[7990] | 1 | MODULE zdfiwm |
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[1418] | 2 | !!======================================================================== |
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[7990] | 3 | !! *** MODULE zdfiwm *** |
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[7953] | 4 | !! Ocean physics: Internal gravity wave-driven vertical mixing |
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[1418] | 5 | !!======================================================================== |
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| 6 | !! History : 1.0 ! 2004-04 (L. Bessieres, G. Madec) Original code |
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[7953] | 7 | !! - ! 2006-08 (A. Koch-Larrouy) Indonesian strait |
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| 8 | !! 3.3 ! 2010-10 (C. Ethe, G. Madec) reorganisation of initialisation phase |
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| 9 | !! 3.6 ! 2016-03 (C. de Lavergne) New param: internal wave-driven mixing |
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[7990] | 10 | !! 4.0 ! 2017-04 (G. Madec) renamed module, remove the old param. and the CPP keys |
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[1418] | 11 | !!---------------------------------------------------------------------- |
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| 12 | |
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| 13 | !!---------------------------------------------------------------------- |
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[7990] | 14 | !! zdf_iwm : global momentum & tracer Kz with wave induced Kz |
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| 15 | !! zdf_iwm_init : global momentum & tracer Kz with wave induced Kz |
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[6497] | 16 | !!---------------------------------------------------------------------- |
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| 17 | USE oce ! ocean dynamics and tracers variables |
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| 18 | USE dom_oce ! ocean space and time domain variables |
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| 19 | USE zdf_oce ! ocean vertical physics variables |
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| 20 | USE zdfddm ! ocean vertical physics: double diffusive mixing |
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| 21 | USE lbclnk ! ocean lateral boundary conditions (or mpp link) |
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| 22 | USE eosbn2 ! ocean equation of state |
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| 23 | USE phycst ! physical constants |
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| 24 | USE prtctl ! Print control |
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| 25 | USE in_out_manager ! I/O manager |
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| 26 | USE iom ! I/O Manager |
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| 27 | USE lib_mpp ! MPP library |
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| 28 | USE wrk_nemo ! work arrays |
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| 29 | USE timing ! Timing |
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| 30 | USE lib_fortran ! Fortran utilities (allows no signed zero when 'key_nosignedzero' defined) |
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| 31 | |
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| 32 | IMPLICIT NONE |
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| 33 | PRIVATE |
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| 34 | |
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[7990] | 35 | PUBLIC zdf_iwm ! called in step module |
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| 36 | PUBLIC zdf_iwm_init ! called in nemogcm module |
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[6497] | 37 | |
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[7990] | 38 | ! !!* Namelist namzdf_iwm : internal wave-driven mixing * |
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[6497] | 39 | INTEGER :: nn_zpyc ! pycnocline-intensified mixing energy proportional to N (=1) or N^2 (=2) |
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| 40 | LOGICAL :: ln_mevar ! variable (=T) or constant (=F) mixing efficiency |
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| 41 | LOGICAL :: ln_tsdiff ! account for differential T/S wave-driven mixing (=T) or not (=F) |
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| 42 | |
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| 43 | REAL(wp) :: r1_6 = 1._wp / 6._wp |
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| 44 | |
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[7990] | 45 | REAL(wp), ALLOCATABLE, SAVE, DIMENSION(:,:) :: ebot_iwm ! power available from high-mode wave breaking (W/m2) |
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| 46 | REAL(wp), ALLOCATABLE, SAVE, DIMENSION(:,:) :: epyc_iwm ! power available from low-mode, pycnocline-intensified wave breaking (W/m2) |
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| 47 | REAL(wp), ALLOCATABLE, SAVE, DIMENSION(:,:) :: ecri_iwm ! power available from low-mode, critical slope wave breaking (W/m2) |
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| 48 | REAL(wp), ALLOCATABLE, SAVE, DIMENSION(:,:) :: hbot_iwm ! WKB decay scale for high-mode energy dissipation (m) |
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| 49 | REAL(wp), ALLOCATABLE, SAVE, DIMENSION(:,:) :: hcri_iwm ! decay scale for low-mode critical slope dissipation (m) |
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| 50 | REAL(wp), ALLOCATABLE, SAVE, DIMENSION(:,:,:) :: emix_iwm ! local energy density available for mixing (W/kg) |
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| 51 | REAL(wp), ALLOCATABLE, SAVE, DIMENSION(:,:,:) :: bflx_iwm ! buoyancy flux Kz * N^2 (W/kg) |
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| 52 | REAL(wp), ALLOCATABLE, SAVE, DIMENSION(:,:) :: pcmap_iwm ! vertically integrated buoyancy flux (W/m2) |
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[6497] | 53 | REAL(wp), ALLOCATABLE, SAVE, DIMENSION(:,:,:) :: zav_ratio ! S/T diffusivity ratio (only for ln_tsdiff=T) |
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| 54 | REAL(wp), ALLOCATABLE, SAVE, DIMENSION(:,:,:) :: zav_wave ! Internal wave-induced diffusivity |
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| 55 | |
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| 56 | !! * Substitutions |
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[8055] | 57 | # include "domain_substitute.h90" |
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[6497] | 58 | !!---------------------------------------------------------------------- |
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| 59 | !! NEMO/OPA 4.0 , NEMO Consortium (2016) |
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| 60 | !! $Id$ |
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| 61 | !! Software governed by the CeCILL licence (NEMOGCM/NEMO_CeCILL.txt) |
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| 62 | !!---------------------------------------------------------------------- |
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| 63 | CONTAINS |
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| 64 | |
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[7990] | 65 | INTEGER FUNCTION zdf_iwm_alloc() |
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[6497] | 66 | !!---------------------------------------------------------------------- |
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[7990] | 67 | !! *** FUNCTION zdf_iwm_alloc *** |
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[6497] | 68 | !!---------------------------------------------------------------------- |
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[7990] | 69 | ALLOCATE( ebot_iwm(jpi,jpj), epyc_iwm(jpi,jpj), ecri_iwm(jpi,jpj) , & |
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| 70 | & hbot_iwm(jpi,jpj), hcri_iwm(jpi,jpj), emix_iwm(jpi,jpj,jpk), & |
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| 71 | & bflx_iwm(jpi,jpj,jpk), pcmap_iwm(jpi,jpj), zav_ratio(jpi,jpj,jpk), & |
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| 72 | & zav_wave(jpi,jpj,jpk), STAT=zdf_iwm_alloc ) |
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[6497] | 73 | ! |
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[7990] | 74 | IF( lk_mpp ) CALL mpp_sum ( zdf_iwm_alloc ) |
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| 75 | IF( zdf_iwm_alloc /= 0 ) CALL ctl_warn('zdf_iwm_alloc: failed to allocate arrays') |
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| 76 | END FUNCTION zdf_iwm_alloc |
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[6497] | 77 | |
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| 78 | |
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[8055] | 79 | SUBROUTINE zdf_iwm( ARG_2D, kt, p_avm, p_avt, p_avs ) |
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[6497] | 80 | !!---------------------------------------------------------------------- |
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[7990] | 81 | !! *** ROUTINE zdf_iwm *** |
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[6497] | 82 | !! |
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| 83 | !! ** Purpose : add to the vertical mixing coefficients the effect of |
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| 84 | !! breaking internal waves. |
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| 85 | !! |
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| 86 | !! ** Method : - internal wave-driven vertical mixing is given by: |
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[7990] | 87 | !! Kz_wave = min( 100 cm2/s, f( Reb = emix_iwm /( Nu * N^2 ) ) |
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| 88 | !! where emix_iwm is the 3D space distribution of the wave-breaking |
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[6497] | 89 | !! energy and Nu the molecular kinematic viscosity. |
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| 90 | !! The function f(Reb) is linear (constant mixing efficiency) |
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| 91 | !! if the namelist parameter ln_mevar = F and nonlinear if ln_mevar = T. |
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| 92 | !! |
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[7990] | 93 | !! - Compute emix_iwm, the 3D power density that allows to compute |
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[6497] | 94 | !! Reb and therefrom the wave-induced vertical diffusivity. |
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| 95 | !! This is divided into three components: |
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| 96 | !! 1. Bottom-intensified low-mode dissipation at critical slopes |
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[7990] | 97 | !! emix_iwm(z) = ( ecri_iwm / rau0 ) * EXP( -(H-z)/hcri_iwm ) |
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| 98 | !! / ( 1. - EXP( - H/hcri_iwm ) ) * hcri_iwm |
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| 99 | !! where hcri_iwm is the characteristic length scale of the bottom |
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| 100 | !! intensification, ecri_iwm a map of available power, and H the ocean depth. |
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[6497] | 101 | !! 2. Pycnocline-intensified low-mode dissipation |
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[7990] | 102 | !! emix_iwm(z) = ( epyc_iwm / rau0 ) * ( sqrt(rn2(z))^nn_zpyc ) |
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[6497] | 103 | !! / SUM( sqrt(rn2(z))^nn_zpyc * e3w(z) ) |
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[7990] | 104 | !! where epyc_iwm is a map of available power, and nn_zpyc |
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[6497] | 105 | !! is the chosen stratification-dependence of the internal wave |
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| 106 | !! energy dissipation. |
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| 107 | !! 3. WKB-height dependent high mode dissipation |
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[7990] | 108 | !! emix_iwm(z) = ( ebot_iwm / rau0 ) * rn2(z) * EXP(-z_wkb(z)/hbot_iwm) |
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| 109 | !! / SUM( rn2(z) * EXP(-z_wkb(z)/hbot_iwm) * e3w(z) ) |
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| 110 | !! where hbot_iwm is the characteristic length scale of the WKB bottom |
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| 111 | !! intensification, ebot_iwm is a map of available power, and z_wkb is the |
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[6497] | 112 | !! WKB-stretched height above bottom defined as |
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| 113 | !! z_wkb(z) = H * SUM( sqrt(rn2(z'>=z)) * e3w(z'>=z) ) |
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| 114 | !! / SUM( sqrt(rn2(z')) * e3w(z') ) |
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| 115 | !! |
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| 116 | !! - update the model vertical eddy viscosity and diffusivity: |
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| 117 | !! avt = avt + av_wave |
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| 118 | !! avm = avm + av_wave |
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| 119 | !! |
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| 120 | !! - if namelist parameter ln_tsdiff = T, account for differential mixing: |
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| 121 | !! avs = avt + av_wave * diffusivity_ratio(Reb) |
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| 122 | !! |
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[7990] | 123 | !! ** Action : - Define emix_iwm used to compute internal wave-induced mixing |
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| 124 | !! - avt, avs, avm, increased by internal wave-driven mixing |
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[6497] | 125 | !! |
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| 126 | !! References : de Lavergne et al. 2015, JPO; 2016, in prep. |
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| 127 | !!---------------------------------------------------------------------- |
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[8055] | 128 | INTEGER , INTENT(in ) :: ARG_2D ! inner domain start-end i-indices |
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| 129 | INTEGER , INTENT(in ) :: kt ! ocean time step |
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| 130 | REAL(wp), DIMENSION(:,:,:) , INTENT(inout) :: p_avm ! momentum Kz (w-points) |
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| 131 | REAL(wp), DIMENSION(:,:,:) , INTENT(inout) :: p_avt, p_avs ! tracer Kz (w-points) |
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[6497] | 132 | ! |
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| 133 | INTEGER :: ji, jj, jk ! dummy loop indices |
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[8055] | 134 | REAL(wp) :: zztemp ! scalar workspace |
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| 135 | REAL(wp), DIMENSION(WRK_2D) :: zfact ! Used for vertical structure |
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| 136 | REAL(wp), DIMENSION(WRK_2D) :: zhdep ! Ocean depth |
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| 137 | REAL(wp), DIMENSION(WRK_3D) :: zwkb ! WKB-stretched height above bottom |
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| 138 | REAL(wp), DIMENSION(WRK_3D) :: zweight ! Weight for high mode vertical distribution |
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| 139 | REAL(wp), DIMENSION(WRK_3D) :: znu_t ! Molecular kinematic viscosity (T grid) |
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| 140 | REAL(wp), DIMENSION(WRK_3D) :: znu_w ! Molecular kinematic viscosity (W grid) |
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| 141 | REAL(wp), DIMENSION(WRK_3D) :: zReb ! Turbulence intensity parameter |
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[6497] | 142 | !!---------------------------------------------------------------------- |
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| 143 | ! |
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[7990] | 144 | IF( nn_timing == 1 ) CALL timing_start('zdf_iwm') |
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[6497] | 145 | ! |
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| 146 | ! ! ----------------------------- ! |
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| 147 | ! ! Internal wave-driven mixing ! (compute zav_wave) |
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| 148 | ! ! ----------------------------- ! |
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| 149 | ! |
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| 150 | ! !* Critical slope mixing: distribute energy over the time-varying ocean depth, |
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| 151 | ! using an exponential decay from the seafloor. |
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[8055] | 152 | DO jj = k_Jstr, k_Jend |
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| 153 | DO ji = k_Istr, k_Iend ! part independent of the level |
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[6497] | 154 | zhdep(ji,jj) = gdepw_0(ji,jj,mbkt(ji,jj)+1) ! depth of the ocean |
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[7990] | 155 | zfact(ji,jj) = rau0 * ( 1._wp - EXP( -zhdep(ji,jj) / hcri_iwm(ji,jj) ) ) |
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| 156 | IF( zfact(ji,jj) /= 0._wp ) zfact(ji,jj) = ecri_iwm(ji,jj) / zfact(ji,jj) |
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[6497] | 157 | END DO |
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| 158 | END DO |
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[8055] | 159 | DO jk = 2, jpkm1 ! complete with the level-dependent part |
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| 160 | DO jj = k_Jstr, k_Jend |
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| 161 | DO ji = k_Istr, k_Iend |
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| 162 | emix_iwm(ji,jj,jk) = zfact(ji,jj) * wmask(ji,jj,jk) & |
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| 163 | & * ( EXP( ( gde3w_n(ji,jj,jk ) - zhdep(ji,jj) ) / hcri_iwm(ji,jj) ) & |
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| 164 | & - EXP( ( gde3w_n(ji,jj,jk-1) - zhdep(ji,jj) ) / hcri_iwm(ji,jj) ) ) & |
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| 165 | & / ( gde3w_n(ji,jj,jk) - gde3w_n(ji,jj,jk-1) ) |
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[6497] | 166 | |
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[7931] | 167 | !!gm delta(gde3w_n) = e3t_n !! Please verify the grid-point position w versus t-point |
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[8055] | 168 | !!gm it seems to me that only 1/hcri_iwm is used ==> compute it one for all |
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| 169 | |
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| 170 | END DO |
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| 171 | END DO |
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[6497] | 172 | END DO |
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| 173 | |
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| 174 | ! !* Pycnocline-intensified mixing: distribute energy over the time-varying |
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| 175 | ! !* ocean depth as proportional to sqrt(rn2)^nn_zpyc |
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[8055] | 176 | ! ! (NB: N2 is masked, so no use of wmask here) |
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[6497] | 177 | SELECT CASE ( nn_zpyc ) |
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[7990] | 178 | ! |
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[6497] | 179 | CASE ( 1 ) ! Dissipation scales as N (recommended) |
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[7990] | 180 | ! |
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[8055] | 181 | zfact(WRK_2D) = 0._wp ! part independent of the level |
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| 182 | DO jk = 2, jpkm1 |
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| 183 | zfact(WRK_2D) = zfact(WRK_2D) + e3w_n(WRK_2D,jk) * SQRT( MAX( 0._wp, rn2(WRK_2D,jk) ) ) |
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[6497] | 184 | END DO |
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[7990] | 185 | ! |
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[8055] | 186 | WHERE( zfact(WRK_2D) /= 0 ) zfact(WRK_2D) = epyc_iwm(WRK_2D) / ( rau0 * zfact(WRK_2D) ) |
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| 187 | ! DO jj = k_Jstr, k_Jend |
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| 188 | ! DO ji = k_Istr, k_Iend |
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| 189 | ! IF( zfact(ji,jj) /= 0 ) zfact(ji,jj) = epyc_iwm(ji,jj) / ( rau0 * zfact(ji,jj) ) |
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| 190 | ! END DO |
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| 191 | ! END DO |
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| 192 | ! ! complete with the level-dependent part |
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| 193 | DO jk = 2, jpkm1 |
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| 194 | emix_iwm(WRK_2D,jk) = emix_iwm(WRK_2D,jk) + zfact(WRK_2D) * SQRT( MAX( 0._wp, rn2(WRK_2D,jk) ) ) |
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[6497] | 195 | END DO |
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[7990] | 196 | ! |
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[6497] | 197 | CASE ( 2 ) ! Dissipation scales as N^2 |
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[7990] | 198 | ! |
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[8055] | 199 | zfact(WRK_2D) = 0._wp |
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| 200 | DO jk = 2, jpkm1 ! part independent of the level |
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| 201 | zfact(WRK_2D) = zfact(WRK_2D) + e3w_n(WRK_2D,jk) * MAX( 0._wp, rn2(WRK_2D,jk) ) |
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[6497] | 202 | END DO |
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[7990] | 203 | ! |
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[8055] | 204 | WHERE( zfact(WRK_2D) /= 0 ) zfact(WRK_2D) = epyc_iwm(WRK_2D) / ( rau0 * zfact(WRK_2D) ) |
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| 205 | ! DO jj = k_Jstr, k_Jend |
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| 206 | ! DO ji = k_Istr, k_Iend |
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| 207 | ! IF( zfact(ji,jj) /= 0 ) zfact(ji,jj) = epyc_iwm(ji,jj) / ( rau0 * zfact(ji,jj) ) |
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| 208 | ! END DO |
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| 209 | ! END DO |
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[7990] | 210 | ! |
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[6497] | 211 | DO jk = 2, jpkm1 ! complete with the level-dependent part |
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[8055] | 212 | emix_iwm(WRK_2D,jk) = emix_iwm(WRK_2D,jk) + zfact(WRK_2D) * MAX( 0._wp, rn2(WRK_2D,jk) ) |
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[6497] | 213 | END DO |
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[7990] | 214 | ! |
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[6497] | 215 | END SELECT |
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| 216 | |
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| 217 | ! !* WKB-height dependent mixing: distribute energy over the time-varying |
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| 218 | ! !* ocean depth as proportional to rn2 * exp(-z_wkb/rn_hbot) |
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[7990] | 219 | ! |
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[8055] | 220 | zwkb (WRK_3D) = 0._wp |
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| 221 | zfact(WRK_2D) = 0._wp |
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[6497] | 222 | DO jk = 2, jpkm1 |
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[8055] | 223 | !!gm this is potentially dangerous |
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| 224 | ! zfact(WRK_2D) = zfact(WRK_2D) + e3w_n(WRK_2D,jk) * SQRT( MAX( 0._wp, rn2(WRK_2D,jk) ) ) |
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| 225 | ! zwkb (WRK_2D,jk) = zfact(WRK_2D) |
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| 226 | DO jj = k_Jstr, k_Jend |
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| 227 | DO ji = k_Istr, k_Iend |
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| 228 | zztemp = zfact(ji,jj) + e3w_n(ji,jj,jk) * SQRT( MAX( 0._wp, rn2(ji,jj,jk) ) ) |
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| 229 | zfact(ji,jj) = zztemp |
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| 230 | zwkb (ji,jj,jk) = zztemp |
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| 231 | END DO |
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| 232 | END DO |
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[6497] | 233 | END DO |
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[7990] | 234 | ! |
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[6497] | 235 | DO jk = 2, jpkm1 |
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[8055] | 236 | DO jj = k_Jstr, k_Jend |
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| 237 | DO ji = k_Istr, k_Iend |
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[6497] | 238 | IF( zfact(ji,jj) /= 0 ) zwkb(ji,jj,jk) = zhdep(ji,jj) * ( zfact(ji,jj) - zwkb(ji,jj,jk) ) & |
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[8055] | 239 | & * wmask(ji,jj,jk) / zfact(ji,jj) |
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[6497] | 240 | END DO |
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| 241 | END DO |
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| 242 | END DO |
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[8055] | 243 | zwkb(WRK_2D,1) = zhdep(WRK_2D) * wmask(WRK_2D,1) |
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[7990] | 244 | ! |
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[8055] | 245 | zweight(WRK_3D) = 0._wp |
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[6497] | 246 | DO jk = 2, jpkm1 |
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[8055] | 247 | zweight(WRK_2D,jk) = MAX( 0._wp, rn2(WRK_2D,jk) ) * hbot_iwm(:,:) & |
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| 248 | & * ( EXP( -zwkb(WRK_2D,jk ) / hbot_iwm(WRK_2D) ) & |
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| 249 | & - EXP( -zwkb(WRK_2D,jk-1) / hbot_iwm(WRK_2D) ) ) |
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[6497] | 250 | END DO |
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[7990] | 251 | ! |
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[8055] | 252 | zfact(WRK_2D) = 0._wp |
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[6497] | 253 | DO jk = 2, jpkm1 ! part independent of the level |
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[8055] | 254 | zfact(WRK_2D) = zfact(WRK_2D) + zweight(WRK_2D,jk) |
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[6497] | 255 | END DO |
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[7990] | 256 | ! |
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[8055] | 257 | WHERE( zfact(WRK_2D) /= 0 ) zfact(WRK_2D) = ebot_iwm(WRK_2D) / ( rau0 * zfact(WRK_2D) ) |
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| 258 | ! DO jj = k_Jstr, k_Jend |
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| 259 | ! DO ji = k_Istr, k_Iend |
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| 260 | ! IF( zfact(ji,jj) /= 0 ) zfact(ji,jj) = ebot_iwm(ji,jj) / ( rau0 * zfact(ji,jj) ) |
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| 261 | ! END DO |
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| 262 | ! END DO |
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[7990] | 263 | ! |
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[6497] | 264 | DO jk = 2, jpkm1 ! complete with the level-dependent part |
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[8055] | 265 | emix_iwm(WRK_2D,jk) = emix_iwm(WRK_2D,jk) + zweight(WRK_2D,jk) * zfact(WRK_2D) * wmask(WRK_2D,jk) & |
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| 266 | & / ( gde3w_n(WRK_2D,jk) - gde3w_n(WRK_2D,jk-1) ) |
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| 267 | !!gm use of e3t_n just above? |
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[6497] | 268 | END DO |
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[7990] | 269 | ! |
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[8055] | 270 | !!gm this is to be replaced by just a constant value znu=1.e-6 m2/s |
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[6497] | 271 | ! Calculate molecular kinematic viscosity |
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[8055] | 272 | znu_t(WRK_3D) = 1.e-4_wp * ( 17.91_wp - 0.53810_wp * tsn(WRK_3D,jp_tem) & |
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| 273 | & + 0.00694_wp * tsn(WRK_3D,jp_tem) * tsn(WRK_3D,jp_tem) & |
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| 274 | & + 0.02305_wp * tsn(WRK_3D,jp_sal) ) * tmask(WRK_3D) * r1_rau0 |
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[6497] | 275 | DO jk = 2, jpkm1 |
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[8055] | 276 | znu_w(WRK_2D,jk) = 0.5_wp * ( znu_t(WRK_2D,jk-1) + znu_t(WRK_2D,jk) ) * wmask(WRK_2D,jk) |
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[6497] | 277 | END DO |
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[8055] | 278 | !!gm end |
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[7990] | 279 | ! |
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[6497] | 280 | ! Calculate turbulence intensity parameter Reb |
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| 281 | DO jk = 2, jpkm1 |
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[8055] | 282 | zReb(WRK_2D,jk) = emix_iwm(WRK_2D,jk) / MAX( 1.e-20_wp, znu_w(WRK_2D,jk) * rn2(WRK_2D,jk) ) |
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[6497] | 283 | END DO |
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[7990] | 284 | ! |
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[6497] | 285 | ! Define internal wave-induced diffusivity |
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| 286 | DO jk = 2, jpkm1 |
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[8055] | 287 | zav_wave(WRK_2D,jk) = znu_w(WRK_2D,jk) * zReb(WRK_2D,jk) * r1_6 ! This corresponds to a constant mixing efficiency of 1/6 |
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[6497] | 288 | END DO |
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[7990] | 289 | ! |
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[6497] | 290 | IF( ln_mevar ) THEN ! Variable mixing efficiency case : modify zav_wave in the |
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| 291 | DO jk = 2, jpkm1 ! energetic (Reb > 480) and buoyancy-controlled (Reb <10.224 ) regimes |
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[8055] | 292 | DO jj = k_Jstr, k_Jend |
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| 293 | DO ji = k_Istr, k_Iend |
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[6497] | 294 | IF( zReb(ji,jj,jk) > 480.00_wp ) THEN |
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| 295 | zav_wave(ji,jj,jk) = 3.6515_wp * znu_w(ji,jj,jk) * SQRT( zReb(ji,jj,jk) ) |
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| 296 | ELSEIF( zReb(ji,jj,jk) < 10.224_wp ) THEN |
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| 297 | zav_wave(ji,jj,jk) = 0.052125_wp * znu_w(ji,jj,jk) * zReb(ji,jj,jk) * SQRT( zReb(ji,jj,jk) ) |
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| 298 | ENDIF |
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| 299 | END DO |
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| 300 | END DO |
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| 301 | END DO |
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| 302 | ENDIF |
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[7990] | 303 | ! |
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[6497] | 304 | DO jk = 2, jpkm1 ! Bound diffusivity by molecular value and 100 cm2/s |
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[8055] | 305 | zav_wave(WRK_2D,jk) = MIN( MAX( 1.4e-7_wp, zav_wave(WRK_2D,jk) ), 1.e-2_wp ) * wmask(WRK_2D,jk) |
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[6497] | 306 | END DO |
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[7990] | 307 | ! |
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[6497] | 308 | IF( kt == nit000 ) THEN !* Control print at first time-step: diagnose the energy consumed by zav_wave |
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[8055] | 309 | zztemp = 0._wp |
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[7931] | 310 | !!gm used of glosum 3D.... |
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[6497] | 311 | DO jk = 2, jpkm1 |
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[8055] | 312 | DO jj = k_Jstr, k_Jend |
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| 313 | DO ji = k_Istr, k_Iend |
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| 314 | zztemp = zztemp + e3w_n(ji,jj,jk) * e1e2t(ji,jj) & |
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[6497] | 315 | & * MAX( 0._wp, rn2(ji,jj,jk) ) * zav_wave(ji,jj,jk) * wmask(ji,jj,jk) * tmask_i(ji,jj) |
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| 316 | END DO |
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| 317 | END DO |
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| 318 | END DO |
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[8055] | 319 | IF( lk_mpp ) CALL mpp_sum( zztemp ) |
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| 320 | zztemp = rau0 * zztemp ! Global integral of rauo * Kz * N^2 = power contributing to mixing |
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[7990] | 321 | ! |
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[6497] | 322 | IF(lwp) THEN |
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| 323 | WRITE(numout,*) |
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[7990] | 324 | WRITE(numout,*) 'zdf_iwm : Internal wave-driven mixing (iwm)' |
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[6497] | 325 | WRITE(numout,*) '~~~~~~~ ' |
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| 326 | WRITE(numout,*) |
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[8055] | 327 | WRITE(numout,*) ' Total power consumption by av_wave = ', zztemp * 1.e-12_wp, 'TW' |
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[6497] | 328 | ENDIF |
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| 329 | ENDIF |
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| 330 | |
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| 331 | ! ! ----------------------- ! |
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| 332 | ! ! Update mixing coefs ! |
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| 333 | ! ! ----------------------- ! |
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| 334 | ! |
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| 335 | IF( ln_tsdiff ) THEN !* Option for differential mixing of salinity and temperature |
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| 336 | DO jk = 2, jpkm1 ! Calculate S/T diffusivity ratio as a function of Reb |
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[8055] | 337 | DO jj = k_Jstr, k_Jend |
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| 338 | DO ji = k_Istr, k_Iend |
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[6497] | 339 | zav_ratio(ji,jj,jk) = ( 0.505_wp + 0.495_wp * & |
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| 340 | & TANH( 0.92_wp * ( LOG10( MAX( 1.e-20_wp, zReb(ji,jj,jk) * 5._wp * r1_6 ) ) - 0.60_wp ) ) & |
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| 341 | & ) * wmask(ji,jj,jk) |
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| 342 | END DO |
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| 343 | END DO |
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| 344 | END DO |
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[7753] | 345 | CALL iom_put( "av_ratio", zav_ratio ) |
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[6497] | 346 | DO jk = 2, jpkm1 !* update momentum & tracer diffusivity with wave-driven mixing |
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[8055] | 347 | p_avs(WRK_2D,jk) = p_avs(WRK_2D,jk) + zav_wave(WRK_2D,jk) * zav_ratio(WRK_2D,jk) |
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| 348 | p_avt(WRK_2D,jk) = p_avt(WRK_2D,jk) + zav_wave(WRK_2D,jk) |
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| 349 | p_avm(WRK_2D,jk) = p_avm(WRK_2D,jk) + zav_wave(WRK_2D,jk) |
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[6497] | 350 | END DO |
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| 351 | ! |
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| 352 | ELSE !* update momentum & tracer diffusivity with wave-driven mixing |
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| 353 | DO jk = 2, jpkm1 |
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[8055] | 354 | p_avs(WRK_2D,jk) = p_avs(WRK_2D,jk) + zav_wave(WRK_2D,jk) |
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| 355 | p_avt(WRK_2D,jk) = p_avt(WRK_2D,jk) + zav_wave(WRK_2D,jk) |
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| 356 | p_avm(WRK_2D,jk) = p_avm(WRK_2D,jk) + zav_wave(WRK_2D,jk) |
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[6497] | 357 | END DO |
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| 358 | ENDIF |
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| 359 | |
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| 360 | ! !* output internal wave-driven mixing coefficient |
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| 361 | CALL iom_put( "av_wave", zav_wave ) |
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[7990] | 362 | !* output useful diagnostics: N^2, Kz * N^2 (bflx_iwm), |
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| 363 | ! vertical integral of rau0 * Kz * N^2 (pcmap_iwm), energy density (emix_iwm) |
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| 364 | IF( iom_use("bflx_iwm") .OR. iom_use("pcmap_iwm") ) THEN |
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[7753] | 365 | DO jk = 2, jpkm1 |
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[8055] | 366 | bflx_iwm(WRK_2D,jk) = MAX( 0._wp, rn2(WRK_2D,jk) ) * zav_wave(WRK_2D,jk) |
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[6497] | 367 | END DO |
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[8055] | 368 | pcmap_iwm(WRK_2D) = 0._wp |
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| 369 | DO jk = 2, jpkm1 |
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| 370 | pcmap_iwm(WRK_2D) = pcmap_iwm(WRK_2D) + e3w_n(WRK_2D,jk) * bflx_iwm(WRK_2D,jk) |
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| 371 | END DO |
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| 372 | pcmap_iwm(WRK_2D) = rau0 * pcmap_iwm(WRK_2D) |
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| 373 | CALL iom_put( "bflx_iwm" , bflx_iwm ) |
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[7990] | 374 | CALL iom_put( "pcmap_iwm", pcmap_iwm ) |
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[6497] | 375 | ENDIF |
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| 376 | CALL iom_put( "bn2", rn2 ) |
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[7990] | 377 | CALL iom_put( "emix_iwm", emix_iwm ) |
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[6497] | 378 | |
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[7990] | 379 | IF(ln_ctl) CALL prt_ctl(tab3d_1=zav_wave , clinfo1=' iwm - av_wave: ', tab3d_2=avt, clinfo2=' avt: ', ovlap=1, kdim=jpk) |
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[6497] | 380 | ! |
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[7990] | 381 | IF( nn_timing == 1 ) CALL timing_stop('zdf_iwm') |
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[6497] | 382 | ! |
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[7990] | 383 | END SUBROUTINE zdf_iwm |
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[6497] | 384 | |
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| 385 | |
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[7990] | 386 | SUBROUTINE zdf_iwm_init |
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[6497] | 387 | !!---------------------------------------------------------------------- |
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[7990] | 388 | !! *** ROUTINE zdf_iwm_init *** |
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[6497] | 389 | !! |
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| 390 | !! ** Purpose : Initialization of the wave-driven vertical mixing, reading |
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| 391 | !! of input power maps and decay length scales in netcdf files. |
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| 392 | !! |
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[7990] | 393 | !! ** Method : - Read the namzdf_iwm namelist and check the parameters |
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[6497] | 394 | !! |
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| 395 | !! - Read the input data in NetCDF files : |
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| 396 | !! power available from high-mode wave breaking (mixing_power_bot.nc) |
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| 397 | !! power available from pycnocline-intensified wave-breaking (mixing_power_pyc.nc) |
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| 398 | !! power available from critical slope wave-breaking (mixing_power_cri.nc) |
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| 399 | !! WKB decay scale for high-mode wave-breaking (decay_scale_bot.nc) |
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| 400 | !! decay scale for critical slope wave-breaking (decay_scale_cri.nc) |
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| 401 | !! |
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[7990] | 402 | !! ** input : - Namlist namzdf_iwm |
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[6497] | 403 | !! - NetCDF files : mixing_power_bot.nc, mixing_power_pyc.nc, mixing_power_cri.nc, |
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| 404 | !! decay_scale_bot.nc decay_scale_cri.nc |
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| 405 | !! |
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| 406 | !! ** Action : - Increase by 1 the nstop flag is setting problem encounter |
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[7990] | 407 | !! - Define ebot_iwm, epyc_iwm, ecri_iwm, hbot_iwm, hcri_iwm |
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[6497] | 408 | !! |
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[7990] | 409 | !! References : de Lavergne et al. JPO, 2015 ; de Lavergne PhD 2016 |
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| 410 | !! de Lavergne et al. in prep., 2017 |
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[6497] | 411 | !!---------------------------------------------------------------------- |
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| 412 | INTEGER :: ji, jj, jk ! dummy loop indices |
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| 413 | INTEGER :: inum ! local integer |
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| 414 | INTEGER :: ios |
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| 415 | REAL(wp) :: zbot, zpyc, zcri ! local scalars |
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| 416 | !! |
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[7990] | 417 | NAMELIST/namzdf_iwm_new/ nn_zpyc, ln_mevar, ln_tsdiff |
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[6497] | 418 | !!---------------------------------------------------------------------- |
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| 419 | ! |
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[7990] | 420 | IF( nn_timing == 1 ) CALL timing_start('zdf_iwm_init') |
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[6497] | 421 | ! |
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[7990] | 422 | REWIND( numnam_ref ) ! Namelist namzdf_iwm in reference namelist : Wave-driven mixing |
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| 423 | READ ( numnam_ref, namzdf_iwm_new, IOSTAT = ios, ERR = 901) |
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| 424 | 901 IF( ios /= 0 ) CALL ctl_nam ( ios , 'namzdf_iwm in reference namelist', lwp ) |
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[6497] | 425 | ! |
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[7990] | 426 | REWIND( numnam_cfg ) ! Namelist namzdf_iwm in configuration namelist : Wave-driven mixing |
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| 427 | READ ( numnam_cfg, namzdf_iwm_new, IOSTAT = ios, ERR = 902 ) |
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| 428 | 902 IF( ios /= 0 ) CALL ctl_nam ( ios , 'namzdf_iwm in configuration namelist', lwp ) |
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| 429 | IF(lwm) WRITE ( numond, namzdf_iwm_new ) |
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[6497] | 430 | ! |
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| 431 | IF(lwp) THEN ! Control print |
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| 432 | WRITE(numout,*) |
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[7990] | 433 | WRITE(numout,*) 'zdf_iwm_init : internal wave-driven mixing' |
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[6497] | 434 | WRITE(numout,*) '~~~~~~~~~~~~' |
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[7990] | 435 | WRITE(numout,*) ' Namelist namzdf_iwm_new : set wave-driven mixing parameters' |
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[6497] | 436 | WRITE(numout,*) ' Pycnocline-intensified diss. scales as N (=1) or N^2 (=2) = ', nn_zpyc |
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| 437 | WRITE(numout,*) ' Variable (T) or constant (F) mixing efficiency = ', ln_mevar |
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| 438 | WRITE(numout,*) ' Differential internal wave-driven mixing (T) or not (F) = ', ln_tsdiff |
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| 439 | ENDIF |
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| 440 | |
---|
| 441 | ! The new wave-driven mixing parameterization elevates avt and avm in the interior, and |
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| 442 | ! ensures that avt remains larger than its molecular value (=1.4e-7). Therefore, avtb should |
---|
| 443 | ! be set here to a very small value, and avmb to its (uniform) molecular value (=1.4e-6). |
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| 444 | avmb(:) = 1.4e-6_wp ! viscous molecular value |
---|
[7990] | 445 | avtb(:) = 1.e-10_wp ! very small diffusive minimum (background avt is specified in zdf_iwm) |
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[7753] | 446 | avtb_2d(:,:) = 1.e0_wp ! uniform |
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[6497] | 447 | IF(lwp) THEN ! Control print |
---|
| 448 | WRITE(numout,*) |
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| 449 | WRITE(numout,*) ' Force the background value applied to avm & avt in TKE to be everywhere ', & |
---|
| 450 | & 'the viscous molecular value & a very small diffusive value, resp.' |
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| 451 | ENDIF |
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[7931] | 452 | |
---|
[7990] | 453 | ! ! allocate iwm arrays |
---|
| 454 | IF( zdf_iwm_alloc() /= 0 ) CALL ctl_stop( 'STOP', 'zdf_iwm_init : unable to allocate iwm arrays' ) |
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[6497] | 455 | ! |
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| 456 | ! ! read necessary fields |
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| 457 | CALL iom_open('mixing_power_bot',inum) ! energy flux for high-mode wave breaking [W/m2] |
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[7990] | 458 | CALL iom_get (inum, jpdom_data, 'field', ebot_iwm, 1 ) |
---|
[6497] | 459 | CALL iom_close(inum) |
---|
| 460 | ! |
---|
| 461 | CALL iom_open('mixing_power_pyc',inum) ! energy flux for pynocline-intensified wave breaking [W/m2] |
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[7990] | 462 | CALL iom_get (inum, jpdom_data, 'field', epyc_iwm, 1 ) |
---|
[6497] | 463 | CALL iom_close(inum) |
---|
| 464 | ! |
---|
| 465 | CALL iom_open('mixing_power_cri',inum) ! energy flux for critical slope wave breaking [W/m2] |
---|
[7990] | 466 | CALL iom_get (inum, jpdom_data, 'field', ecri_iwm, 1 ) |
---|
[6497] | 467 | CALL iom_close(inum) |
---|
| 468 | ! |
---|
| 469 | CALL iom_open('decay_scale_bot',inum) ! spatially variable decay scale for high-mode wave breaking [m] |
---|
[7990] | 470 | CALL iom_get (inum, jpdom_data, 'field', hbot_iwm, 1 ) |
---|
[6497] | 471 | CALL iom_close(inum) |
---|
| 472 | ! |
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| 473 | CALL iom_open('decay_scale_cri',inum) ! spatially variable decay scale for critical slope wave breaking [m] |
---|
[7990] | 474 | CALL iom_get (inum, jpdom_data, 'field', hcri_iwm, 1 ) |
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[6497] | 475 | CALL iom_close(inum) |
---|
| 476 | |
---|
[7990] | 477 | ebot_iwm(:,:) = ebot_iwm(:,:) * ssmask(:,:) |
---|
| 478 | epyc_iwm(:,:) = epyc_iwm(:,:) * ssmask(:,:) |
---|
| 479 | ecri_iwm(:,:) = ecri_iwm(:,:) * ssmask(:,:) |
---|
[6497] | 480 | |
---|
[7753] | 481 | ! Set once for all to zero the first and last vertical levels of appropriate variables |
---|
[7990] | 482 | emix_iwm (:,:, 1 ) = 0._wp |
---|
| 483 | emix_iwm (:,:,jpk) = 0._wp |
---|
[7753] | 484 | zav_ratio(:,:, 1 ) = 0._wp |
---|
| 485 | zav_ratio(:,:,jpk) = 0._wp |
---|
| 486 | zav_wave (:,:, 1 ) = 0._wp |
---|
| 487 | zav_wave (:,:,jpk) = 0._wp |
---|
| 488 | |
---|
[7990] | 489 | zbot = glob_sum( e1e2t(:,:) * ebot_iwm(:,:) ) |
---|
| 490 | zpyc = glob_sum( e1e2t(:,:) * epyc_iwm(:,:) ) |
---|
| 491 | zcri = glob_sum( e1e2t(:,:) * ecri_iwm(:,:) ) |
---|
[6497] | 492 | IF(lwp) THEN |
---|
| 493 | WRITE(numout,*) ' High-mode wave-breaking energy: ', zbot * 1.e-12_wp, 'TW' |
---|
| 494 | WRITE(numout,*) ' Pycnocline-intensifed wave-breaking energy: ', zpyc * 1.e-12_wp, 'TW' |
---|
| 495 | WRITE(numout,*) ' Critical slope wave-breaking energy: ', zcri * 1.e-12_wp, 'TW' |
---|
| 496 | ENDIF |
---|
| 497 | ! |
---|
[7990] | 498 | IF( nn_timing == 1 ) CALL timing_stop('zdf_iwm_init') |
---|
[6497] | 499 | ! |
---|
[7990] | 500 | END SUBROUTINE zdf_iwm_init |
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[6497] | 501 | |
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[1418] | 502 | !!====================================================================== |
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[7990] | 503 | END MODULE zdfiwm |
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