwam, zwbm, zwas, zwbs ! #else REAL(wp) :: zwsun, zwmun, zcons, zconm, zwcons, zwconm ! #endif REAL(wp) :: zsr, zbw, ze, zb, zd, zc, zaw, za, zb1, za1, zkw, zk0, zcomp , zrhd,zrhdr,zbvzed ! In situ density #if ! defined key_kppcustom INTEGER :: jm ! dummy loop indices REAL(wp) :: zr1, zr2, zr3, zr4, zrhop ! Compression terms #endif REAL(wp) :: zflag, ztemp, zrn2, zdep21, zdep32, zdep43 REAL(wp) :: zdku2, zdkv2, ze3sqr, zsh2, zri, zfri ! Interior richardson mixing REAL(wp), POINTER, DIMENSION(:,:) :: zmoek ! Moning-Obukov limitation REAL(wp), POINTER, DIMENSION(:) :: zmoa, zekman REAL(wp) :: zmob, zek REAL(wp), POINTER, DIMENSION(:,:) :: zdepw, zdift, zvisc ! The pipe REAL(wp), POINTER, DIMENSION(:,:) :: zdept REAL(wp), POINTER, DIMENSION(:,:) :: zriblk REAL(wp), POINTER, DIMENSION(:) :: zhmax, zria, zhbl REAL(wp) :: zflagri, zflagek, zflagmo, zflagh, zflagkb ! REAL(wp), POINTER, DIMENSION(:) :: za2m, za3m, zkmpm, za2t, za3t, zkmpt ! Shape function (G) REAL(wp) :: zdelta, zdelta2, zdzup, zdzdn, zdzh, zvath, zgat1, zdat1, zkm1m, zkm1t #if defined key_zdfddm REAL(wp) :: zrw, zkm1s ! local scalars REAL(wp) :: zrrau, zdt, zds, zavdds, zavddt, zinr ! double diffusion mixing REAL(wp), POINTER, DIMENSION(:,:) :: zdifs REAL(wp), POINTER, DIMENSION(:) :: za2s, za3s, zkmps REAL(wp), POINTER, DIMENSION(:,:) :: zblcs REAL(wp), POINTER, DIMENSION(:,:,:) :: zdiffus #endif REAL(wp), POINTER, DIMENSION(:,:) :: zBo, zBosol, zustar ! Surface buoyancy forcing, friction velocity REAL(wp), POINTER, DIMENSION(:,:) :: zmask, zblcm, zblct !!-------------------------------------------------------------------- ! IF( nn_timing == 1 ) CALL timing_start('zdf_kpp') ! CALL wrk_alloc( jpi, zmoa, zekman, zhmax, zria, zhbl ) CALL wrk_alloc( jpi, za2m, za3m, zkmpm, za2t, za3t, zkmpt ) CALL wrk_alloc( jpi,2, zriblk ) CALL wrk_alloc( jpi,3, zmoek, kjstart = 0 ) CALL wrk_alloc( jpi,3, zdept ) CALL wrk_alloc( jpi,4, zdepw, zdift, zvisc ) CALL wrk_alloc( jpi,jpj, zBo, zBosol, zustar ) CALL wrk_alloc( jpi,jpk, zmask, zblcm, zblct ) #if defined key_zdfddm CALL wrk_alloc( jpi,4, zdifs ) CALL wrk_alloc( jpi, zmoa, za2s, za3s, zkmps ) CALL wrk_alloc( jpi,jpk, zblcs ) CALL wrk_alloc( jpi,jpi,jpk, zdiffus ) #endif zviscos(:,:,:) = 0._wp zblcm (:,: ) = 0._wp zdiffut(:,:,:) = 0._wp zblct (:,: ) = 0._wp #if defined key_zdfddm zdiffus(:,:,:) = 0._wp zblcs (:,: ) = 0._wp #endif ghats (:,:,:) = 0._wp zBo (:,: ) = 0._wp zBosol (:,: ) = 0._wp zustar (:,: ) = 0._wp ! !>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> ! I. Interior diffusivity and viscosity at w points ( T interfaces) !<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<< DO jk = 2, jpkm1 DO jj = 2, jpjm1 DO ji = fs_2, fs_jpim1 ! Mixing due to internal waves breaking ! ------------------------------------- avmu(ji,jj,jk) = rn_difmiw avt (ji,jj,jk) = rn_difsiw ! Mixing due to vertical shear instability ! ------------------------------------- IF( ln_kpprimix ) THEN ! Compute the gradient Richardson number at interfaces (zri): ! LMD94, eq. 27 (is vertical smoothing needed : Rig=N^2 / (dz(u))^2 + (dz(v))^2 zdku2 = ( un(ji - 1,jj,jk - 1) - un(ji - 1,jj,jk) ) & & * ( un(ji - 1,jj,jk - 1) - un(ji - 1,jj,jk) ) & & + ( un(ji ,jj,jk - 1) - un(ji ,jj,jk) ) & & * ( un(ji ,jj,jk - 1) - un(ji ,jj,jk) ) zdkv2 = ( vn(ji,jj - 1,jk - 1) - vn(ji,jj - 1,jk) ) & & * ( vn(ji,jj - 1,jk - 1) - vn(ji,jj - 1,jk) ) & & + ( vn(ji, jj,jk - 1) - vn(ji, jj,jk) ) & & * ( vn(ji, jj,jk - 1) - vn(ji, jj,jk) ) ze3sqr = 1. / ( fse3w(ji,jj,jk) * fse3w(ji,jj,jk) ) ! Square of vertical shear at interfaces zsh2 = 0.5 * ( zdku2 + zdkv2 ) * ze3sqr zri = MAX( rn2(ji,jj,jk), 0. ) / ( zsh2 + epsln ) #if defined key_c1d ! save the gradient richardson number rig(ji,jj,jk) = zri * tmask(ji,jj,jk) #endif ! Evaluate f of Ri (zri) for shear instability store in zfri ! LMD94, eq. 28a,b,c, figure 3 ; Rem: p1 is 3, hard coded zfri = MAX( zri , 0. ) zfri = MIN( zfri / rn_riinfty , 1.0 ) zfri = ( 1.0 - zfri * zfri ) zfri = zfri * zfri * zfri ! add shear contribution to mixing coef. avmu(ji,jj,jk) = avmu(ji,jj,jk) + rn_difri * zfri avt (ji,jj,jk) = avt (ji,jj,jk) + rn_difri * zfri ENDIF ! #if defined key_zdfddm ! ! Double diffusion mixing ; NOT IN ROUTINE ZDFDDM.F90 ! ------------------------- avs (ji,jj,jk) = avt (ji,jj,jk) ! R=zrau = (alpha / beta) (dk[t] / dk[s]) zrw = ( fsdepw(ji,jj,jk ) - fsdept(ji,jj,jk) ) & & / ( fsdept(ji,jj,jk-1) - fsdept(ji,jj,jk) ) ! zaw = ( rab_n(ji,jj,jk,jp_tem) * (1. - zrw) + rab_n(ji,jj,jk-1,jp_tem) * zrw ) * tmask(ji,jj,jk) zbw = ( rab_n(ji,jj,jk,jp_sal) * (1. - zrw) + rab_n(ji,jj,jk-1,jp_sal) * zrw ) * tmask(ji,jj,jk) ! zdt = zaw * ( tsn(ji,jj,jk-1,jp_tem) - tsn(ji,jj,jk,jp_tem) ) zds = zbw * ( tsn(ji,jj,jk-1,jp_sal) - tsn(ji,jj,jk,jp_sal) ) IF( ABS( zds) <= 1.e-20_wp ) zds = 1.e-20_wp zrrau = MAX( epsln , zdt / zds ) ! only retains positive value of zrau ! IF( zrrau > 1. .AND. zds > 0.) THEN ! Salt fingering case. ! !--------------------- ! Compute interior diffusivity for double diffusive mixing of salinity. ! Upper bound "zrrau" by "Rrho0"; (Rrho0=1.9, difcoefnuf=0.001). ! After that set interior diffusivity for double diffusive mixing of temperature zavdds = MIN( zrrau, Rrho0 ) zavdds = ( zavdds - 1.0 ) / ( Rrho0 - 1.0 ) zavdds = 1.0 - zavdds * zavdds zavdds = zavdds * zavdds * zavdds zavdds = difssf * zavdds zavddt = 0.7 * zavdds ! ELSEIF( zrrau < 1. .AND. zrrau > 0. .AND. zds < 0.) THEN ! Diffusive convection case. ! !--------------------------- ! Compute interior diffusivity for double diffusive mixing of temperature (Marmorino and Caldwell, 1976); ! Compute interior diffusivity for double diffusive mixing of salinity zinr = 1. / zrrau zavddt = 0.909 * EXP( 4.6 * EXP( -0.54* ( zinr - 1. ) ) ) zavddt = difsdc * zavddt IF( zrrau < 0.5) THEN ; zavdds = zavddt * 0.15 * zrrau ELSE ; zavdds = zavddt * (1.85 * zrrau - 0.85 ) ENDIF ELSE zavddt = 0. zavdds = 0. ENDIF ! Add double diffusion contribution to temperature and salinity mixing coefficients. avt (ji,jj,jk) = avt (ji,jj,jk) + zavddt avs (ji,jj,jk) = avs (ji,jj,jk) + zavdds #endif END DO END DO END DO ! Radiative (zBosol) and non radiative (zBo) surface buoyancy !JMM at the time zdfkpp is called, q still holds the sum q + qsr !--------------------------------------------------------------------- DO jj = 2, jpjm1 DO ji = fs_2, fs_jpim1 zrhos = rau0 * ( 1._wp + rhd(ji,jj,1) ) * tmask(ji,jj,1) zthermal = rab_n(ji,jj,1,jp_tem) / ( rcp * zrhos + epsln ) zbeta = rab_n(ji,jj,1,jp_sal) zhalin = zbeta * tsn(ji,jj,1,jp_sal) * rcs ! ! Radiative surface buoyancy force zBosol(ji,jj) = grav * zthermal * qsr(ji,jj) ! Non radiative surface buoyancy force zBo (ji,jj) = grav * zthermal * qns(ji,jj) - grav * zhalin * ( emp(ji,jj)-rnf(ji,jj) ) & & - grav * zbeta * rcs * sfx(ji,jj) ! Surface Temperature flux for non-local term wt0(ji,jj) = - ( qsr(ji,jj) + qns(ji,jj) )* r1_rau0_rcp * tmask(ji,jj,1) ! Surface salinity flux for non-local term ws0(ji,jj) = - ( ( emp(ji,jj)-rnf(ji,jj) ) * tsn(ji,jj,1,jp_sal) & & + sfx(ji,jj) ) * rcs * tmask(ji,jj,1) END DO END DO zflageos = 0.5 + SIGN( 0.5, nn_eos - 1. ) ! Compute surface buoyancy forcing, Monin Obukhov and Ekman depths !------------------------------------------------------------------ DO jj = 2, jpjm1 DO ji = fs_2, fs_jpim1 ! Reference surface density = density at first T point level zrhos = rhop(ji,jj,1) + zflageos * rau0 * ( 1. - tmask(ji,jj,1) ) ! Friction velocity (zustar), at T-point : LMD94 eq. 2 zustar(ji,jj) = SQRT( taum(ji,jj) / ( zrhos + epsln ) ) END DO END DO !CDIR NOVERRCHK ! ! =============== DO jj = 2, jpjm1 ! Vertical slab ! ! =============== !>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> ! II Compute Boundary layer mixing coef. and diagnose the new boundary layer depth !<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<< ! Initialization jkmax = 0 zdept (:,:) = 0. zdepw (:,:) = 0. zriblk(:,:) = 0. zmoek (:,:) = 0. zvisc (:,:) = 0. zdift (:,:) = 0. #if defined key_zdfddm zdifs (:,:) = 0. #endif zmask (:,:) = 0. DO ji = fs_2, fs_jpim1 zria(ji ) = 0. ! Maximum boundary layer depth ikbot = mbkt(ji,jj) ! ikbot is the last T point in the water zhmax(ji) = fsdept(ji,jj,ikbot) - 0.001 ! Compute Monin obukhov length scale at the surface and Ekman depth: zbuofdep = zBo(ji,jj) + zBosol(ji,jj) * ratt(1) zekman(ji) = rcekman * zustar(ji,jj) / ( ABS( ff(ji,jj) ) + epsln ) zucube = zustar(ji,jj) * zustar(ji,jj) * zustar(ji,jj) zmoa(ji) = zucube / ( vonk * ( zbuofdep + epsln ) ) #if defined key_c1d ! store the surface buoyancy forcing zstabl = 0.5 + SIGN( 0.5, zbuofdep ) buof(ji,jj,1) = zbuofdep * tmask(ji,jj,1) ! store the moning-oboukov length scale at surface zmob = zstabl * zmoa(ji) + ( 1.0 - zstabl ) * fsdept(ji,jj,1) mols(ji,jj,1) = MIN( zmob , zhmax(ji) ) * tmask(ji,jj,1) ! store Ekman depth zek = zstabl * zekman(ji) + ( 1.0 - zstabl ) * fsdept(ji,jj,1) ekdp(ji,jj ) = MIN( zek , zhmax(ji) ) * tmask(ji,jj,1) #endif END DO ! Compute the pipe ! --------------------- DO jk = 2, jpkm1 DO ji = fs_2, fs_jpim1 ! Compute bfsfc = Bo + radiative contribution down to hbf*depht zbuofdep = zBo(ji,jj) + zBosol(ji,jj) * ratt(jk) ! Flag (zstabl = 1) if positive forcing zstabl = 0.5 + SIGN( 0.5, zbuofdep) ! Compute bulk richardson number zrib at depht !------------------------------------------------------- ! [Br - B(d)] * d zrinum ! Rib(z) = ----------------------- = ------------- ! |Vr - V(d)|^2 + Vt(d)^2 zdVsq + zVtsq ! ! First compute zt,zs,zu,zv = means in the surface layer < epsilon*depht ! Else surface values are taken at the first T level. ! For stability, resolved vertical shear is computed with "before velocities". zref = epsilon * fsdept(ji,jj,jk) #if defined key_kppcustom ! zref = gdept(1) zref = fsdept(ji,jj,1) zt = tsn(ji,jj,1,jp_tem) zs = tsn(ji,jj,1,jp_sal) zrh = rhop(ji,jj,1) zu = ( ub(ji,jj,1) + ub(ji - 1,jj ,1) ) / MAX( 1. , umask(ji,jj,1) + umask(ji - 1,jj ,1) ) zv = ( vb(ji,jj,1) + vb(ji ,jj - 1,1) ) / MAX( 1. , vmask(ji,jj,1) + vmask(ji ,jj - 1,1) ) #else zt = 0. zs = 0. zu = 0. zv = 0. zrh = 0. ! vertically integration over the upper epsilon*gdept(jk) ; del () array is computed once in zdf_kpp_init DO jm = 1, jpkm1 zt = zt + del(jk,jm) * tsn(ji,jj,jm,jp_tem) zs = zs + del(jk,jm) * tsn(ji,jj,jm,jp_sal) zu = zu + 0.5 * del(jk,jm) & & * ( ub(ji,jj,jm) + ub(ji - 1,jj,jm) ) & & / MAX( 1. , umask(ji,jj,jm) + umask(ji - 1,jj,jm) ) zv = zv + 0.5 * del(jk,jm) & & * ( vb(ji,jj,jm) + vb(ji,jj - 1,jm) ) & & / MAX( 1. , vmask(ji,jj,jm) + vmask(ji,jj - 1,jm) ) zrh = zrh + del(jk,jm) * rhop(ji,jj,jm) END DO #endif zsr = SQRT( ABS( tsn(ji,jj,jk,jp_sal) ) ) ! depth zh = fsdept(ji,jj,jk) ! compute compression terms on density ze = ( -3.508914e-8*zt-1.248266e-8 ) *zt-2.595994e-6 zbw = ( 1.296821e-6*zt-5.782165e-9 ) *zt+1.045941e-4 zb = zbw + ze * zs zd = -2.042967e-2 zc = (-7.267926e-5*zt+2.598241e-3 ) *zt+0.1571896 zaw = ( ( 5.939910e-6*zt+2.512549e-3 ) *zt-0.1028859 ) *zt - 4.721788 za = ( zd*zsr + zc ) *zs + zaw zb1 = (-0.1909078*zt+7.390729 ) *zt-55.87545 za1 = ( ( 2.326469e-3*zt+1.553190)*zt-65.00517 ) *zt+1044.077 zkw = ( ( (-1.361629e-4*zt-1.852732e-2 ) *zt-30.41638 ) *zt + 2098.925 ) *zt+190925.6 zk0 = ( zb1*zsr + za1 )*zs + zkw zcomp = 1.0 - zh / ( zk0 - zh * ( za - zh * zb ) ) #if defined key_kppcustom ! potential density of water(zrh = zt,zs at level jk): zrhdr = zrh / zcomp #else ! potential density of water(ztref,zsref at level jk): ! compute volumic mass pure water at atm pressure IF ( nn_eos < 1 ) THEN zr1= ( ( ( ( 6.536332e-9*zt-1.120083e-6 )*zt+1.001685e-4)*zt & & -9.095290e-3 )*zt+6.793952e-2 )*zt+999.842594 ! seawater volumic mass atm pressure zr2= ( ( ( 5.3875e-9*zt-8.2467e-7 ) *zt+7.6438e-5 ) *zt & & -4.0899e-3 ) *zt+0.824493 zr3= ( -1.6546e-6*zt+1.0227e-4 ) *zt-5.72466e-3 zr4= 4.8314e-4 ! potential volumic mass (reference to the surface) zrhop= ( zr4*zs + zr3*zsr + zr2 ) *zs + zr1 zrhdr = zrhop / zcomp ELSE zrhdr = zrh / zcomp ENDIF #endif ! potential density of ambiant water at level jk : zrhd = ( rhd(ji,jj,jk) * rau0 + rau0 ) ! And now the Rib number numerator . zrinum = grav * ( zrhd - zrhdr ) / rau0 zrinum = zrinum * ( fsdept(ji,jj,jk) - zref ) * tmask(ji,jj,jk) ! Resolved shear contribution to Rib at depth T-point (zdVsq) ztx = ( ub( ji , jj ,jk) + ub(ji - 1, jj ,jk) ) & & / MAX( 1. , umask( ji , jj ,jk) + umask(ji - 1, jj ,jk) ) zty = ( vb( ji , jj ,jk) + vb(ji ,jj - 1,jk) ) & & / MAX( 1., vmask( ji , jj ,jk) + vmask(ji ,jj - 1,jk) ) zdVsq = ( zu - ztx ) * ( zu - ztx ) + ( zv - zty ) * ( zv - zty ) ! Scalar turbulent velocity scale zws for hbl=gdept zscale = zstabl + ( 1.0 - zstabl ) * epsilon zehat = vonk * zscale * fsdept(ji,jj,jk) * zbuofdep zucube = zustar(ji,jj) * zustar(ji,jj) * zustar(ji,jj) zeta = zehat / ( zucube + epsln ) IF( zehat > 0. ) THEN ! Stable case zws = vonk * zustar(ji,jj) / ( 1.0 + rconc1 * zeta ) ELSE ! Unstable case #if defined key_kpplktb ! use lookup table zd = zehat - dehatmin il = INT( zd / dezehat ) il = MIN( il, nilktbm1 ) il = MAX( il, 1 ) ud = zustar(ji,jj) - ustmin jl = INT( ud / deustar ) jl = MIN( jl, njlktbm1 ) jl = MAX( jl, 1 ) zfrac = zd / dezehat - FLOAT( il ) ufrac = ud / deustar - FLOAT( jl ) zwas = ( 1. - zfrac ) * wslktb(il,jl+1) + zfrac * wslktb(il+1,jl+1) zwbs = ( 1. - zfrac ) * wslktb(il,jl ) + zfrac * wslktb(il+1,jl ) ! zws = ( 1. - ufrac ) * zwbs + ufrac * zwas #else ! use analytical functions: zcons = 0.5 + SIGN( 0.5 , ( rzetas - zeta ) ) zwcons = vonk * zustar(ji,jj) * ( ( ABS( rconas - rconcs * zeta ) )**pthird ) zwsun = vonk * zustar(ji,jj) * SQRT( ABS ( 1.0 - rconc2 * zeta ) ) ! zws = zcons * zwcons + ( 1.0 - zcons) * zwsun #endif ENDIF ! Turbulent shear contribution to Rib (zVtsq) bv frequency at levels ( ie T-point jk) zrn2 = 0.5 * ( rn2(ji,jj,jk) + rn2(ji,jj,jk+1) ) zbvzed = SQRT( ABS( zrn2 ) ) zVtsq = fsdept(ji,jj,jk) * zws * zbvzed * Vtc ! Finally, the bulk Richardson number at depth fsdept(i,j,k) zrib = zrinum / ( zdVsq + zVtsq + epsln ) ! Find subscripts around the boundary layer depth, build the pipe ! ---------------------------------------------------------------- ! Flag (zflagri = 1) if zrib < Ricr zflagri = 0.5 + SIGN( 0.5, ( Ricr - zrib ) ) ! Flag (zflagh = 1) if still within overall boundary layer zflagh = 0.5 + SIGN( 0.5, ( fsdept(ji,jj,1) - zdept(ji,2) ) ) ! Ekman layer depth zek = zstabl * zekman(ji) + ( 1.0 - zstabl ) * zhmax(ji) zflag = 0.5 + SIGN( 0.5, ( zek - fsdept(ji,jj,jk-1) ) ) zek = zflag * zek + ( 1.0 - zflag ) * zhmax(ji) zflagek = 0.5 + SIGN( 0.5, ( zek - fsdept(ji,jj,jk) ) ) ! Flag (zflagmo = 1) if still within stable Monin-Obukhov and in water zmob = zucube / ( vonk * ( zbuofdep + epsln ) ) ztemp = zstabl * zmob + ( 1.0 - zstabl) * zhmax(ji) ztemp = MIN( ztemp , zhmax(ji) ) zflagmo = 0.5 + SIGN( 0.5, ( ztemp - fsdept(ji,jj,jk) ) ) ! No limitation by Monin Obukhov or Ekman depths: ! zflagek = 1.0 ! zflagmo = 0.5 + SIGN( 0.5, ( zhmax(ji) - fsdept(ji,jj,jk) ) ) ! Load pipe via zflagkb for later calculations ! Flag (zflagkb = 1) if zflagh = 1 and (zflagri = 0 or zflagek = 0 or zflagmo = 0) zflagkb = zflagh * ( 1.0 - ( zflagri * zflagek * zflagmo ) ) zmask(ji,jk) = zflagh jkp2 = MIN( jk+2 , ikbot ) jkm1 = MAX( jk-1 , 2 ) jkmax = MAX( jkmax, jk * INT( REAL( zflagh+epsln ) ) ) zdept(ji,1) = zdept(ji,1) + zflagkb * fsdept(ji,jj,jk-1) zdept(ji,2) = zdept(ji,2) + zflagkb * fsdept(ji,jj,jk ) zdept(ji,3) = zdept(ji,3) + zflagkb * fsdept(ji,jj,jk+1) zdepw(ji,1) = zdepw(ji,1) + zflagkb * fsdepw(ji,jj,jk-1) zdepw(ji,2) = zdepw(ji,2) + zflagkb * fsdepw(ji,jj,jk ) zdepw(ji,3) = zdepw(ji,3) + zflagkb * fsdepw(ji,jj,jk+1) zdepw(ji,4) = zdepw(ji,4) + zflagkb * fsdepw(ji,jj,jkp2) zriblk(ji,1) = zriblk(ji,1) + zflagkb * zria(ji) zriblk(ji,2) = zriblk(ji,2) + zflagkb * zrib zmoek (ji,0) = zmoek (ji,0) + zflagkb * zek zmoek (ji,1) = zmoek (ji,1) + zflagkb * zmoa(ji) zmoek (ji,2) = zmoek (ji,2) + zflagkb * ztemp ! Save Monin Obukhov depth zmoa (ji) = zmob zvisc(ji,1) = zvisc(ji,1) + zflagkb * avmu(ji,jj,jkm1) zvisc(ji,2) = zvisc(ji,2) + zflagkb * avmu(ji,jj,jk ) zvisc(ji,3) = zvisc(ji,3) + zflagkb * avmu(ji,jj,jk+1) zvisc(ji,4) = zvisc(ji,4) + zflagkb * avmu(ji,jj,jkp2) zdift(ji,1) = zdift(ji,1) + zflagkb * avt (ji,jj,jkm1) zdift(ji,2) = zdift(ji,2) + zflagkb * avt (ji,jj,jk ) zdift(ji,3) = zdift(ji,3) + zflagkb * avt (ji,jj,jk+1) zdift(ji,4) = zdift(ji,4) + zflagkb * avt (ji,jj,jkp2) #if defined key_zdfddm zdifs(ji,1) = zdifs(ji,1) + zflagkb * avs (ji,jj,jkm1) zdifs(ji,2) = zdifs(ji,2) + zflagkb * avs (ji,jj,jk ) zdifs(ji,3) = zdifs(ji,3) + zflagkb * avs (ji,jj,jk+1) zdifs(ji,4) = zdifs(ji,4) + zflagkb * avs (ji,jj,jkp2) #endif ! Save the Richardson number zria (ji) = zrib #if defined key_c1d ! store buoyancy length scale buof(ji,jj,jk) = zbuofdep * tmask(ji,jj,jk) ! store Monin Obukhov zmob = zstabl * zmob + ( 1.0 - zstabl) * fsdept(ji,jj,1) mols(ji,jj,jk) = MIN( zmob , zhmax(ji) ) * tmask(ji,jj,jk) ! Bulk Richardson number rib(ji,jj,jk) = zrib * tmask(ji,jj,jk) #endif END DO END DO !>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> ! III PROCESS THE PIPE !<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<< DO ji = fs_2, fs_jpim1 ! Find the boundary layer depth zhbl ! ---------------------------------------- ! Interpolate monin Obukhov and critical Ri mumber depths ztemp = zdept(ji,2) - zdept(ji,1) zflag = ( Ricr - zriblk(ji,1) ) / ( zriblk(ji,2) - zriblk(ji,1) + epsln ) zhrib = zdept(ji,1) + zflag * ztemp IF( zriblk(ji,2) < Ricr ) zhrib = zhmax(ji) IF( zmoek(ji,2) < zdept(ji,2) ) THEN IF ( zmoek(ji,1) < 0. ) THEN zmob = zdept(ji,2) - epsln ELSE zmob = ztemp + zmoek(ji,1) - zmoek(ji,2) zmob = ( zmoek(ji,1) * zdept(ji,2) - zmoek(ji,2) * zdept(ji,1) ) / zmob zmob = MAX( zmob , zdept(ji,1) + epsln ) ENDIF ELSE zmob = zhmax(ji) ENDIF ztemp = MIN( zmob , zmoek(ji,0) ) ! Finally, the boundary layer depth, zhbl zhbl(ji) = MAX( fsdept(ji,jj,1) + epsln, MIN( zhrib , ztemp ) ) ! Save hkpp for further diagnostics (optional) hkpp(ji,jj) = zhbl(ji) * tmask(ji,jj,1) ! Correct mask if zhbl < fsdepw(ji,jj,2) for no viscosity/diffusivity enhancement at fsdepw(ji,jj,2) ! zflag = 1 if zhbl(ji) > fsdepw(ji,jj,2) IF( zhbl(ji) < fsdepw(ji,jj,2) ) zmask(ji,2) = 0. ! Velocity scales at depth zhbl ! ----------------------------------- ! Compute bouyancy forcing down to zhbl ztemp = -hbf * zhbl(ji) zatt1 = 1.0 - ( rabs * EXP( ztemp / xsi1 ) + ( 1.0 - rabs ) * EXP( ztemp / xsi2 ) ) zbuofdep = zBo(ji,jj) + zBosol(ji,jj) * zatt1 zstabl = 0.5 + SIGN( 0.5 , zbuofdep ) zbuofdep = zbuofdep + zstabl * epsln zscale = zstabl + ( 1.0 - zstabl ) * epsilon zehat = vonk * zscale * zhbl(ji) * zbuofdep zucube = zustar(ji,jj) * zustar(ji,jj) * zustar(ji,jj) zeta = zehat / ( zucube + epsln ) IF( zehat > 0. ) THEN ! Stable case zws = vonk * zustar(ji,jj) / ( 1.0 + rconc1 * zeta ) zwm = zws ELSE ! Unstable case #if defined key_kpplktb ! use lookup table zd = zehat - dehatmin il = INT( zd / dezehat ) il = MIN( il, nilktbm1 ) il = MAX( il, 1 ) ud = zustar(ji,jj) - ustmin jl = INT( ud / deustar ) jl = MIN( jl, njlktbm1 ) jl = MAX( jl, 1 ) zfrac = zd / dezehat - FLOAT( il ) ufrac = ud / deustar - FLOAT( jl ) zwas = ( 1. - zfrac ) * wslktb(il,jl+1) + zfrac * wslktb(il+1,jl+1) zwbs = ( 1. - zfrac ) * wslktb(il,jl ) + zfrac * wslktb(il+1,jl ) zwam = ( 1. - zfrac ) * wmlktb(il,jl+1) + zfrac * wmlktb(il+1,jl+1) zwbm = ( 1. - zfrac ) * wmlktb(il,jl ) + zfrac * wmlktb(il+1,jl ) ! zws = ( 1. - ufrac ) * zwbs + ufrac * zwas zwm = ( 1. - ufrac ) * zwbm + ufrac * zwam #else ! use analytical functions zconm = 0.5 + SIGN( 0.5, ( rzetam - zeta) ) zcons = 0.5 + SIGN( 0.5, ( rzetas - zeta) ) ! Momentum : zeta < rzetam (zconm = 1) ! Scalars : zeta < rzetas (zcons = 1) zwconm = zustar(ji,jj) * vonk * ( ( ABS( rconam - rconcm * zeta) )**pthird ) zwcons = zustar(ji,jj) * vonk * ( ( ABS( rconas - rconcs * zeta) )**pthird ) ! Momentum : rzetam <= zeta < 0 (zconm = 0) ! Scalars : rzetas <= zeta < 0 (zcons = 0) zwmun = SQRT( ABS( 1.0 - rconc2 * zeta ) ) zwsun = vonk * zustar(ji,jj) * zwmun zwmun = vonk * zustar(ji,jj) * SQRT(zwmun) ! zwm = zconm * zwconm + ( 1.0 - zconm ) * zwmun zws = zcons * zwcons + ( 1.0 - zcons ) * zwsun #endif ENDIF ! Viscosity, diffusivity values and derivatives at h ! -------------------------------------------------------- ! check between at which interfaces is located zhbl(ji) ! ztemp = 1, zdepw(ji,2) < zhbl < zdepw(ji,3) ! ztemp = 0, zdepw(ji,1) < zhbl < zdepw(ji,2) ztemp = 0.5 + SIGN( 0.5, ( zhbl(ji) - zdepw(ji,2) ) ) zdep21 = zdepw(ji,2) - zdepw(ji,1) + epsln zdep32 = zdepw(ji,3) - zdepw(ji,2) + epsln zdep43 = zdepw(ji,4) - zdepw(ji,3) + epsln ! Compute R as in LMD94, eq D5b zdelta = ( zhbl(ji) - zdepw(ji,2) ) * ztemp / zdep32 & & + ( zhbl(ji) - zdepw(ji,1) ) * ( 1.0 - ztemp ) / zdep21 ! Compute the vertical derivative of viscosities (zdzh) at z=zhbl(ji) zdzup = ( zvisc(ji,2) - zvisc(ji,3) ) * ztemp / zdep32 & & + ( zvisc(ji,1) - zvisc(ji,2) ) * ( 1.0 - ztemp ) / zdep21 zdzdn = ( zvisc(ji,3) - zvisc(ji,4) ) * ztemp / zdep43 & & + ( zvisc(ji,2) - zvisc(ji,3) ) * ( 1.0 - ztemp ) / zdep32 ! LMD94, eq D5b : zdzh = ( 1.0 - zdelta ) * zdzup + zdelta * zdzdn zdzh = MAX( zdzh , 0. ) ! Compute viscosities (zvath) at z=zhbl(ji), LMD94 eq D5a zvath = ztemp * ( zvisc(ji,3) + zdzh * ( zdepw(ji,3) - zhbl(ji) ) ) & & + ( 1.0 - ztemp ) * ( zvisc(ji,2) + zdzh * ( zdepw(ji,2) - zhbl(ji) ) ) ! Compute G (zgat1) and its derivative (zdat1) at z=hbl(ji), LMD94 eq 18 ! Vertical derivative of velocity scale divided by velocity scale squared at z=hbl(ji) ! (non zero only in stable conditions) zflag = -zstabl * rconc1 * zbuofdep / ( zucube * zustar(ji,jj) + epsln ) ! G at its derivative at z=hbl: zgat1 = zvath / ( zhbl(ji) * ( zwm + epsln ) ) zdat1 = -zdzh / ( zwm + epsln ) - zflag * zvath / zhbl(ji) ! G coefficients, LMD94 eq 17 za2m(ji) = -2.0 + 3.0 * zgat1 - zdat1 za3m(ji) = 1.0 - 2.0 * zgat1 + zdat1 ! Compute the vertical derivative of temperature diffusivities (zdzh) at z=zhbl(ji) zdzup = ( zdift(ji,2) - zdift(ji,3) ) * ztemp / zdep32 & & + ( zdift(ji,1) - zdift(ji,2) ) * ( 1.0 - ztemp ) / zdep21 zdzdn = ( zdift(ji,3) - zdift(ji,4) ) * ztemp / zdep43 & & + ( zdift(ji,2) - zdift(ji,3) ) * ( 1.0 - ztemp ) / zdep32 ! LMD94, eq D5b : zdzh = ( 1.0 - zdelta ) * zdzup + zdelta * zdzdn zdzh = MAX( zdzh , 0. ) ! Compute diffusivities (zvath) at z=zhbl(ji), LMD94 eq D5a zvath = ztemp * ( zdift(ji,3) + zdzh * ( zdepw(ji,3) - zhbl(ji) ) ) & & + ( 1.0 - ztemp ) * ( zdift(ji,2) + zdzh * ( zdepw(ji,2) - zhbl(ji) ) ) ! G at its derivative at z=hbl: zgat1 = zvath / ( zhbl(ji) * ( zws + epsln ) ) zdat1 = -zdzh / ( zws + epsln ) - zflag * zvath / zhbl(ji) ! G coefficients, LMD94 eq 17 za2t(ji) = -2.0 + 3.0 * zgat1 - zdat1 za3t(ji) = 1.0 - 2.0 * zgat1 + zdat1 #if defined key_zdfddm ! Compute the vertical derivative of salinities diffusivities (zdzh) at z=zhbl(ji) zdzup = ( zdifs(ji,2) - zdifs(ji,3) ) * ztemp / zdep32 & & + ( zdifs(ji,1) - zdifs(ji,2) ) * ( 1.0 - ztemp ) / zdep21 zdzdn = ( zdifs(ji,3) - zdifs(ji,4) ) * ztemp / zdep43 & & + ( zdifs(ji,2) - zdifs(ji,3) ) * ( 1.0 - ztemp ) / zdep32 ! LMD94, eq D5b : zdzh = ( 1.0 - zdelta ) * zdzup + zdelta * zdzdn zdzh = MAX( zdzh , 0. ) ! Compute diffusivities (zvath) at z=zhbl(ji), LMD94 eq D5a zvath = ztemp * ( zdifs(ji,3) + zdzh * ( zdepw(ji,3) - zhbl(ji) ) ) & & + ( 1.0 - ztemp ) * ( zdifs(ji,2) + zdzh * ( zdepw(ji,2) - zhbl(ji) ) ) ! G at its derivative at z=hbl: zgat1 = zvath / ( zhbl(ji) * ( zws + epsln ) ) zdat1 = -zdzh / ( zws + epsln ) - zflag * zvath / zhbl(ji) ! G coefficients, LMD94 eq 17 za2s(ji) = -2.0 + 3.0 * zgat1 - zdat1 za3s(ji) = 1.0 - 2.0 * zgat1 + zdat1 #endif !-------------------turn off interior matching here------ ! za2(ji,1) = -2.0 ! za3(ji,1) = 1.0 ! za2(ji,2) = -2.0 ! za3(ji,2) = 1.0 !-------------------------------------------------------- ! Compute Enhanced Mixing Coefficients (LMD94,eq D6) ! --------------------------------------------------------------- ! Delta zdelta = ( zhbl(ji) - zdept(ji,1) ) / ( zdept(ji,2) - zdept(ji,1) + epsln ) zdelta2 = zdelta * zdelta ! Mixing coefficients at first level above h (zdept(ji,1)) ! and at first interface in the pipe (zdepw(ji,2)) ! At first T level above h (zdept(ji,1)) (always in the boundary layer) zsig = zdept(ji,1) / zhbl(ji) ztemp = zstabl * zsig + ( 1.0 - zstabl ) * MIN( zsig , epsilon ) zehat = vonk * ztemp * zhbl(ji) * zbuofdep zeta = zehat / ( zucube + epsln) zwst = vonk * zustar(ji,jj) / ( ABS( 1.0 + rconc1 * zeta ) + epsln) zwm = zstabl * zwst + ( 1.0 - zstabl ) * zwm zws = zstabl * zwst + ( 1.0 - zstabl ) * zws zkm1m = zhbl(ji) * zwm * zsig * ( 1.0 + zsig * ( za2m(ji) + zsig * za3m(ji) ) ) zkm1t = zhbl(ji) * zws * zsig * ( 1.0 + zsig * ( za2t(ji) + zsig * za3t(ji) ) ) #if defined key_zdfddm zkm1s = zhbl(ji) * zws * zsig * ( 1.0 + zsig * ( za2s(ji) + zsig * za3s(ji) ) ) #endif ! At first W level in the pipe (zdepw(ji,2)) (not always in the boundary layer ): zsig = MIN( zdepw(ji,2) / zhbl(ji) , 1.0 ) ztemp = zstabl * zsig + ( 1.0 - zstabl ) * MIN( zsig , epsilon ) zehat = vonk * ztemp * zhbl(ji) * zbuofdep zeta = zehat / ( zucube + epsln ) zwst = vonk * zustar(ji,jj) / ( ABS( 1.0 + rconc1 * zeta ) + epsln) zws = zstabl * zws + ( 1.0 - zstabl ) * zws zwm = zstabl * zws + ( 1.0 - zstabl ) * zwm zkmpm(ji) = zhbl(ji) * zwm * zsig * ( 1.0 + zsig * ( za2m(ji) + zsig * za3m(ji) ) ) zkmpt(ji) = zhbl(ji) * zws * zsig * ( 1.0 + zsig * ( za2t(ji) + zsig * za3t(ji) ) ) #if defined key_zdfddm zkmps(ji) = zhbl(ji) * zws * zsig * ( 1.0 + zsig * ( za2s(ji) + zsig * za3s(ji) ) ) #endif ! check if this point is in the boundary layer,else take interior viscosity/diffusivity: zflag = 0.5 + SIGN( 0.5, ( zhbl(ji) - zdepw(ji,2) ) ) zkmpm(ji) = zkmpm(ji) * zflag + ( 1.0 - zflag ) * zvisc(ji,2) zkmpt(ji) = zkmpt(ji) * zflag + ( 1.0 - zflag ) * zdift(ji,2) #if defined key_zdfddm zkmps(ji) = zkmps(ji) * zflag + ( 1.0 - zflag ) * zdifs(ji,2) #endif ! Enhanced viscosity/diffusivity at zdepw(ji,2) ztemp = ( 1.0 - 2.0 * zdelta + zdelta2 ) * zkm1m + zdelta2 * zkmpm(ji) zkmpm(ji) = ( 1.0 - zdelta ) * zvisc(ji,2) + zdelta * ztemp ztemp = ( 1.0 - 2.0 * zdelta + zdelta2 ) * zkm1t + zdelta2 * zkmpt(ji) zkmpt(ji) = ( 1.0 - zdelta ) * zdift(ji,2) + zdelta * ztemp #if defined key_zdfddm ztemp = ( 1.0 - 2.0 * zdelta + zdelta2 ) * zkm1s + zdelta2 * zkmps(ji) zkmps(ji) = ( 1.0 - zdelta ) * zdifs(ji,2) + zdelta * ztemp #endif END DO !>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>> ! IV. Compute vertical eddy viscosity and diffusivity coefficients !<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<< DO jk = 2, jkmax ! Compute turbulent velocity scales on the interfaces ! -------------------------------------------------------- DO ji = fs_2, fs_jpim1 zbuofdep = zBo(ji,jj) + zBosol(ji,jj) * zatt1 zstabl = 0.5 + SIGN( 0.5 , zbuofdep ) zbuofdep = zbuofdep + zstabl * epsln zsig = fsdepw(ji,jj,jk) / zhbl(ji) ztemp = zstabl * zsig + ( 1. - zstabl ) * MIN( zsig , epsilon ) zehat = vonk * ztemp * zhbl(ji) * zbuofdep zucube = zustar(ji,jj) * zustar(ji,jj) * zustar(ji,jj) zeta = zehat / ( zucube + epsln ) IF( zehat > 0. ) THEN ! Stable case zws = vonk * zustar(ji,jj) / ( 1.0 + rconc1 * zeta ) zwm = zws ELSE ! Unstable case #if defined key_kpplktb ! use lookup table zd = zehat - dehatmin il = INT( zd / dezehat ) il = MIN( il, nilktbm1 ) il = MAX( il, 1 ) ud = zustar(ji,jj) - ustmin jl = INT( ud / deustar ) jl = MIN( jl, njlktbm1 ) jl = MAX( jl, 1 ) zfrac = zd / dezehat - FLOAT( il ) ufrac = ud / deustar - FLOAT( jl ) zwas = ( 1. - zfrac ) * wslktb(il,jl+1) + zfrac * wslktb(il+1,jl+1) zwbs = ( 1. - zfrac ) * wslktb(il,jl ) + zfrac * wslktb(il+1,jl ) zwam = ( 1. - zfrac ) * wmlktb(il,jl+1) + zfrac * wmlktb(il+1,jl+1) zwbm = ( 1. - zfrac ) * wmlktb(il,jl ) + zfrac * wmlktb(il+1,jl ) ! zws = ( 1. - ufrac ) * zwbs + ufrac * zwas zwm = ( 1. - ufrac ) * zwbm + ufrac * zwam #else ! use analytical functions zconm = 0.5 + SIGN( 0.5, ( rzetam - zeta) ) zcons = 0.5 + SIGN( 0.5, ( rzetas - zeta) ) ! Momentum : zeta < rzetam (zconm = 1) ! Scalars : zeta < rzetas (zcons = 1) zwconm = zustar(ji,jj) * vonk * ( ( ABS( rconam - rconcm * zeta) )**pthird ) zwcons = zustar(ji,jj) * vonk * ( ( ABS( rconas - rconcs * zeta) )**pthird ) ! Momentum : rzetam <= zeta < 0 (zconm = 0) ! Scalars : rzetas <= zeta < 0 (zcons = 0) zwmun = SQRT( ABS( 1.0 - rconc2 * zeta ) ) zwsun = vonk * zustar(ji,jj) * zwmun zwmun = vonk * zustar(ji,jj) * SQRT(zwmun) ! zwm = zconm * zwconm + ( 1.0 - zconm ) * zwmun zws = zcons * zwcons + ( 1.0 - zcons ) * zwsun #endif ENDIF zblcm(ji,jk) = zhbl(ji) * zwm * zsig * ( 1.0 + zsig * ( za2m(ji) + zsig * za3m(ji) ) ) zblct(ji,jk) = zhbl(ji) * zws * zsig * ( 1.0 + zsig * ( za2t(ji) + zsig * za3t(ji) ) ) #if defined key_zdfddm zblcs(ji,jk) = zhbl(ji) * zws * zsig * ( 1.0 + zsig * ( za2s(ji) + zsig * za3s(ji) ) ) #endif ! Compute Nonlocal transport term = ghats * o ! ---------------------------------------------------- ghats(ji,jj,jk-1) = ( 1. - zstabl ) * rcg / ( zws * zhbl(ji) + epsln ) * tmask(ji,jj,jk) END DO END DO ! Combine interior and boundary layer coefficients and nonlocal term ! ----------------------------------------------------------------------- DO jk = 2, jpkm1 DO ji = fs_2, fs_jpim1 zflag = zmask(ji,jk) * zmask(ji,jk+1) zviscos(ji,jj,jk) = ( 1.0 - zmask(ji,jk) ) * avmu (ji,jj,jk) & ! interior viscosities & + zflag * zblcm(ji,jk ) & ! boundary layer viscosities & + zmask(ji,jk) * ( 1.0 - zflag ) * zkmpm(ji ) ! viscosity enhancement at W_level near zhbl zviscos(ji,jj,jk) = zviscos(ji,jj,jk) * tmask(ji,jj,jk) zdiffut(ji,jj,jk) = ( 1.0 - zmask(ji,jk) ) * avt (ji,jj,jk) & ! interior diffusivities & + zflag * zblct(ji,jk ) & ! boundary layer diffusivities & + zmask(ji,jk) * ( 1.0 - zflag ) * zkmpt(ji ) ! diffusivity enhancement at W_level near zhbl zdiffut(ji,jj,jk) = zdiffut(ji,jj,jk) * tmask(ji,jj,jk) #if defined key_zdfddm zdiffus(ji,jj,jk) = ( 1.0 - zmask(ji,jk) ) * avs (ji,jj,jk) & ! interior diffusivities & + zflag * zblcs(ji,jk ) & ! boundary layer diffusivities & + zmask(ji,jk) * ( 1.0 - zflag ) * zkmps(ji ) ! diffusivity enhancement at W_level near zhbl zdiffus(ji,jj,jk) = zdiffus(ji,jj,jk) * tmask(ji,jj,jk) #endif ! Non local flux in the boundary layer only ghats(ji,jj,jk-1) = zmask(ji,jk) * ghats(ji,jj,jk-1) ENDDO END DO ! ! =============== END DO ! End of slab ! ! =============== ! Lateral boundary conditions on zvicos and zdiffus (sign unchanged) CALL lbc_lnk( zviscos(:,:,:), 'U', 1. ) ; CALL lbc_lnk( zdiffut(:,:,:), 'W', 1. ) #if defined key_zdfddm CALL lbc_lnk( zdiffus(:,:,:), 'W', 1. ) #endif SELECT CASE ( nn_ave ) ! CASE ( 0 ) ! no viscosity and diffusivity smoothing DO jk = 2, jpkm1 DO jj = 2, jpjm1 DO ji = fs_2, fs_jpim1 avmu(ji,jj,jk) = ( zviscos(ji,jj,jk) + zviscos(ji+1,jj,jk) ) & & / MAX( 1., tmask(ji,jj,jk) + tmask (ji + 1,jj,jk) ) * umask(ji,jj,jk) avmv(ji,jj,jk) = ( zviscos(ji,jj,jk) + zviscos(ji,jj+1,jk) ) & & / MAX( 1., tmask(ji,jj,jk) + tmask (ji,jj+1,jk) ) * vmask(ji,jj,jk) avt (ji,jj,jk) = zdiffut(ji,jj,jk) * tmask(ji,jj,jk) #if defined key_zdfddm avs (ji,jj,jk) = zdiffus(ji,jj,jk) * tmask(ji,jj,jk) #endif END DO END DO END DO CASE ( 1 ) ! viscosity and diffusivity smoothing ! ! ( 1/2 1 1/2 ) ( 1/2 1/2 ) ( 1/2 1 1/2 ) ! avt = 1/8 ( 1 2 1 ) avmu = 1/4 ( 1 1 ) avmv= 1/4 ( 1/2 1 1/2 ) ! ( 1/2 1 1/2 ) ( 1/2 1/2 ) DO jk = 2, jpkm1 DO jj = 2, jpjm1 DO ji = fs_2, fs_jpim1 avmu(ji,jj,jk) = ( zviscos(ji ,jj ,jk) + zviscos(ji+1,jj ,jk) & & +.5*( zviscos(ji ,jj-1,jk) + zviscos(ji+1,jj-1,jk) & & +zviscos(ji ,jj+1,jk) + zviscos(ji+1,jj+1,jk) ) ) * eumean(ji,jj,jk) avmv(ji,jj,jk) = ( zviscos(ji ,jj ,jk) + zviscos(ji ,jj+1,jk) & & +.5*( zviscos(ji-1,jj ,jk) + zviscos(ji-1,jj+1,jk) & & +zviscos(ji+1,jj ,jk) + zviscos(ji+1,jj+1,jk) ) ) * evmean(ji,jj,jk) avt (ji,jj,jk) = ( .5*( zdiffut(ji-1,jj+1,jk) + zdiffut(ji-1,jj-1,jk) & & +zdiffut(ji+1,jj+1,jk) + zdiffut(ji+1,jj-1,jk) ) & & +1.*( zdiffut(ji-1,jj ,jk) + zdiffut(ji ,jj+1,jk) & & +zdiffut(ji ,jj-1,jk) + zdiffut(ji+1,jj ,jk) ) & & +2.* zdiffut(ji ,jj ,jk) ) * etmean(ji,jj,jk) #if defined key_zdfddm avs (ji,jj,jk) = ( .5*( zdiffus(ji-1,jj+1,jk) + zdiffus(ji-1,jj-1,jk) & & +zdiffus(ji+1,jj+1,jk) + zdiffus(ji+1,jj-1,jk) ) & & +1.*( zdiffus(ji-1,jj ,jk) + zdiffus(ji ,jj+1,jk) & & +zdiffus(ji ,jj-1,jk) + zdiffus(ji+1,jj ,jk) ) & & +2.* zdiffus(ji ,jj ,jk) ) * etmean(ji,jj,jk) #endif END DO END DO END DO END SELECT DO jk = 2, jpkm1 ! vertical slab ! ! Minimum value on the eddy diffusivity ! ---------------------------------------- DO jj = 2, jpjm1 DO ji = fs_2, fs_jpim1 ! vector opt. avt(ji,jj,jk) = MAX( avt(ji,jj,jk), avtb(jk) ) * tmask(ji,jj,jk) #if defined key_zdfddm avs(ji,jj,jk) = MAX( avs(ji,jj,jk), avtb(jk) ) * tmask(ji,jj,jk) #endif END DO END DO ! ! Minimum value on the eddy viscosity ! ---------------------------------------- DO jj = 1, jpj DO ji = 1, jpi avmu(ji,jj,jk) = MAX( avmu(ji,jj,jk), avmb(jk) ) * umask(ji,jj,jk) avmv(ji,jj,jk) = MAX( avmv(ji,jj,jk), avmb(jk) ) * vmask(ji,jj,jk) END DO END DO ! END DO ! Lateral boundary conditions on avt (sign unchanged) CALL lbc_lnk( hkpp(:,:), 'T', 1. ) ! Lateral boundary conditions on avt (sign unchanged) CALL lbc_lnk( avt(:,:,:), 'W', 1. ) #if defined key_zdfddm CALL lbc_lnk( avs(:,:,:), 'W', 1. ) #endif ! Lateral boundary conditions (avmu,avmv) (U- and V- points, sign unchanged) CALL lbc_lnk( avmu(:,:,:), 'U', 1. ) ; CALL lbc_lnk( avmv(:,:,:), 'V', 1. ) IF(ln_ctl) THEN #if defined key_zdfddm CALL prt_ctl(tab3d_1=avt , clinfo1=' kpp - t: ', tab3d_2=avs , clinfo2=' s: ', ovlap=1, kdim=jpk) #else CALL prt_ctl(tab3d_1=avt , clinfo1=' kpp - t: ', ovlap=1, kdim=jpk) #endif CALL prt_ctl(tab3d_1=avmu, clinfo1=' kpp - u: ', mask1=umask, & & tab3d_2=avmv, clinfo2= ' v: ', mask2=vmask, ovlap=1, kdim=jpk) ENDIF CALL wrk_dealloc( jpi, zmoa, zekman, zhmax, zria, zhbl ) CALL wrk_dealloc( jpi, za2m, za3m, zkmpm, za2t, za3t, zkmpt ) CALL wrk_dealloc( jpi,2, zriblk ) CALL wrk_dealloc( jpi,3, zmoek, kjstart = 0 ) CALL wrk_dealloc( jpi,3, zdept ) CALL wrk_dealloc( jpi,4, zdepw, zdift, zvisc ) CALL wrk_dealloc( jpi,jpj, zBo, zBosol, zustar ) CALL wrk_dealloc( jpi,jpk, zmask, zblcm, zblct ) #if defined key_zdfddm CALL wrk_dealloc( jpi,4, zdifs ) CALL wrk_dealloc( jpi, zmoa, za2s, za3s, zkmps ) CALL wrk_dealloc( jpi,jpk, zblcs ) CALL wrk_dealloc( jpi,jpi,jpk, zdiffus ) #endif ! IF( nn_timing == 1 ) CALL timing_stop('zdf_kpp') ! END SUBROUTINE zdf_kpp SUBROUTINE tra_kpp( kt ) !!---------------------------------------------------------------------- !! *** ROUTINE tra_kpp *** !! !! ** Purpose : compute and add to the tracer trend the non-local tracer flux !! !! ** Method : ??? !!---------------------------------------------------------------------- REAL(wp), DIMENSION(:,:,:), ALLOCATABLE :: ztrdt, ztrds ! 3D workspace !!---------------------------------------------------------------------- INTEGER, INTENT(in) :: kt INTEGER :: ji, jj, jk ! IF( nn_timing == 1 ) CALL timing_start('tra_kpp') ! IF( kt == nit000 ) THEN IF(lwp) WRITE(numout,*) IF(lwp) WRITE(numout,*) 'tra_kpp : KPP non-local tracer fluxes' IF(lwp) WRITE(numout,*) '~~~~~~~ ' ENDIF IF( l_trdtra ) THEN !* Save ta and sa trends ALLOCATE( ztrdt(jpi,jpj,jpk) ) ; ztrdt(:,:,:) = tsa(:,:,:,jp_tem) ALLOCATE( ztrds(jpi,jpj,jpk) ) ; ztrds(:,:,:) = tsa(:,:,:,jp_sal) ENDIF ! add non-local temperature and salinity flux ( in convective case only) DO jk = 1, jpkm1 DO jj = 2, jpjm1 DO ji = fs_2, fs_jpim1 tsa(ji,jj,jk,jp_tem) = tsa(ji,jj,jk,jp_tem) & & - ( ghats(ji,jj,jk ) * avt (ji,jj,jk ) & & - ghats(ji,jj,jk+1) * avt (ji,jj,jk+1) ) * wt0(ji,jj) / fse3t(ji,jj,jk) tsa(ji,jj,jk,jp_sal) = tsa(ji,jj,jk,jp_sal) & & - ( ghats(ji,jj,jk ) * fsavs(ji,jj,jk ) & & - ghats(ji,jj,jk+1) * fsavs(ji,jj,jk+1) ) * ws0(ji,jj) / fse3t(ji,jj,jk) END DO END DO END DO ! save the non-local tracer flux trends for diagnostic IF( l_trdtra ) THEN ztrdt(:,:,:) = tsa(:,:,:,jp_tem) - ztrdt(:,:,:) ztrds(:,:,:) = tsa(:,:,:,jp_sal) - ztrds(:,:,:) !!bug gm jpttdzdf ==> jpttkpp CALL trd_tra( kt, 'TRA', jp_tem, jptra_zdf, ztrdt ) CALL trd_tra( kt, 'TRA', jp_sal, jptra_zdf, ztrds ) DEALLOCATE( ztrdt ) ; DEALLOCATE( ztrds ) ENDIF IF(ln_ctl) THEN CALL prt_ctl( tab3d_1=tsa(:,:,:,jp_tem), clinfo1=' kpp - Ta: ', mask1=tmask, & & tab3d_2=tsa(:,:,:,jp_sal), clinfo2= ' Sa: ', mask2=tmask, clinfo3='tra' ) ENDIF ! IF( nn_timing == 1 ) CALL timing_stop('tra_kpp') ! END SUBROUTINE tra_kpp #if defined key_top !!---------------------------------------------------------------------- !! 'key_top' TOP models !!---------------------------------------------------------------------- SUBROUTINE trc_kpp( kt ) !!---------------------------------------------------------------------- !! *** ROUTINE trc_kpp *** !! !! ** Purpose : compute and add to the tracer trend the non-local !! tracer flux !! !! ** Method : ??? !! !! history : !! 9.0 ! 2005-11 (G. Madec) Original code !! NEMO 3.3 ! 2010-06 (C. Ethe ) Adapted to passive tracers !!---------------------------------------------------------------------- USE trc USE prtctl_trc ! Print control ! INTEGER, INTENT(in) :: kt ! ocean time-step index ! INTEGER :: ji, jj, jk, jn ! Dummy loop indices CHARACTER (len=35) :: charout REAL(wp) :: ztra, zflx REAL(wp), DIMENSION(:,:,:), ALLOCATABLE :: ztrtrd !!---------------------------------------------------------------------- IF( kt == nit000 ) THEN IF(lwp) WRITE(numout,*) IF(lwp) WRITE(numout,*) 'trc_kpp : KPP non-local tracer fluxes' IF(lwp) WRITE(numout,*) '~~~~~~~ ' ENDIF IF( l_trdtrc ) ALLOCATE( ztrtrd(jpi,jpj,jpk) ) ! DO jn = 1, jptra ! IF( l_trdtrc ) ztrtrd(:,:,:) = tra(:,:,:,jn) ! add non-local on passive tracer flux ( in convective case only) DO jk = 1, jpkm1 DO jj = 2, jpjm1 DO ji = fs_2, fs_jpim1 ! Surface tracer flux for non-local term zflx = - ( sfx (ji,jj) * tra(ji,jj,1,jn) * rcs ) * tmask(ji,jj,1) ! compute the trend ztra = - ( ghats(ji,jj,jk ) * fsavs(ji,jj,jk ) & & - ghats(ji,jj,jk+1) * fsavs(ji,jj,jk+1) ) * zflx / fse3t(ji,jj,jk) ! add the trend to the general trend tra(ji,jj,jk,jn) = tra(ji,jj,jk,jn) + ztra END DO END DO END DO ! IF( l_trdtrc ) THEN ! save the non-local tracer flux trends for diagnostic ztrtrd(:,:,:) = tra(:,:,:,jn) - ztrtrd(:,:,:) CALL trd_tra( kt, 'TRC', jn, jptra_zdf, ztrtrd(:,:,:) ) ENDIF ! END DO IF( l_trdtrc ) DEALLOCATE( ztrtrd ) IF( ln_ctl ) THEN WRITE(charout, FMT="(' kpp')") ; CALL prt_ctl_trc_info(charout) CALL prt_ctl_trc( tab4d=tra, mask=tmask, clinfo=ctrcnm, clinfo2='trd' ) ENDIF ! END SUBROUTINE trc_kpp #else !!---------------------------------------------------------------------- !! NO 'key_top' DUMMY routine No TOP models !!---------------------------------------------------------------------- SUBROUTINE trc_kpp( kt ) ! Dummy routine INTEGER, INTENT(in) :: kt ! ocean time-step index WRITE(*,*) 'tra_kpp: You should not have seen this print! error?', kt END SUBROUTINE trc_kpp #endif SUBROUTINE zdf_kpp_init !!---------------------------------------------------------------------- !! *** ROUTINE zdf_kpp_init *** !! !! ** Purpose : Initialization of the vertical eddy diffivity and !! viscosity when using a kpp turbulent closure scheme !! !! ** Method : Read the namkpp namelist and check the parameters !! called at the first timestep (nit000) !! !! ** input : Namlist namkpp !!---------------------------------------------------------------------- INTEGER :: ji, jj, jk ! dummy loop indices INTEGER :: ios ! local integer #if ! defined key_kppcustom INTEGER :: jm ! dummy loop indices REAL(wp) :: zref, zdist ! tempory scalars #endif #if defined key_kpplktb REAL(wp) :: zustar, zucube, zustvk, zeta, zehat ! tempory scalars #endif REAL(wp) :: zhbf ! tempory scalars LOGICAL :: ll_kppcustom ! 1st ocean level taken as surface layer LOGICAL :: ll_kpplktb ! Lookup table for turbul. velocity scales !! NAMELIST/namzdf_kpp/ ln_kpprimix, rn_difmiw, rn_difsiw, rn_riinfty, rn_difri, rn_bvsqcon, rn_difcon, nn_ave !!---------------------------------------------------------------------- ! IF( nn_timing == 1 ) CALL timing_start('zdf_kpp_init') ! REWIND( numnam_ref ) ! Namelist namzdf_kpp in reference namelist : Vertical eddy diffivity and viscosity using kpp turbulent closure scheme READ ( numnam_ref, namzdf_kpp, IOSTAT = ios, ERR = 901) 901 IF( ios /= 0 ) CALL ctl_nam ( ios , 'namzdf_kpp in reference namelist', lwp ) REWIND( numnam_cfg ) ! Namelist namzdf_kpp in configuration namelist : Vertical eddy diffivity and viscosity using kpp turbulent closure scheme READ ( numnam_cfg, namzdf_kpp, IOSTAT = ios, ERR = 902 ) 902 IF( ios /= 0 ) CALL ctl_nam ( ios , 'namzdf_kpp in configuration namelist', lwp ) IF(lwm) WRITE ( numond, namzdf_kpp ) IF(lwp) THEN ! Control print WRITE(numout,*) WRITE(numout,*) 'zdf_kpp_init : K-Profile Parameterisation' WRITE(numout,*) '~~~~~~~~~~~~' WRITE(numout,*) ' Namelist namzdf_kpp : set tke mixing parameters' WRITE(numout,*) ' Shear instability mixing ln_kpprimix = ', ln_kpprimix WRITE(numout,*) ' max. internal wave viscosity rn_difmiw = ', rn_difmiw WRITE(numout,*) ' max. internal wave diffusivity rn_difsiw = ', rn_difsiw WRITE(numout,*) ' Richardson Number limit for shear instability rn_riinfty = ', rn_riinfty WRITE(numout,*) ' max. shear mixing at Rig = 0 rn_difri = ', rn_difri WRITE(numout,*) ' Brunt-Vaisala squared for max. convection rn_bvsqcon = ', rn_bvsqcon WRITE(numout,*) ' max. mix. in interior convec. rn_difcon = ', rn_difcon WRITE(numout,*) ' horizontal average flag nn_ave = ', nn_ave ENDIF ! ! allocate zdfkpp arrays IF( zdf_kpp_alloc() /= 0 ) CALL ctl_stop( 'STOP', 'zdf_kpp_init : unable to allocate arrays' ) ll_kppcustom = .FALSE. ll_kpplktb = .FALSE. #if defined key_kppcustom ll_kppcustom = .TRUE. #endif #if defined key_kpplktb ll_kpplktb = .TRUE. #endif IF(lwp) THEN WRITE(numout,*) ' Lookup table for turbul. velocity scales ll_kpplktb = ', ll_kpplktb WRITE(numout,*) ' 1st ocean level taken as surface layer ll_kppcustom = ', ll_kppcustom ENDIF IF( lk_zdfddm) THEN IF(lwp) THEN WRITE(numout,*) WRITE(numout,*) ' Double diffusion mixing on temperature and salinity ' WRITE(numout,*) ' CAUTION : done in routine zdfkpp, not in routine zdfddm ' ENDIF ENDIF !set constants not in namelist !----------------------------- Vtc = rconcv * SQRT( 0.2 / ( rconcs * epsilon ) ) / ( vonk * vonk * Ricr ) rcg = rcstar * vonk * ( rconcs * vonk * epsilon )**pthird IF(lwp) THEN WRITE(numout,*) WRITE(numout,*) ' Constant value for unreso. turbul. velocity shear Vtc = ', Vtc WRITE(numout,*) ' Non-dimensional coef. for nonlocal transport rcg = ', rcg ENDIF ! ratt is the attenuation coefficient for solar flux ! Should be different is s_coordinate DO jk = 1, jpk zhbf = - fsdept(1,1,jk) * hbf ratt(jk) = 1.0 - ( rabs * EXP( zhbf / xsi1 ) + ( 1.0 - rabs ) * EXP( zhbf / xsi2 ) ) ENDDO ! Horizontal average : initialization of weighting arrays ! ------------------- SELECT CASE ( nn_ave ) CASE ( 0 ) ! no horizontal average IF(lwp) WRITE(numout,*) ' no horizontal average on avt, avmu, avmv' IF(lwp) WRITE(numout,*) ' only in very high horizontal resolution !' ! weighting mean arrays etmean, eumean and evmean ! ( 1 1 ) ( 1 ) ! avt = 1/4 ( 1 1 ) avmu = 1/2 ( 1 1 ) avmv= 1/2 ( 1 ) ! etmean(:,:,:) = 0.e0 eumean(:,:,:) = 0.e0 evmean(:,:,:) = 0.e0 DO jk = 1, jpkm1 DO jj = 2, jpjm1 DO ji = 2, jpim1 ! vector opt. etmean(ji,jj,jk) = tmask(ji,jj,jk) & & / MAX( 1., umask(ji-1,jj ,jk) + umask(ji,jj,jk) & & + vmask(ji ,jj-1,jk) + vmask(ji,jj,jk) ) eumean(ji,jj,jk) = umask(ji,jj,jk) & & / MAX( 1., tmask(ji,jj,jk) + tmask(ji+1,jj ,jk) ) evmean(ji,jj,jk) = vmask(ji,jj,jk) & & / MAX( 1., tmask(ji,jj,jk) + tmask(ji ,jj+1,jk) ) END DO END DO END DO CASE ( 1 ) ! horizontal average IF(lwp) WRITE(numout,*) ' horizontal average on avt, avmu, avmv' ! weighting mean arrays etmean, eumean and evmean ! ( 1/2 1 1/2 ) ( 1/2 1/2 ) ( 1/2 1 1/2 ) ! avt = 1/8 ( 1 2 1 ) avmu = 1/4 ( 1 1 ) avmv= 1/4 ( 1/2 1 1/2 ) ! ( 1/2 1 1/2 ) ( 1/2 1/2 ) etmean(:,:,:) = 0.e0 eumean(:,:,:) = 0.e0 evmean(:,:,:) = 0.e0 DO jk = 1, jpkm1 DO jj = 2, jpjm1 DO ji = fs_2, fs_jpim1 ! vector opt. etmean(ji,jj,jk) = tmask(ji, jj,jk) & & / MAX( 1., 2.* tmask(ji,jj,jk) & & +.5 * ( tmask(ji-1,jj+1,jk) + tmask(ji-1,jj-1,jk) & & +tmask(ji+1,jj+1,jk) + tmask(ji+1,jj-1,jk) ) & & +1. * ( tmask(ji-1,jj ,jk) + tmask(ji ,jj+1,jk) & & +tmask(ji ,jj-1,jk) + tmask(ji+1,jj ,jk) ) ) eumean(ji,jj,jk) = umask(ji,jj,jk) & & / MAX( 1., tmask(ji,jj ,jk) + tmask(ji+1,jj ,jk) & & +.5 * ( tmask(ji,jj-1,jk) + tmask(ji+1,jj-1,jk) & & +tmask(ji,jj+1,jk) + tmask(ji+1,jj+1,jk) ) ) evmean(ji,jj,jk) = vmask(ji,jj,jk) & & / MAX( 1., tmask(ji ,jj,jk) + tmask(ji ,jj+1,jk) & & +.5 * ( tmask(ji-1,jj,jk) + tmask(ji-1,jj+1,jk) & & +tmask(ji+1,jj,jk) + tmask(ji+1,jj+1,jk) ) ) END DO END DO END DO CASE DEFAULT WRITE(ctmp1,*) ' bad flag value for nn_ave = ', nn_ave CALL ctl_stop( ctmp1 ) END SELECT ! Initialization of vertical eddy coef. to the background value ! ------------------------------------------------------------- DO jk = 1, jpk avt (:,:,jk) = avtb(jk) * tmask(:,:,jk) avmu(:,:,jk) = avmb(jk) * umask(:,:,jk) avmv(:,:,jk) = avmb(jk) * vmask(:,:,jk) END DO ! zero the surface flux for non local term and kpp mixed layer depth ! ------------------------------------------------------------------ ghats(:,:,:) = 0. wt0 (:,: ) = 0. ws0 (:,: ) = 0. hkpp (:,: ) = 0. ! just a diagnostic (not essential) #if ! defined key_kppcustom ! compute arrays (del, wz) for reference mean values ! (increase speed for vectorization key_kppcustom not defined) del(1:jpk, 1:jpk) = 0. DO jk = 1, jpk zref = epsilon * fsdept(1,1,jk) DO jm = 1 , jpk zdist = zref - fsdepw(1,1,jm) IF( zdist > 0. ) THEN del(jk,jm) = MIN( zdist, fse3t(1,1,jm) ) / zref ELSE del(jk,jm) = 0. ENDIF ENDDO ENDDO #endif #if defined key_kpplktb ! build lookup table for turbulent velocity scales dezehat = ( dehatmax - dehatmin ) / nilktbm1 deustar = ( ustmax - ustmin ) / njlktbm1 DO jj = 1, njlktb zustar = ( jj - 1) * deustar + ustmin zustvk = vonk * zustar zucube = zustar * zustar * zustar DO ji = 1 , nilktb zehat = ( ji - 1 ) * dezehat + dehatmin zeta = zehat / ( zucube + epsln ) IF( zehat >= 0 ) THEN ! Stable case wmlktb(ji,jj) = zustvk / ABS( 1.0 + rconc1 * zeta + epsln ) wslktb(ji,jj) = wmlktb(ji,jj) ELSE ! Unstable case IF( zeta > rzetam ) THEN wmlktb(ji,jj) = zustvk * ABS( 1.0 - rconc2 * zeta )**pfourth ELSE wmlktb(ji,jj) = zustvk * ABS( rconam - rconcm * zeta )**pthird ENDIF IF( zeta > rzetas ) THEN wslktb(ji,jj) = zustvk * SQRT( ABS( 1.0 - rconc2 * zeta ) ) ELSE wslktb(ji,jj) = zustvk * ABS( rconas - rconcs * zeta )**pthird ENDIF ENDIF END DO END DO #endif ! IF( nn_timing == 1 ) CALL timing_stop('zdf_kpp_init') ! END SUBROUTINE zdf_kpp_init #else !!---------------------------------------------------------------------- !! Dummy module : NO KPP scheme !!---------------------------------------------------------------------- LOGICAL, PUBLIC, PARAMETER :: lk_zdfkpp = .FALSE. !: KPP flag CONTAINS SUBROUTINE zdf_kpp_init ! Dummy routine WRITE(*,*) 'zdf_kpp_init: You should not have seen this print! error?' END SUBROUTINE zdf_kpp_init SUBROUTINE zdf_kpp( kt ) ! Dummy routine WRITE(*,*) 'zdf_kpp: You should not have seen this print! error?', kt END SUBROUTINE zdf_kpp SUBROUTINE tra_kpp( kt ) ! Dummy routine WRITE(*,*) 'tra_kpp: You should not have seen this print! error?', kt END SUBROUTINE tra_kpp SUBROUTINE trc_kpp( kt ) ! Dummy routine WRITE(*,*) 'trc_kpp: You should not have seen this print! error?', kt END SUBROUTINE trc_kpp #endif !!====================================================================== END MODULE zdfkpp