[6723] | 1 | MODULE sbcblk |
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| 2 | !!====================================================================== |
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| 3 | !! *** MODULE sbcblk *** |
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| 4 | !! Ocean forcing: momentum, heat and freshwater flux formulation |
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| 5 | !! Aerodynamic Bulk Formulas |
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| 6 | !! SUCCESSOR OF "sbcblk_core" |
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| 7 | !!===================================================================== |
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[7163] | 8 | !! History : 1.0 ! 2004-08 (U. Schweckendiek) Original CORE code |
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| 9 | !! 2.0 ! 2005-04 (L. Brodeau, A.M. Treguier) improved CORE bulk and its user interface |
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| 10 | !! 3.0 ! 2006-06 (G. Madec) sbc rewritting |
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| 11 | !! - ! 2006-12 (L. Brodeau) Original code for turb_core |
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[6723] | 12 | !! 3.2 ! 2009-04 (B. Lemaire) Introduce iom_put |
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| 13 | !! 3.3 ! 2010-10 (S. Masson) add diurnal cycle |
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[7163] | 14 | !! 3.4 ! 2011-11 (C. Harris) Fill arrays required by CICE |
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| 15 | !! 3.7 ! 2014-06 (L. Brodeau) simplification and optimization of CORE bulk |
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| 16 | !! 4.0 ! 2016-06 (L. Brodeau) sbcblk_core becomes sbcblk and is not restricted to the CORE algorithm anymore |
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[9019] | 17 | !! ! ==> based on AeroBulk (http://aerobulk.sourceforge.net/) |
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[7163] | 18 | !! 4.0 ! 2016-10 (G. Madec) introduce a sbc_blk_init routine |
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[10534] | 19 | !! 4.0 ! 2016-10 (M. Vancoppenolle) Introduce conduction flux emulator (M. Vancoppenolle) |
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[6723] | 20 | !!---------------------------------------------------------------------- |
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| 21 | |
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| 22 | !!---------------------------------------------------------------------- |
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[7163] | 23 | !! sbc_blk_init : initialisation of the chosen bulk formulation as ocean surface boundary condition |
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| 24 | !! sbc_blk : bulk formulation as ocean surface boundary condition |
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[6727] | 25 | !! blk_oce : computes momentum, heat and freshwater fluxes over ocean |
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| 26 | !! rho_air : density of (moist) air (depends on T_air, q_air and SLP |
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| 27 | !! cp_air : specific heat of (moist) air (depends spec. hum. q_air) |
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| 28 | !! q_sat : saturation humidity as a function of SLP and temperature |
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| 29 | !! L_vap : latent heat of vaporization of water as a function of temperature |
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[9019] | 30 | !! sea-ice case only : |
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| 31 | !! blk_ice_tau : provide the air-ice stress |
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| 32 | !! blk_ice_flx : provide the heat and mass fluxes at air-ice interface |
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[10534] | 33 | !! blk_ice_qcn : provide ice surface temperature and snow/ice conduction flux (emulating conduction flux) |
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[9019] | 34 | !! Cdn10_Lupkes2012 : Lupkes et al. (2012) air-ice drag |
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| 35 | !! Cdn10_Lupkes2015 : Lupkes et al. (2015) air-ice drag |
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[6723] | 36 | !!---------------------------------------------------------------------- |
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| 37 | USE oce ! ocean dynamics and tracers |
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| 38 | USE dom_oce ! ocean space and time domain |
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| 39 | USE phycst ! physical constants |
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| 40 | USE fldread ! read input fields |
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| 41 | USE sbc_oce ! Surface boundary condition: ocean fields |
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[15613] | 42 | USE trc_oce ! share SMS/Ocean variables |
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[6723] | 43 | USE cyclone ! Cyclone 10m wind form trac of cyclone centres |
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| 44 | USE sbcdcy ! surface boundary condition: diurnal cycle |
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| 45 | USE sbcwave , ONLY : cdn_wave ! wave module |
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| 46 | USE sbc_ice ! Surface boundary condition: ice fields |
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| 47 | USE lib_fortran ! to use key_nosignedzero |
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[9570] | 48 | #if defined key_si3 |
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[13284] | 49 | USE ice , ONLY : u_ice, v_ice, jpl, a_i_b, at_i_b, t_su, rn_cnd_s, hfx_err_dif, nn_qtrice |
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| 50 | USE icevar ! for CALL ice_var_snwblow |
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[6723] | 51 | #endif |
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| 52 | USE sbcblk_algo_ncar ! => turb_ncar : NCAR - CORE (Large & Yeager, 2009) |
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| 53 | USE sbcblk_algo_coare ! => turb_coare : COAREv3.0 (Fairall et al. 2003) |
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| 54 | USE sbcblk_algo_coare3p5 ! => turb_coare3p5 : COAREv3.5 (Edson et al. 2013) |
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| 55 | USE sbcblk_algo_ecmwf ! => turb_ecmwf : ECMWF (IFS cycle 31) |
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[6727] | 56 | ! |
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[6723] | 57 | USE iom ! I/O manager library |
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| 58 | USE in_out_manager ! I/O manager |
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| 59 | USE lib_mpp ! distribued memory computing library |
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| 60 | USE lbclnk ! ocean lateral boundary conditions (or mpp link) |
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| 61 | USE prtctl ! Print control |
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| 62 | |
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| 63 | IMPLICIT NONE |
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| 64 | PRIVATE |
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| 65 | |
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[7163] | 66 | PUBLIC sbc_blk_init ! called in sbcmod |
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| 67 | PUBLIC sbc_blk ! called in sbcmod |
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[9570] | 68 | #if defined key_si3 |
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[10535] | 69 | PUBLIC blk_ice_tau ! routine called in icesbc |
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| 70 | PUBLIC blk_ice_flx ! routine called in icesbc |
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| 71 | PUBLIC blk_ice_qcn ! routine called in icesbc |
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[9019] | 72 | #endif |
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[6723] | 73 | |
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[6727] | 74 | !!Lolo: should ultimately be moved in the module with all physical constants ? |
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| 75 | !!gm : In principle, yes. |
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[6723] | 76 | REAL(wp), PARAMETER :: Cp_dry = 1005.0 !: Specic heat of dry air, constant pressure [J/K/kg] |
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| 77 | REAL(wp), PARAMETER :: Cp_vap = 1860.0 !: Specic heat of water vapor, constant pressure [J/K/kg] |
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| 78 | REAL(wp), PARAMETER :: R_dry = 287.05_wp !: Specific gas constant for dry air [J/K/kg] |
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| 79 | REAL(wp), PARAMETER :: R_vap = 461.495_wp !: Specific gas constant for water vapor [J/K/kg] |
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| 80 | REAL(wp), PARAMETER :: reps0 = R_dry/R_vap !: ratio of gas constant for dry air and water vapor => ~ 0.622 |
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[12901] | 81 | REAL(wp), PARAMETER :: rctv0 = R_vap/R_dry - 1._wp !: for virtual temperature (== (1-eps)/eps) => ~ 0.608 |
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[6723] | 82 | |
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[13284] | 83 | INTEGER , PARAMETER :: jpfld =11 ! maximum number of files to read |
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[6723] | 84 | INTEGER , PARAMETER :: jp_wndi = 1 ! index of 10m wind velocity (i-component) (m/s) at T-point |
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| 85 | INTEGER , PARAMETER :: jp_wndj = 2 ! index of 10m wind velocity (j-component) (m/s) at T-point |
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[7163] | 86 | INTEGER , PARAMETER :: jp_tair = 3 ! index of 10m air temperature (Kelvin) |
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| 87 | INTEGER , PARAMETER :: jp_humi = 4 ! index of specific humidity ( % ) |
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| 88 | INTEGER , PARAMETER :: jp_qsr = 5 ! index of solar heat (W/m2) |
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| 89 | INTEGER , PARAMETER :: jp_qlw = 6 ! index of Long wave (W/m2) |
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[6723] | 90 | INTEGER , PARAMETER :: jp_prec = 7 ! index of total precipitation (rain+snow) (Kg/m2/s) |
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| 91 | INTEGER , PARAMETER :: jp_snow = 8 ! index of snow (solid prcipitation) (kg/m2/s) |
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[7421] | 92 | INTEGER , PARAMETER :: jp_slp = 9 ! index of sea level pressure (Pa) |
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[13284] | 93 | INTEGER , PARAMETER :: jp_cc =10 ! index of cloud cover (-) range:0-1 |
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| 94 | INTEGER , PARAMETER :: jp_tdif =11 ! index of tau diff associated to HF tau (N/m2) at T-point |
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[6723] | 95 | |
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| 96 | TYPE(FLD), ALLOCATABLE, DIMENSION(:) :: sf ! structure of input fields (file informations, fields read) |
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| 97 | |
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| 98 | ! !!! Bulk parameters |
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[7355] | 99 | REAL(wp), PARAMETER :: cpa = 1000.5 ! specific heat of air (only used for ice fluxes now...) |
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| 100 | REAL(wp), PARAMETER :: Ls = 2.839e6 ! latent heat of sublimation |
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| 101 | REAL(wp), PARAMETER :: Stef = 5.67e-8 ! Stefan Boltzmann constant |
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[9019] | 102 | REAL(wp), PARAMETER :: Cd_ice = 1.4e-3 ! transfer coefficient over ice |
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[7355] | 103 | REAL(wp), PARAMETER :: albo = 0.066 ! ocean albedo assumed to be constant |
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[6723] | 104 | ! |
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| 105 | ! !!* Namelist namsbc_blk : bulk parameters |
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| 106 | LOGICAL :: ln_NCAR ! "NCAR" algorithm (Large and Yeager 2008) |
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| 107 | LOGICAL :: ln_COARE_3p0 ! "COARE 3.0" algorithm (Fairall et al. 2003) |
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| 108 | LOGICAL :: ln_COARE_3p5 ! "COARE 3.5" algorithm (Edson et al. 2013) |
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| 109 | LOGICAL :: ln_ECMWF ! "ECMWF" algorithm (IFS cycle 31) |
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| 110 | ! |
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| 111 | LOGICAL :: ln_taudif ! logical flag to use the "mean of stress module - module of mean stress" data |
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| 112 | REAL(wp) :: rn_pfac ! multiplication factor for precipitation |
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[9019] | 113 | REAL(wp) :: rn_efac ! multiplication factor for evaporation |
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| 114 | REAL(wp) :: rn_vfac ! multiplication factor for ice/ocean velocity in the calculation of wind stress |
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[6723] | 115 | REAL(wp) :: rn_zqt ! z(q,t) : height of humidity and temperature measurements |
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| 116 | REAL(wp) :: rn_zu ! z(u) : height of wind measurements |
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[9019] | 117 | !!gm ref namelist initialize it so remove the setting to false below |
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| 118 | LOGICAL :: ln_Cd_L12 = .FALSE. ! Modify the drag ice-atm depending on ice concentration (from Lupkes et al. JGR2012) |
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| 119 | LOGICAL :: ln_Cd_L15 = .FALSE. ! Modify the drag ice-atm depending on ice concentration (from Lupkes et al. JGR2015) |
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[7355] | 120 | ! |
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[9019] | 121 | REAL(wp), ALLOCATABLE, SAVE, DIMENSION(:,:) :: Cd_atm ! transfer coefficient for momentum (tau) |
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| 122 | REAL(wp), ALLOCATABLE, SAVE, DIMENSION(:,:) :: Ch_atm ! transfer coefficient for sensible heat (Q_sens) |
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| 123 | REAL(wp), ALLOCATABLE, SAVE, DIMENSION(:,:) :: Ce_atm ! tansfert coefficient for evaporation (Q_lat) |
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| 124 | REAL(wp), ALLOCATABLE, SAVE, DIMENSION(:,:) :: t_zu ! air temperature at wind speed height (needed by Lupkes 2015 bulk scheme) |
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| 125 | REAL(wp), ALLOCATABLE, SAVE, DIMENSION(:,:) :: q_zu ! air spec. hum. at wind speed height (needed by Lupkes 2015 bulk scheme) |
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| 126 | REAL(wp), ALLOCATABLE, SAVE, DIMENSION(:,:) :: cdn_oce, chn_oce, cen_oce ! needed by Lupkes 2015 bulk scheme |
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[6723] | 127 | |
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| 128 | INTEGER :: nblk ! choice of the bulk algorithm |
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| 129 | ! ! associated indices: |
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| 130 | INTEGER, PARAMETER :: np_NCAR = 1 ! "NCAR" algorithm (Large and Yeager 2008) |
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| 131 | INTEGER, PARAMETER :: np_COARE_3p0 = 2 ! "COARE 3.0" algorithm (Fairall et al. 2003) |
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| 132 | INTEGER, PARAMETER :: np_COARE_3p5 = 3 ! "COARE 3.5" algorithm (Edson et al. 2013) |
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| 133 | INTEGER, PARAMETER :: np_ECMWF = 4 ! "ECMWF" algorithm (IFS cycle 31) |
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| 134 | |
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| 135 | !! * Substitutions |
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| 136 | # include "vectopt_loop_substitute.h90" |
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| 137 | !!---------------------------------------------------------------------- |
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[9598] | 138 | !! NEMO/OCE 4.0 , NEMO Consortium (2018) |
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[10069] | 139 | !! $Id$ |
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[10068] | 140 | !! Software governed by the CeCILL license (see ./LICENSE) |
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[6723] | 141 | !!---------------------------------------------------------------------- |
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| 142 | CONTAINS |
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| 143 | |
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[7355] | 144 | INTEGER FUNCTION sbc_blk_alloc() |
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| 145 | !!------------------------------------------------------------------- |
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| 146 | !! *** ROUTINE sbc_blk_alloc *** |
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| 147 | !!------------------------------------------------------------------- |
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[9019] | 148 | ALLOCATE( Cd_atm (jpi,jpj), Ch_atm (jpi,jpj), Ce_atm (jpi,jpj), t_zu(jpi,jpj), q_zu(jpi,jpj), & |
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| 149 | & cdn_oce(jpi,jpj), chn_oce(jpi,jpj), cen_oce(jpi,jpj), STAT=sbc_blk_alloc ) |
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[7355] | 150 | ! |
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[10425] | 151 | CALL mpp_sum ( 'sbcblk', sbc_blk_alloc ) |
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| 152 | IF( sbc_blk_alloc /= 0 ) CALL ctl_stop( 'STOP', 'sbc_blk_alloc: failed to allocate arrays' ) |
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[7355] | 153 | END FUNCTION sbc_blk_alloc |
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| 154 | |
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[9019] | 155 | |
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[7163] | 156 | SUBROUTINE sbc_blk_init |
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| 157 | !!--------------------------------------------------------------------- |
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| 158 | !! *** ROUTINE sbc_blk_init *** |
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| 159 | !! |
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| 160 | !! ** Purpose : choose and initialize a bulk formulae formulation |
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| 161 | !! |
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| 162 | !! ** Method : |
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| 163 | !! |
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| 164 | !!---------------------------------------------------------------------- |
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[13284] | 165 | INTEGER :: jfpr, jfld ! dummy loop indice and argument |
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[7163] | 166 | INTEGER :: ios, ierror, ioptio ! Local integer |
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| 167 | !! |
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| 168 | CHARACTER(len=100) :: cn_dir ! Root directory for location of atmospheric forcing files |
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| 169 | TYPE(FLD_N), DIMENSION(jpfld) :: slf_i ! array of namelist informations on the fields to read |
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| 170 | TYPE(FLD_N) :: sn_wndi, sn_wndj, sn_humi, sn_qsr ! informations about the fields to be read |
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| 171 | TYPE(FLD_N) :: sn_qlw , sn_tair, sn_prec, sn_snow ! " " |
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[13284] | 172 | TYPE(FLD_N) :: sn_slp , sn_tdif, sn_cc ! " " |
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[7163] | 173 | NAMELIST/namsbc_blk/ sn_wndi, sn_wndj, sn_humi, sn_qsr, sn_qlw , & ! input fields |
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[13284] | 174 | & sn_tair, sn_prec, sn_snow, sn_slp, sn_tdif, sn_cc, & |
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[7163] | 175 | & ln_NCAR, ln_COARE_3p0, ln_COARE_3p5, ln_ECMWF, & ! bulk algorithm |
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[7355] | 176 | & cn_dir , ln_taudif, rn_zqt, rn_zu, & |
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[9019] | 177 | & rn_pfac, rn_efac, rn_vfac, ln_Cd_L12, ln_Cd_L15 |
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[7163] | 178 | !!--------------------------------------------------------------------- |
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| 179 | ! |
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[7355] | 180 | ! ! allocate sbc_blk_core array |
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| 181 | IF( sbc_blk_alloc() /= 0 ) CALL ctl_stop( 'STOP', 'sbc_blk : unable to allocate standard arrays' ) |
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| 182 | ! |
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[7163] | 183 | ! !** read bulk namelist |
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| 184 | REWIND( numnam_ref ) !* Namelist namsbc_blk in reference namelist : bulk parameters |
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| 185 | READ ( numnam_ref, namsbc_blk, IOSTAT = ios, ERR = 901) |
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[11536] | 186 | 901 IF( ios /= 0 ) CALL ctl_nam ( ios , 'namsbc_blk in reference namelist' ) |
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[7163] | 187 | ! |
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| 188 | REWIND( numnam_cfg ) !* Namelist namsbc_blk in configuration namelist : bulk parameters |
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| 189 | READ ( numnam_cfg, namsbc_blk, IOSTAT = ios, ERR = 902 ) |
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[11536] | 190 | 902 IF( ios > 0 ) CALL ctl_nam ( ios , 'namsbc_blk in configuration namelist' ) |
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[7163] | 191 | ! |
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| 192 | IF(lwm) WRITE( numond, namsbc_blk ) |
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| 193 | ! |
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| 194 | ! !** initialization of the chosen bulk formulae (+ check) |
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| 195 | ! !* select the bulk chosen in the namelist and check the choice |
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[8666] | 196 | ioptio = 0 |
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[7163] | 197 | IF( ln_NCAR ) THEN ; nblk = np_NCAR ; ioptio = ioptio + 1 ; ENDIF |
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| 198 | IF( ln_COARE_3p0 ) THEN ; nblk = np_COARE_3p0 ; ioptio = ioptio + 1 ; ENDIF |
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| 199 | IF( ln_COARE_3p5 ) THEN ; nblk = np_COARE_3p5 ; ioptio = ioptio + 1 ; ENDIF |
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| 200 | IF( ln_ECMWF ) THEN ; nblk = np_ECMWF ; ioptio = ioptio + 1 ; ENDIF |
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| 201 | ! |
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| 202 | IF( ioptio /= 1 ) CALL ctl_stop( 'sbc_blk_init: Choose one and only one bulk algorithm' ) |
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| 203 | ! |
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| 204 | IF( ln_dm2dc ) THEN !* check: diurnal cycle on Qsr |
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[11536] | 205 | IF( sn_qsr%freqh /= 24. ) CALL ctl_stop( 'sbc_blk_init: ln_dm2dc=T only with daily short-wave input' ) |
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[7163] | 206 | IF( sn_qsr%ln_tint ) THEN |
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| 207 | CALL ctl_warn( 'sbc_blk_init: ln_dm2dc=T daily qsr time interpolation done by sbcdcy module', & |
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| 208 | & ' ==> We force time interpolation = .false. for qsr' ) |
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| 209 | sn_qsr%ln_tint = .false. |
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| 210 | ENDIF |
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| 211 | ENDIF |
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| 212 | ! !* set the bulk structure |
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| 213 | ! !- store namelist information in an array |
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| 214 | slf_i(jp_wndi) = sn_wndi ; slf_i(jp_wndj) = sn_wndj |
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| 215 | slf_i(jp_qsr ) = sn_qsr ; slf_i(jp_qlw ) = sn_qlw |
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| 216 | slf_i(jp_tair) = sn_tair ; slf_i(jp_humi) = sn_humi |
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| 217 | slf_i(jp_prec) = sn_prec ; slf_i(jp_snow) = sn_snow |
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[13284] | 218 | slf_i(jp_slp) = sn_slp ; slf_i(jp_cc) = sn_cc |
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| 219 | slf_i(jp_tdif) = sn_tdif |
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[7163] | 220 | ! |
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| 221 | lhftau = ln_taudif !- add an extra field if HF stress is used |
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| 222 | jfld = jpfld - COUNT( (/.NOT.lhftau/) ) |
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| 223 | ! |
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| 224 | ! !- allocate the bulk structure |
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| 225 | ALLOCATE( sf(jfld), STAT=ierror ) |
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| 226 | IF( ierror > 0 ) CALL ctl_stop( 'STOP', 'sbc_blk_init: unable to allocate sf structure' ) |
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[8530] | 227 | |
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[7163] | 228 | ! !- fill the bulk structure with namelist informations |
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| 229 | CALL fld_fill( sf, slf_i, cn_dir, 'sbc_blk_init', 'surface boundary condition -- bulk formulae', 'namsbc_blk' ) |
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| 230 | ! |
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[13284] | 231 | DO jfpr = 1, jfld |
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| 232 | ! |
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| 233 | IF( TRIM(sf(jfpr)%clrootname) == 'NOT USED' ) THEN !-- not used field --! (only now allocated and set to zero) |
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| 234 | ALLOCATE( sf(jfpr)%fnow(jpi,jpj,1) ) |
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| 235 | sf(jfpr)%fnow(:,:,1) = 0._wp |
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| 236 | ELSE !-- used field --! |
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| 237 | ALLOCATE( sf(jfpr)%fnow(jpi,jpj,1) ) |
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| 238 | IF( slf_i(jfpr)%ln_tint ) ALLOCATE( sf(jfpr)%fdta(jpi,jpj,1,2) ) |
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| 239 | IF( slf_i(jfpr)%freqh > 0. .AND. MOD( NINT(3600. * slf_i(jfpr)%freqh), nn_fsbc * NINT(rdt) ) /= 0 ) & |
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| 240 | & CALL ctl_warn( 'sbc_blk_init: sbcmod timestep rdt*nn_fsbc is NOT a submultiple of atmospheric forcing frequency.', & |
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| 241 | & ' This is not ideal. You should consider changing either rdt or nn_fsbc value...' ) |
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| 242 | ENDIF |
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| 243 | ENDDO |
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| 244 | ! fill cloud cover array with constant value if "not used" |
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| 245 | IF( TRIM(sf(jp_cc)%clrootname) == 'NOT USED' ) sf(jp_cc)%fnow(:,:,1) = pp_cldf |
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| 246 | |
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[7431] | 247 | IF ( ln_wave ) THEN |
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| 248 | !Activated wave module but neither drag nor stokes drift activated |
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[9033] | 249 | IF ( .NOT.(ln_cdgw .OR. ln_sdw .OR. ln_tauwoc .OR. ln_stcor ) ) THEN |
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[10425] | 250 | CALL ctl_stop( 'STOP', 'Ask for wave coupling but ln_cdgw=F, ln_sdw=F, ln_tauwoc=F, ln_stcor=F' ) |
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[7431] | 251 | !drag coefficient read from wave model definable only with mfs bulk formulae and core |
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| 252 | ELSEIF (ln_cdgw .AND. .NOT. ln_NCAR ) THEN |
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[10190] | 253 | CALL ctl_stop( 'drag coefficient read from wave model definable only with NCAR and CORE bulk formulae') |
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[7431] | 254 | ELSEIF (ln_stcor .AND. .NOT. ln_sdw) THEN |
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| 255 | CALL ctl_stop( 'Stokes-Coriolis term calculated only if activated Stokes Drift ln_sdw=T') |
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| 256 | ENDIF |
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| 257 | ELSE |
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[9033] | 258 | IF ( ln_cdgw .OR. ln_sdw .OR. ln_tauwoc .OR. ln_stcor ) & |
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[7431] | 259 | & CALL ctl_stop( 'Not Activated Wave Module (ln_wave=F) but asked coupling ', & |
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| 260 | & 'with drag coefficient (ln_cdgw =T) ' , & |
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| 261 | & 'or Stokes Drift (ln_sdw=T) ' , & |
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[9033] | 262 | & 'or ocean stress modification due to waves (ln_tauwoc=T) ', & |
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[7431] | 263 | & 'or Stokes-Coriolis term (ln_stcori=T)' ) |
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| 264 | ENDIF |
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| 265 | ! |
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[7163] | 266 | ! |
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| 267 | IF(lwp) THEN !** Control print |
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| 268 | ! |
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| 269 | WRITE(numout,*) !* namelist |
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| 270 | WRITE(numout,*) ' Namelist namsbc_blk (other than data information):' |
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| 271 | WRITE(numout,*) ' "NCAR" algorithm (Large and Yeager 2008) ln_NCAR = ', ln_NCAR |
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| 272 | WRITE(numout,*) ' "COARE 3.0" algorithm (Fairall et al. 2003) ln_COARE_3p0 = ', ln_COARE_3p0 |
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[13348] | 273 | WRITE(numout,*) ' "COARE 3.5" algorithm (Edson et al. 2013) ln_COARE_3p5 = ', ln_COARE_3p5 |
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[7163] | 274 | WRITE(numout,*) ' "ECMWF" algorithm (IFS cycle 31) ln_ECMWF = ', ln_ECMWF |
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| 275 | WRITE(numout,*) ' add High freq.contribution to the stress module ln_taudif = ', ln_taudif |
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| 276 | WRITE(numout,*) ' Air temperature and humidity reference height (m) rn_zqt = ', rn_zqt |
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| 277 | WRITE(numout,*) ' Wind vector reference height (m) rn_zu = ', rn_zu |
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| 278 | WRITE(numout,*) ' factor applied on precipitation (total & snow) rn_pfac = ', rn_pfac |
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| 279 | WRITE(numout,*) ' factor applied on evaporation rn_efac = ', rn_efac |
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| 280 | WRITE(numout,*) ' factor applied on ocean/ice velocity rn_vfac = ', rn_vfac |
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| 281 | WRITE(numout,*) ' (form absolute (=0) to relative winds(=1))' |
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[9019] | 282 | WRITE(numout,*) ' use ice-atm drag from Lupkes2012 ln_Cd_L12 = ', ln_Cd_L12 |
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| 283 | WRITE(numout,*) ' use ice-atm drag from Lupkes2015 ln_Cd_L15 = ', ln_Cd_L15 |
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[7163] | 284 | ! |
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| 285 | WRITE(numout,*) |
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| 286 | SELECT CASE( nblk ) !* Print the choice of bulk algorithm |
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[9190] | 287 | CASE( np_NCAR ) ; WRITE(numout,*) ' ==>>> "NCAR" algorithm (Large and Yeager 2008)' |
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| 288 | CASE( np_COARE_3p0 ) ; WRITE(numout,*) ' ==>>> "COARE 3.0" algorithm (Fairall et al. 2003)' |
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| 289 | CASE( np_COARE_3p5 ) ; WRITE(numout,*) ' ==>>> "COARE 3.5" algorithm (Edson et al. 2013)' |
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| 290 | CASE( np_ECMWF ) ; WRITE(numout,*) ' ==>>> "ECMWF" algorithm (IFS cycle 31)' |
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[7163] | 291 | END SELECT |
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| 292 | ! |
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| 293 | ENDIF |
---|
| 294 | ! |
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| 295 | END SUBROUTINE sbc_blk_init |
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| 296 | |
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| 297 | |
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[6723] | 298 | SUBROUTINE sbc_blk( kt ) |
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| 299 | !!--------------------------------------------------------------------- |
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| 300 | !! *** ROUTINE sbc_blk *** |
---|
| 301 | !! |
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| 302 | !! ** Purpose : provide at each time step the surface ocean fluxes |
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[9019] | 303 | !! (momentum, heat, freshwater and runoff) |
---|
[6723] | 304 | !! |
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| 305 | !! ** Method : (1) READ each fluxes in NetCDF files: |
---|
| 306 | !! the 10m wind velocity (i-component) (m/s) at T-point |
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| 307 | !! the 10m wind velocity (j-component) (m/s) at T-point |
---|
| 308 | !! the 10m or 2m specific humidity ( % ) |
---|
| 309 | !! the solar heat (W/m2) |
---|
| 310 | !! the Long wave (W/m2) |
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| 311 | !! the 10m or 2m air temperature (Kelvin) |
---|
| 312 | !! the total precipitation (rain+snow) (Kg/m2/s) |
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| 313 | !! the snow (solid prcipitation) (kg/m2/s) |
---|
| 314 | !! the tau diff associated to HF tau (N/m2) at T-point (ln_taudif=T) |
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| 315 | !! (2) CALL blk_oce |
---|
| 316 | !! |
---|
| 317 | !! C A U T I O N : never mask the surface stress fields |
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| 318 | !! the stress is assumed to be in the (i,j) mesh referential |
---|
| 319 | !! |
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| 320 | !! ** Action : defined at each time-step at the air-sea interface |
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| 321 | !! - utau, vtau i- and j-component of the wind stress |
---|
| 322 | !! - taum wind stress module at T-point |
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| 323 | !! - wndm wind speed module at T-point over free ocean or leads in presence of sea-ice |
---|
| 324 | !! - qns, qsr non-solar and solar heat fluxes |
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| 325 | !! - emp upward mass flux (evapo. - precip.) |
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| 326 | !! - sfx salt flux due to freezing/melting (non-zero only if ice is present) |
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| 327 | !! |
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| 328 | !! ** References : Large & Yeager, 2004 / Large & Yeager, 2008 |
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| 329 | !! Brodeau et al. Ocean Modelling 2010 |
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| 330 | !!---------------------------------------------------------------------- |
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| 331 | INTEGER, INTENT(in) :: kt ! ocean time step |
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| 332 | !!--------------------------------------------------------------------- |
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| 333 | ! |
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| 334 | CALL fld_read( kt, nn_fsbc, sf ) ! input fields provided at the current time-step |
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[7163] | 335 | ! |
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[6723] | 336 | ! ! compute the surface ocean fluxes using bulk formulea |
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| 337 | IF( MOD( kt - 1, nn_fsbc ) == 0 ) CALL blk_oce( kt, sf, sst_m, ssu_m, ssv_m ) |
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| 338 | |
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| 339 | #if defined key_cice |
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| 340 | IF( MOD( kt - 1, nn_fsbc ) == 0 ) THEN |
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[7753] | 341 | qlw_ice(:,:,1) = sf(jp_qlw )%fnow(:,:,1) |
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| 342 | IF( ln_dm2dc ) THEN ; qsr_ice(:,:,1) = sbc_dcy( sf(jp_qsr)%fnow(:,:,1) ) |
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| 343 | ELSE ; qsr_ice(:,:,1) = sf(jp_qsr)%fnow(:,:,1) |
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[7282] | 344 | ENDIF |
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[7753] | 345 | tatm_ice(:,:) = sf(jp_tair)%fnow(:,:,1) |
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| 346 | qatm_ice(:,:) = sf(jp_humi)%fnow(:,:,1) |
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| 347 | tprecip(:,:) = sf(jp_prec)%fnow(:,:,1) * rn_pfac |
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| 348 | sprecip(:,:) = sf(jp_snow)%fnow(:,:,1) * rn_pfac |
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| 349 | wndi_ice(:,:) = sf(jp_wndi)%fnow(:,:,1) |
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| 350 | wndj_ice(:,:) = sf(jp_wndj)%fnow(:,:,1) |
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[6723] | 351 | ENDIF |
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| 352 | #endif |
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| 353 | ! |
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| 354 | END SUBROUTINE sbc_blk |
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| 355 | |
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| 356 | |
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| 357 | SUBROUTINE blk_oce( kt, sf, pst, pu, pv ) |
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| 358 | !!--------------------------------------------------------------------- |
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| 359 | !! *** ROUTINE blk_oce *** |
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| 360 | !! |
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| 361 | !! ** Purpose : provide the momentum, heat and freshwater fluxes at |
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| 362 | !! the ocean surface at each time step |
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| 363 | !! |
---|
| 364 | !! ** Method : bulk formulea for the ocean using atmospheric |
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| 365 | !! fields read in sbc_read |
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| 366 | !! |
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| 367 | !! ** Outputs : - utau : i-component of the stress at U-point (N/m2) |
---|
| 368 | !! - vtau : j-component of the stress at V-point (N/m2) |
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| 369 | !! - taum : Wind stress module at T-point (N/m2) |
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| 370 | !! - wndm : Wind speed module at T-point (m/s) |
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| 371 | !! - qsr : Solar heat flux over the ocean (W/m2) |
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| 372 | !! - qns : Non Solar heat flux over the ocean (W/m2) |
---|
| 373 | !! - emp : evaporation minus precipitation (kg/m2/s) |
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| 374 | !! |
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| 375 | !! ** Nota : sf has to be a dummy argument for AGRIF on NEC |
---|
| 376 | !!--------------------------------------------------------------------- |
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| 377 | INTEGER , INTENT(in ) :: kt ! time step index |
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| 378 | TYPE(fld), INTENT(inout), DIMENSION(:) :: sf ! input data |
---|
| 379 | REAL(wp) , INTENT(in) , DIMENSION(:,:) :: pst ! surface temperature [Celcius] |
---|
| 380 | REAL(wp) , INTENT(in) , DIMENSION(:,:) :: pu ! surface current at U-point (i-component) [m/s] |
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| 381 | REAL(wp) , INTENT(in) , DIMENSION(:,:) :: pv ! surface current at V-point (j-component) [m/s] |
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| 382 | ! |
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| 383 | INTEGER :: ji, jj ! dummy loop indices |
---|
| 384 | REAL(wp) :: zztmp ! local variable |
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[9019] | 385 | REAL(wp), DIMENSION(jpi,jpj) :: zwnd_i, zwnd_j ! wind speed components at T-point |
---|
| 386 | REAL(wp), DIMENSION(jpi,jpj) :: zsq ! specific humidity at pst |
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| 387 | REAL(wp), DIMENSION(jpi,jpj) :: zqlw, zqsb ! long wave and sensible heat fluxes |
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| 388 | REAL(wp), DIMENSION(jpi,jpj) :: zqla, zevap ! latent heat fluxes and evaporation |
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| 389 | REAL(wp), DIMENSION(jpi,jpj) :: zst ! surface temperature in Kelvin |
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| 390 | REAL(wp), DIMENSION(jpi,jpj) :: zU_zu ! bulk wind speed at height zu [m/s] |
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| 391 | REAL(wp), DIMENSION(jpi,jpj) :: ztpot ! potential temperature of air at z=rn_zqt [K] |
---|
| 392 | REAL(wp), DIMENSION(jpi,jpj) :: zrhoa ! density of air [kg/m^3] |
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[14717] | 393 | REAL(wp), DIMENSION(jpi,jpj) :: zcptrain, zcptsnw, zcptn ! Heat content per unit mass (J/kg) |
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[6723] | 394 | !!--------------------------------------------------------------------- |
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| 395 | ! |
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[14717] | 396 | ! Heat content per unit mass (J/kg) |
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| 397 | zcptrain(:,:) = ( sf(jp_tair)%fnow(:,:,1) - rt0 ) * rcp * tmask(:,:,1) |
---|
| 398 | zcptsnw (:,:) = ( MIN( sf(jp_tair)%fnow(:,:,1), rt0 ) - rt0 ) * rcpi * tmask(:,:,1) |
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| 399 | zcptn (:,:) = pst(:,:) * rcp * tmask(:,:,1) |
---|
| 400 | ! |
---|
[7753] | 401 | ! local scalars ( place there for vector optimisation purposes) |
---|
| 402 | zst(:,:) = pst(:,:) + rt0 ! convert SST from Celcius to Kelvin (and set minimum value far above 0 K) |
---|
[6723] | 403 | |
---|
[13284] | 404 | ! --- cloud cover --- ! |
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| 405 | cloud_fra(:,:) = sf(jp_cc)%fnow(:,:,1) |
---|
| 406 | |
---|
[6723] | 407 | ! ----------------------------------------------------------------------------- ! |
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| 408 | ! 0 Wind components and module at T-point relative to the moving ocean ! |
---|
| 409 | ! ----------------------------------------------------------------------------- ! |
---|
| 410 | |
---|
[7753] | 411 | ! ... components ( U10m - U_oce ) at T-point (unmasked) |
---|
| 412 | !!gm move zwnd_i (_j) set to zero inside the key_cyclone ??? |
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| 413 | zwnd_i(:,:) = 0._wp |
---|
| 414 | zwnd_j(:,:) = 0._wp |
---|
[6723] | 415 | #if defined key_cyclone |
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| 416 | CALL wnd_cyc( kt, zwnd_i, zwnd_j ) ! add analytical tropical cyclone (Vincent et al. JGR 2012) |
---|
| 417 | DO jj = 2, jpjm1 |
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| 418 | DO ji = fs_2, fs_jpim1 ! vect. opt. |
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| 419 | sf(jp_wndi)%fnow(ji,jj,1) = sf(jp_wndi)%fnow(ji,jj,1) + zwnd_i(ji,jj) |
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| 420 | sf(jp_wndj)%fnow(ji,jj,1) = sf(jp_wndj)%fnow(ji,jj,1) + zwnd_j(ji,jj) |
---|
| 421 | END DO |
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| 422 | END DO |
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| 423 | #endif |
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[15813] | 424 | ! mask the wind in case it is not masked in the input file otherwise we end up with twice the stress at the coast |
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| 425 | ! (see calculation of utau/vtau below) |
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[6723] | 426 | DO jj = 2, jpjm1 |
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| 427 | DO ji = fs_2, fs_jpim1 ! vect. opt. |
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[15813] | 428 | zwnd_i(ji,jj) = ( sf(jp_wndi)%fnow(ji,jj,1) - rn_vfac * 0.5 * ( pu(ji-1,jj ) + pu(ji,jj) ) ) * tmask(ji,jj,1) |
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| 429 | zwnd_j(ji,jj) = ( sf(jp_wndj)%fnow(ji,jj,1) - rn_vfac * 0.5 * ( pv(ji ,jj-1) + pv(ji,jj) ) ) * tmask(ji,jj,1) |
---|
[6723] | 430 | END DO |
---|
| 431 | END DO |
---|
[10425] | 432 | CALL lbc_lnk_multi( 'sbcblk', zwnd_i, 'T', -1., zwnd_j, 'T', -1. ) |
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[6723] | 433 | ! ... scalar wind ( = | U10m - U_oce | ) at T-point (masked) |
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[7753] | 434 | wndm(:,:) = SQRT( zwnd_i(:,:) * zwnd_i(:,:) & |
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[15813] | 435 | & + zwnd_j(:,:) * zwnd_j(:,:) ) |
---|
[6723] | 436 | |
---|
| 437 | ! ----------------------------------------------------------------------------- ! |
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| 438 | ! I Radiative FLUXES ! |
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| 439 | ! ----------------------------------------------------------------------------- ! |
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| 440 | |
---|
| 441 | ! ocean albedo assumed to be constant + modify now Qsr to include the diurnal cycle ! Short Wave |
---|
| 442 | zztmp = 1. - albo |
---|
| 443 | IF( ln_dm2dc ) THEN ; qsr(:,:) = zztmp * sbc_dcy( sf(jp_qsr)%fnow(:,:,1) ) * tmask(:,:,1) |
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[7753] | 444 | ELSE ; qsr(:,:) = zztmp * sf(jp_qsr)%fnow(:,:,1) * tmask(:,:,1) |
---|
[6723] | 445 | ENDIF |
---|
| 446 | |
---|
[15613] | 447 | #if defined key_top |
---|
| 448 | IF( ln_trcdc2dm ) THEN ! diurnal cycle in TOP |
---|
| 449 | IF( ln_dm2dc ) THEN ; qsr_mean(:,:) = zztmp * sf(jp_qsr)%fnow(:,:,1) * tmask(:,:,1) |
---|
| 450 | ELSE ; ncpl_qsr_freq = sf(jp_qsr)%freqh * 3600 ! qsr_mean will be computed in TOP |
---|
| 451 | ENDIF |
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| 452 | ENDIF |
---|
| 453 | #endif |
---|
| 454 | |
---|
[7753] | 455 | zqlw(:,:) = ( sf(jp_qlw)%fnow(:,:,1) - Stef * zst(:,:)*zst(:,:)*zst(:,:)*zst(:,:) ) * tmask(:,:,1) ! Long Wave |
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[6723] | 456 | |
---|
| 457 | ! ----------------------------------------------------------------------------- ! |
---|
| 458 | ! II Turbulent FLUXES ! |
---|
| 459 | ! ----------------------------------------------------------------------------- ! |
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| 460 | |
---|
| 461 | ! ... specific humidity at SST and IST tmask( |
---|
[6727] | 462 | zsq(:,:) = 0.98 * q_sat( zst(:,:), sf(jp_slp)%fnow(:,:,1) ) |
---|
[6723] | 463 | !! |
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| 464 | !! Estimate of potential temperature at z=rn_zqt, based on adiabatic lapse-rate |
---|
| 465 | !! (see Josey, Gulev & Yu, 2013) / doi=10.1016/B978-0-12-391851-2.00005-2 |
---|
| 466 | !! (since reanalysis products provide T at z, not theta !) |
---|
[6727] | 467 | ztpot = sf(jp_tair)%fnow(:,:,1) + gamma_moist( sf(jp_tair)%fnow(:,:,1), sf(jp_humi)%fnow(:,:,1) ) * rn_zqt |
---|
[6723] | 468 | |
---|
| 469 | SELECT CASE( nblk ) !== transfer coefficients ==! Cd, Ch, Ce at T-point |
---|
[6727] | 470 | ! |
---|
| 471 | CASE( np_NCAR ) ; CALL turb_ncar ( rn_zqt, rn_zu, zst, ztpot, zsq, sf(jp_humi)%fnow, wndm, & ! NCAR-COREv2 |
---|
[9019] | 472 | & Cd_atm, Ch_atm, Ce_atm, t_zu, q_zu, zU_zu, cdn_oce, chn_oce, cen_oce ) |
---|
[6727] | 473 | CASE( np_COARE_3p0 ) ; CALL turb_coare ( rn_zqt, rn_zu, zst, ztpot, zsq, sf(jp_humi)%fnow, wndm, & ! COARE v3.0 |
---|
[9019] | 474 | & Cd_atm, Ch_atm, Ce_atm, t_zu, q_zu, zU_zu, cdn_oce, chn_oce, cen_oce ) |
---|
[6727] | 475 | CASE( np_COARE_3p5 ) ; CALL turb_coare3p5( rn_zqt, rn_zu, zst, ztpot, zsq, sf(jp_humi)%fnow, wndm, & ! COARE v3.5 |
---|
[9019] | 476 | & Cd_atm, Ch_atm, Ce_atm, t_zu, q_zu, zU_zu, cdn_oce, chn_oce, cen_oce ) |
---|
[6727] | 477 | CASE( np_ECMWF ) ; CALL turb_ecmwf ( rn_zqt, rn_zu, zst, ztpot, zsq, sf(jp_humi)%fnow, wndm, & ! ECMWF |
---|
[9019] | 478 | & Cd_atm, Ch_atm, Ce_atm, t_zu, q_zu, zU_zu, cdn_oce, chn_oce, cen_oce ) |
---|
[6723] | 479 | CASE DEFAULT |
---|
[7163] | 480 | CALL ctl_stop( 'STOP', 'sbc_oce: non-existing bulk formula selected' ) |
---|
[6723] | 481 | END SELECT |
---|
| 482 | |
---|
[6727] | 483 | ! ! Compute true air density : |
---|
| 484 | IF( ABS(rn_zu - rn_zqt) > 0.01 ) THEN ! At zu: (probably useless to remove zrho*grav*rn_zu from SLP...) |
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[9019] | 485 | zrhoa(:,:) = rho_air( t_zu(:,:) , q_zu(:,:) , sf(jp_slp)%fnow(:,:,1) ) |
---|
[6727] | 486 | ELSE ! At zt: |
---|
| 487 | zrhoa(:,:) = rho_air( sf(jp_tair)%fnow(:,:,1), sf(jp_humi)%fnow(:,:,1), sf(jp_slp)%fnow(:,:,1) ) |
---|
[6723] | 488 | END IF |
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| 489 | |
---|
[9019] | 490 | !! CALL iom_put( "Cd_oce", Cd_atm) ! output value of pure ocean-atm. transfer coef. |
---|
| 491 | !! CALL iom_put( "Ch_oce", Ch_atm) ! output value of pure ocean-atm. transfer coef. |
---|
[7355] | 492 | |
---|
[6727] | 493 | DO jj = 1, jpj ! tau module, i and j component |
---|
[6723] | 494 | DO ji = 1, jpi |
---|
[9019] | 495 | zztmp = zrhoa(ji,jj) * zU_zu(ji,jj) * Cd_atm(ji,jj) ! using bulk wind speed |
---|
[6723] | 496 | taum (ji,jj) = zztmp * wndm (ji,jj) |
---|
| 497 | zwnd_i(ji,jj) = zztmp * zwnd_i(ji,jj) |
---|
| 498 | zwnd_j(ji,jj) = zztmp * zwnd_j(ji,jj) |
---|
| 499 | END DO |
---|
| 500 | END DO |
---|
| 501 | |
---|
[6727] | 502 | ! ! add the HF tau contribution to the wind stress module |
---|
[7753] | 503 | IF( lhftau ) taum(:,:) = taum(:,:) + sf(jp_tdif)%fnow(:,:,1) |
---|
[6727] | 504 | |
---|
[6723] | 505 | CALL iom_put( "taum_oce", taum ) ! output wind stress module |
---|
| 506 | |
---|
| 507 | ! ... utau, vtau at U- and V_points, resp. |
---|
| 508 | ! Note the use of 0.5*(2-umask) in order to unmask the stress along coastlines |
---|
| 509 | ! Note the use of MAX(tmask(i,j),tmask(i+1,j) is to mask tau over ice shelves |
---|
| 510 | DO jj = 1, jpjm1 |
---|
| 511 | DO ji = 1, fs_jpim1 |
---|
| 512 | utau(ji,jj) = 0.5 * ( 2. - umask(ji,jj,1) ) * ( zwnd_i(ji,jj) + zwnd_i(ji+1,jj ) ) & |
---|
| 513 | & * MAX(tmask(ji,jj,1),tmask(ji+1,jj,1)) |
---|
| 514 | vtau(ji,jj) = 0.5 * ( 2. - vmask(ji,jj,1) ) * ( zwnd_j(ji,jj) + zwnd_j(ji ,jj+1) ) & |
---|
| 515 | & * MAX(tmask(ji,jj,1),tmask(ji,jj+1,1)) |
---|
| 516 | END DO |
---|
| 517 | END DO |
---|
[10425] | 518 | CALL lbc_lnk_multi( 'sbcblk', utau, 'U', -1., vtau, 'V', -1. ) |
---|
[6723] | 519 | |
---|
| 520 | ! Turbulent fluxes over ocean |
---|
| 521 | ! ----------------------------- |
---|
| 522 | |
---|
| 523 | ! zqla used as temporary array, for rho*U (common term of bulk formulae): |
---|
[9727] | 524 | zqla(:,:) = zrhoa(:,:) * zU_zu(:,:) * tmask(:,:,1) |
---|
[6723] | 525 | |
---|
| 526 | IF( ABS( rn_zu - rn_zqt) < 0.01_wp ) THEN |
---|
| 527 | !! q_air and t_air are given at 10m (wind reference height) |
---|
[9019] | 528 | zevap(:,:) = rn_efac*MAX( 0._wp, zqla(:,:)*Ce_atm(:,:)*(zsq(:,:) - sf(jp_humi)%fnow(:,:,1)) ) ! Evaporation, using bulk wind speed |
---|
| 529 | zqsb (:,:) = cp_air(sf(jp_humi)%fnow(:,:,1))*zqla(:,:)*Ch_atm(:,:)*(zst(:,:) - ztpot(:,:) ) ! Sensible Heat, using bulk wind speed |
---|
[6723] | 530 | ELSE |
---|
| 531 | !! q_air and t_air are not given at 10m (wind reference height) |
---|
| 532 | ! Values of temp. and hum. adjusted to height of wind during bulk algorithm iteration must be used!!! |
---|
[9019] | 533 | zevap(:,:) = rn_efac*MAX( 0._wp, zqla(:,:)*Ce_atm(:,:)*(zsq(:,:) - q_zu(:,:) ) ) ! Evaporation, using bulk wind speed |
---|
| 534 | zqsb (:,:) = cp_air(sf(jp_humi)%fnow(:,:,1))*zqla(:,:)*Ch_atm(:,:)*(zst(:,:) - t_zu(:,:) ) ! Sensible Heat, using bulk wind speed |
---|
[6723] | 535 | ENDIF |
---|
| 536 | |
---|
[6727] | 537 | zqla(:,:) = L_vap(zst(:,:)) * zevap(:,:) ! Latent Heat flux |
---|
[6723] | 538 | |
---|
| 539 | |
---|
| 540 | IF(ln_ctl) THEN |
---|
[9019] | 541 | CALL prt_ctl( tab2d_1=zqla , clinfo1=' blk_oce: zqla : ', tab2d_2=Ce_atm , clinfo2=' Ce_oce : ' ) |
---|
| 542 | CALL prt_ctl( tab2d_1=zqsb , clinfo1=' blk_oce: zqsb : ', tab2d_2=Ch_atm , clinfo2=' Ch_oce : ' ) |
---|
[6723] | 543 | CALL prt_ctl( tab2d_1=zqlw , clinfo1=' blk_oce: zqlw : ', tab2d_2=qsr, clinfo2=' qsr : ' ) |
---|
| 544 | CALL prt_ctl( tab2d_1=zsq , clinfo1=' blk_oce: zsq : ', tab2d_2=zst, clinfo2=' zst : ' ) |
---|
| 545 | CALL prt_ctl( tab2d_1=utau , clinfo1=' blk_oce: utau : ', mask1=umask, & |
---|
| 546 | & tab2d_2=vtau , clinfo2= ' vtau : ', mask2=vmask ) |
---|
| 547 | CALL prt_ctl( tab2d_1=wndm , clinfo1=' blk_oce: wndm : ') |
---|
| 548 | CALL prt_ctl( tab2d_1=zst , clinfo1=' blk_oce: zst : ') |
---|
| 549 | ENDIF |
---|
| 550 | |
---|
| 551 | ! ----------------------------------------------------------------------------- ! |
---|
| 552 | ! III Total FLUXES ! |
---|
| 553 | ! ----------------------------------------------------------------------------- ! |
---|
| 554 | ! |
---|
[7753] | 555 | emp (:,:) = ( zevap(:,:) & ! mass flux (evap. - precip.) |
---|
| 556 | & - sf(jp_prec)%fnow(:,:,1) * rn_pfac ) * tmask(:,:,1) |
---|
| 557 | ! |
---|
| 558 | qns(:,:) = zqlw(:,:) - zqsb(:,:) - zqla(:,:) & ! Downward Non Solar |
---|
[9935] | 559 | & - sf(jp_snow)%fnow(:,:,1) * rn_pfac * rLfus & ! remove latent melting heat for solid precip |
---|
[14717] | 560 | & - zevap(:,:) * zcptn(:,:) & ! remove evap heat content at SST |
---|
[7753] | 561 | & + ( sf(jp_prec)%fnow(:,:,1) - sf(jp_snow)%fnow(:,:,1) ) * rn_pfac & ! add liquid precip heat content at Tair |
---|
[14717] | 562 | & * zcptrain(:,:) & |
---|
[7753] | 563 | & + sf(jp_snow)%fnow(:,:,1) * rn_pfac & ! add solid precip heat content at min(Tair,Tsnow) |
---|
[14717] | 564 | & * zcptsnw(:,:) |
---|
[9727] | 565 | qns(:,:) = qns(:,:) * tmask(:,:,1) |
---|
[7753] | 566 | ! |
---|
[9570] | 567 | #if defined key_si3 |
---|
[9656] | 568 | qns_oce(:,:) = zqlw(:,:) - zqsb(:,:) - zqla(:,:) ! non solar without emp (only needed by SI3) |
---|
[7753] | 569 | qsr_oce(:,:) = qsr(:,:) |
---|
[6723] | 570 | #endif |
---|
| 571 | ! |
---|
| 572 | IF ( nn_ice == 0 ) THEN |
---|
| 573 | CALL iom_put( "qlw_oce" , zqlw ) ! output downward longwave heat over the ocean |
---|
| 574 | CALL iom_put( "qsb_oce" , - zqsb ) ! output downward sensible heat over the ocean |
---|
| 575 | CALL iom_put( "qla_oce" , - zqla ) ! output downward latent heat over the ocean |
---|
| 576 | CALL iom_put( "qemp_oce", qns-zqlw+zqsb+zqla ) ! output downward heat content of E-P over the ocean |
---|
| 577 | CALL iom_put( "qns_oce" , qns ) ! output downward non solar heat over the ocean |
---|
| 578 | CALL iom_put( "qsr_oce" , qsr ) ! output downward solar heat over the ocean |
---|
| 579 | CALL iom_put( "qt_oce" , qns+qsr ) ! output total downward heat over the ocean |
---|
[9727] | 580 | tprecip(:,:) = sf(jp_prec)%fnow(:,:,1) * rn_pfac * tmask(:,:,1) ! output total precipitation [kg/m2/s] |
---|
| 581 | sprecip(:,:) = sf(jp_snow)%fnow(:,:,1) * rn_pfac * tmask(:,:,1) ! output solid precipitation [kg/m2/s] |
---|
[9019] | 582 | CALL iom_put( 'snowpre', sprecip ) ! Snow |
---|
| 583 | CALL iom_put( 'precip' , tprecip ) ! Total precipitation |
---|
[6723] | 584 | ENDIF |
---|
| 585 | ! |
---|
| 586 | IF(ln_ctl) THEN |
---|
| 587 | CALL prt_ctl(tab2d_1=zqsb , clinfo1=' blk_oce: zqsb : ', tab2d_2=zqlw , clinfo2=' zqlw : ') |
---|
| 588 | CALL prt_ctl(tab2d_1=zqla , clinfo1=' blk_oce: zqla : ', tab2d_2=qsr , clinfo2=' qsr : ') |
---|
| 589 | CALL prt_ctl(tab2d_1=pst , clinfo1=' blk_oce: pst : ', tab2d_2=emp , clinfo2=' emp : ') |
---|
| 590 | CALL prt_ctl(tab2d_1=utau , clinfo1=' blk_oce: utau : ', mask1=umask, & |
---|
| 591 | & tab2d_2=vtau , clinfo2= ' vtau : ' , mask2=vmask ) |
---|
| 592 | ENDIF |
---|
| 593 | ! |
---|
| 594 | END SUBROUTINE blk_oce |
---|
| 595 | |
---|
| 596 | |
---|
[9019] | 597 | |
---|
| 598 | FUNCTION rho_air( ptak, pqa, pslp ) |
---|
| 599 | !!------------------------------------------------------------------------------- |
---|
| 600 | !! *** FUNCTION rho_air *** |
---|
| 601 | !! |
---|
| 602 | !! ** Purpose : compute density of (moist) air using the eq. of state of the atmosphere |
---|
| 603 | !! |
---|
| 604 | !! ** Author: L. Brodeau, june 2016 / AeroBulk (https://sourceforge.net/p/aerobulk) |
---|
| 605 | !!------------------------------------------------------------------------------- |
---|
| 606 | REAL(wp), DIMENSION(jpi,jpj), INTENT(in) :: ptak ! air temperature [K] |
---|
| 607 | REAL(wp), DIMENSION(jpi,jpj), INTENT(in) :: pqa ! air specific humidity [kg/kg] |
---|
| 608 | REAL(wp), DIMENSION(jpi,jpj), INTENT(in) :: pslp ! pressure in [Pa] |
---|
| 609 | REAL(wp), DIMENSION(jpi,jpj) :: rho_air ! density of moist air [kg/m^3] |
---|
| 610 | !!------------------------------------------------------------------------------- |
---|
| 611 | ! |
---|
| 612 | rho_air = pslp / ( R_dry*ptak * ( 1._wp + rctv0*pqa ) ) |
---|
| 613 | ! |
---|
| 614 | END FUNCTION rho_air |
---|
| 615 | |
---|
| 616 | |
---|
| 617 | FUNCTION cp_air( pqa ) |
---|
| 618 | !!------------------------------------------------------------------------------- |
---|
| 619 | !! *** FUNCTION cp_air *** |
---|
| 620 | !! |
---|
| 621 | !! ** Purpose : Compute specific heat (Cp) of moist air |
---|
| 622 | !! |
---|
| 623 | !! ** Author: L. Brodeau, june 2016 / AeroBulk (https://sourceforge.net/p/aerobulk) |
---|
| 624 | !!------------------------------------------------------------------------------- |
---|
| 625 | REAL(wp), DIMENSION(jpi,jpj), INTENT(in) :: pqa ! air specific humidity [kg/kg] |
---|
| 626 | REAL(wp), DIMENSION(jpi,jpj) :: cp_air ! specific heat of moist air [J/K/kg] |
---|
| 627 | !!------------------------------------------------------------------------------- |
---|
| 628 | ! |
---|
| 629 | Cp_air = Cp_dry + Cp_vap * pqa |
---|
| 630 | ! |
---|
| 631 | END FUNCTION cp_air |
---|
| 632 | |
---|
| 633 | |
---|
| 634 | FUNCTION q_sat( ptak, pslp ) |
---|
| 635 | !!---------------------------------------------------------------------------------- |
---|
| 636 | !! *** FUNCTION q_sat *** |
---|
| 637 | !! |
---|
| 638 | !! ** Purpose : Specific humidity at saturation in [kg/kg] |
---|
| 639 | !! Based on accurate estimate of "e_sat" |
---|
| 640 | !! aka saturation water vapor (Goff, 1957) |
---|
| 641 | !! |
---|
| 642 | !! ** Author: L. Brodeau, june 2016 / AeroBulk (https://sourceforge.net/p/aerobulk) |
---|
| 643 | !!---------------------------------------------------------------------------------- |
---|
| 644 | REAL(wp), DIMENSION(jpi,jpj), INTENT(in) :: ptak ! air temperature [K] |
---|
| 645 | REAL(wp), DIMENSION(jpi,jpj), INTENT(in) :: pslp ! sea level atmospheric pressure [Pa] |
---|
| 646 | REAL(wp), DIMENSION(jpi,jpj) :: q_sat ! Specific humidity at saturation [kg/kg] |
---|
| 647 | ! |
---|
| 648 | INTEGER :: ji, jj ! dummy loop indices |
---|
| 649 | REAL(wp) :: ze_sat, ztmp ! local scalar |
---|
| 650 | !!---------------------------------------------------------------------------------- |
---|
| 651 | ! |
---|
| 652 | DO jj = 1, jpj |
---|
| 653 | DO ji = 1, jpi |
---|
| 654 | ! |
---|
| 655 | ztmp = rt0 / ptak(ji,jj) |
---|
| 656 | ! |
---|
| 657 | ! Vapour pressure at saturation [hPa] : WMO, (Goff, 1957) |
---|
| 658 | ze_sat = 10.**( 10.79574*(1. - ztmp) - 5.028*LOG10(ptak(ji,jj)/rt0) & |
---|
| 659 | & + 1.50475*10.**(-4)*(1. - 10.**(-8.2969*(ptak(ji,jj)/rt0 - 1.)) ) & |
---|
| 660 | & + 0.42873*10.**(-3)*(10.**(4.76955*(1. - ztmp)) - 1.) + 0.78614 ) |
---|
| 661 | ! |
---|
| 662 | q_sat(ji,jj) = reps0 * ze_sat/( 0.01_wp*pslp(ji,jj) - (1._wp - reps0)*ze_sat ) ! 0.01 because SLP is in [Pa] |
---|
| 663 | ! |
---|
| 664 | END DO |
---|
| 665 | END DO |
---|
| 666 | ! |
---|
| 667 | END FUNCTION q_sat |
---|
| 668 | |
---|
| 669 | |
---|
| 670 | FUNCTION gamma_moist( ptak, pqa ) |
---|
| 671 | !!---------------------------------------------------------------------------------- |
---|
| 672 | !! *** FUNCTION gamma_moist *** |
---|
| 673 | !! |
---|
| 674 | !! ** Purpose : Compute the moist adiabatic lapse-rate. |
---|
| 675 | !! => http://glossary.ametsoc.org/wiki/Moist-adiabatic_lapse_rate |
---|
| 676 | !! => http://www.geog.ucsb.edu/~joel/g266_s10/lecture_notes/chapt03/oh10_3_01/oh10_3_01.html |
---|
| 677 | !! |
---|
| 678 | !! ** Author: L. Brodeau, june 2016 / AeroBulk (https://sourceforge.net/p/aerobulk) |
---|
| 679 | !!---------------------------------------------------------------------------------- |
---|
| 680 | REAL(wp), DIMENSION(jpi,jpj), INTENT(in) :: ptak ! air temperature [K] |
---|
| 681 | REAL(wp), DIMENSION(jpi,jpj), INTENT(in) :: pqa ! specific humidity [kg/kg] |
---|
| 682 | REAL(wp), DIMENSION(jpi,jpj) :: gamma_moist ! moist adiabatic lapse-rate |
---|
| 683 | ! |
---|
| 684 | INTEGER :: ji, jj ! dummy loop indices |
---|
| 685 | REAL(wp) :: zrv, ziRT ! local scalar |
---|
| 686 | !!---------------------------------------------------------------------------------- |
---|
| 687 | ! |
---|
| 688 | DO jj = 1, jpj |
---|
| 689 | DO ji = 1, jpi |
---|
| 690 | zrv = pqa(ji,jj) / (1. - pqa(ji,jj)) |
---|
| 691 | ziRT = 1. / (R_dry*ptak(ji,jj)) ! 1/RT |
---|
[9935] | 692 | gamma_moist(ji,jj) = grav * ( 1. + rLevap*zrv*ziRT ) / ( Cp_dry + rLevap*rLevap*zrv*reps0*ziRT/ptak(ji,jj) ) |
---|
[9019] | 693 | END DO |
---|
| 694 | END DO |
---|
| 695 | ! |
---|
| 696 | END FUNCTION gamma_moist |
---|
| 697 | |
---|
| 698 | |
---|
| 699 | FUNCTION L_vap( psst ) |
---|
| 700 | !!--------------------------------------------------------------------------------- |
---|
| 701 | !! *** FUNCTION L_vap *** |
---|
| 702 | !! |
---|
| 703 | !! ** Purpose : Compute the latent heat of vaporization of water from temperature |
---|
| 704 | !! |
---|
| 705 | !! ** Author: L. Brodeau, june 2016 / AeroBulk (https://sourceforge.net/p/aerobulk) |
---|
| 706 | !!---------------------------------------------------------------------------------- |
---|
| 707 | REAL(wp), DIMENSION(jpi,jpj) :: L_vap ! latent heat of vaporization [J/kg] |
---|
| 708 | REAL(wp), DIMENSION(jpi,jpj), INTENT(in) :: psst ! water temperature [K] |
---|
| 709 | !!---------------------------------------------------------------------------------- |
---|
| 710 | ! |
---|
| 711 | L_vap = ( 2.501 - 0.00237 * ( psst(:,:) - rt0) ) * 1.e6 |
---|
| 712 | ! |
---|
| 713 | END FUNCTION L_vap |
---|
| 714 | |
---|
[9570] | 715 | #if defined key_si3 |
---|
[9019] | 716 | !!---------------------------------------------------------------------- |
---|
[9570] | 717 | !! 'key_si3' SI3 sea-ice model |
---|
[9019] | 718 | !!---------------------------------------------------------------------- |
---|
| 719 | !! blk_ice_tau : provide the air-ice stress |
---|
| 720 | !! blk_ice_flx : provide the heat and mass fluxes at air-ice interface |
---|
[10534] | 721 | !! blk_ice_qcn : provide ice surface temperature and snow/ice conduction flux (emulating conduction flux) |
---|
[9019] | 722 | !! Cdn10_Lupkes2012 : Lupkes et al. (2012) air-ice drag |
---|
| 723 | !! Cdn10_Lupkes2015 : Lupkes et al. (2015) air-ice drag |
---|
| 724 | !!---------------------------------------------------------------------- |
---|
| 725 | |
---|
[6723] | 726 | SUBROUTINE blk_ice_tau |
---|
| 727 | !!--------------------------------------------------------------------- |
---|
| 728 | !! *** ROUTINE blk_ice_tau *** |
---|
| 729 | !! |
---|
| 730 | !! ** Purpose : provide the surface boundary condition over sea-ice |
---|
| 731 | !! |
---|
| 732 | !! ** Method : compute momentum using bulk formulation |
---|
| 733 | !! formulea, ice variables and read atmospheric fields. |
---|
| 734 | !! NB: ice drag coefficient is assumed to be a constant |
---|
| 735 | !!--------------------------------------------------------------------- |
---|
| 736 | INTEGER :: ji, jj ! dummy loop indices |
---|
[9019] | 737 | REAL(wp) :: zwndi_f , zwndj_f, zwnorm_f ! relative wind module and components at F-point |
---|
| 738 | REAL(wp) :: zwndi_t , zwndj_t ! relative wind components at T-point |
---|
[12926] | 739 | REAL(wp) :: zztmp1 , zztmp2 ! temporary values |
---|
[9019] | 740 | REAL(wp), DIMENSION(jpi,jpj) :: zrhoa ! transfer coefficient for momentum (tau) |
---|
[6723] | 741 | !!--------------------------------------------------------------------- |
---|
| 742 | ! |
---|
[9019] | 743 | ! set transfer coefficients to default sea-ice values |
---|
| 744 | Cd_atm(:,:) = Cd_ice |
---|
| 745 | Ch_atm(:,:) = Cd_ice |
---|
| 746 | Ce_atm(:,:) = Cd_ice |
---|
[6723] | 747 | |
---|
[9019] | 748 | wndm_ice(:,:) = 0._wp !!gm brutal.... |
---|
[7355] | 749 | |
---|
[9019] | 750 | ! ------------------------------------------------------------ ! |
---|
| 751 | ! Wind module relative to the moving ice ( U10m - U_ice ) ! |
---|
| 752 | ! ------------------------------------------------------------ ! |
---|
[9767] | 753 | ! C-grid ice dynamics : U & V-points (same as ocean) |
---|
| 754 | DO jj = 2, jpjm1 |
---|
| 755 | DO ji = fs_2, fs_jpim1 ! vect. opt. |
---|
| 756 | zwndi_t = ( sf(jp_wndi)%fnow(ji,jj,1) - rn_vfac * 0.5 * ( u_ice(ji-1,jj ) + u_ice(ji,jj) ) ) |
---|
| 757 | zwndj_t = ( sf(jp_wndj)%fnow(ji,jj,1) - rn_vfac * 0.5 * ( v_ice(ji ,jj-1) + v_ice(ji,jj) ) ) |
---|
| 758 | wndm_ice(ji,jj) = SQRT( zwndi_t * zwndi_t + zwndj_t * zwndj_t ) * tmask(ji,jj,1) |
---|
[9019] | 759 | END DO |
---|
[9767] | 760 | END DO |
---|
[10425] | 761 | CALL lbc_lnk( 'sbcblk', wndm_ice, 'T', 1. ) |
---|
[9767] | 762 | ! |
---|
[9019] | 763 | ! Make ice-atm. drag dependent on ice concentration |
---|
| 764 | IF ( ln_Cd_L12 ) THEN ! calculate new drag from Lupkes(2012) equations |
---|
| 765 | CALL Cdn10_Lupkes2012( Cd_atm ) |
---|
| 766 | Ch_atm(:,:) = Cd_atm(:,:) ! momentum and heat transfer coef. are considered identical |
---|
| 767 | ELSEIF( ln_Cd_L15 ) THEN ! calculate new drag from Lupkes(2015) equations |
---|
| 768 | CALL Cdn10_Lupkes2015( Cd_atm, Ch_atm ) |
---|
[7355] | 769 | ENDIF |
---|
| 770 | |
---|
[9019] | 771 | !! CALL iom_put( "Cd_ice", Cd_atm) ! output value of pure ice-atm. transfer coef. |
---|
| 772 | !! CALL iom_put( "Ch_ice", Ch_atm) ! output value of pure ice-atm. transfer coef. |
---|
| 773 | |
---|
[6723] | 774 | ! local scalars ( place there for vector optimisation purposes) |
---|
| 775 | ! Computing density of air! Way denser that 1.2 over sea-ice !!! |
---|
[7355] | 776 | zrhoa (:,:) = rho_air(sf(jp_tair)%fnow(:,:,1), sf(jp_humi)%fnow(:,:,1), sf(jp_slp)%fnow(:,:,1)) |
---|
[6723] | 777 | |
---|
[9019] | 778 | ! ------------------------------------------------------------ ! |
---|
| 779 | ! Wind stress relative to the moving ice ( U10m - U_ice ) ! |
---|
| 780 | ! ------------------------------------------------------------ ! |
---|
[12926] | 781 | zztmp1 = rn_vfac * 0.5_wp |
---|
| 782 | DO jj = 2, jpj ! at T point |
---|
| 783 | DO ji = 2, jpi |
---|
| 784 | zztmp2 = zrhoa(ji,jj) * Cd_atm(ji,jj) * wndm_ice(ji,jj) |
---|
| 785 | utau_ice(ji,jj) = zztmp2 * ( sf(jp_wndi)%fnow(ji,jj,1) - zztmp1 * ( u_ice(ji-1,jj ) + u_ice(ji,jj) ) ) |
---|
| 786 | vtau_ice(ji,jj) = zztmp2 * ( sf(jp_wndj)%fnow(ji,jj,1) - zztmp1 * ( v_ice(ji ,jj-1) + v_ice(ji,jj) ) ) |
---|
| 787 | END DO |
---|
| 788 | END DO |
---|
| 789 | ! |
---|
| 790 | DO jj = 2, jpjm1 ! U & V-points (same as ocean). |
---|
[9767] | 791 | DO ji = fs_2, fs_jpim1 ! vect. opt. |
---|
[12926] | 792 | ! take care of the land-sea mask to avoid "pollution" of coastal stress. p[uv]taui used in frazil and rheology |
---|
| 793 | zztmp1 = 0.5_wp * ( 2. - umask(ji,jj,1) ) * MAX( tmask(ji,jj,1),tmask(ji+1,jj ,1) ) |
---|
| 794 | zztmp2 = 0.5_wp * ( 2. - vmask(ji,jj,1) ) * MAX( tmask(ji,jj,1),tmask(ji ,jj+1,1) ) |
---|
| 795 | utau_ice(ji,jj) = zztmp1 * ( utau_ice(ji,jj) + utau_ice(ji+1,jj ) ) |
---|
| 796 | vtau_ice(ji,jj) = zztmp2 * ( vtau_ice(ji,jj) + vtau_ice(ji ,jj+1) ) |
---|
[6723] | 797 | END DO |
---|
[9767] | 798 | END DO |
---|
[10425] | 799 | CALL lbc_lnk_multi( 'sbcblk', utau_ice, 'U', -1., vtau_ice, 'V', -1. ) |
---|
[9019] | 800 | ! |
---|
[9767] | 801 | ! |
---|
[6723] | 802 | IF(ln_ctl) THEN |
---|
| 803 | CALL prt_ctl(tab2d_1=utau_ice , clinfo1=' blk_ice: utau_ice : ', tab2d_2=vtau_ice , clinfo2=' vtau_ice : ') |
---|
| 804 | CALL prt_ctl(tab2d_1=wndm_ice , clinfo1=' blk_ice: wndm_ice : ') |
---|
| 805 | ENDIF |
---|
[9019] | 806 | ! |
---|
[6723] | 807 | END SUBROUTINE blk_ice_tau |
---|
| 808 | |
---|
| 809 | |
---|
[9019] | 810 | SUBROUTINE blk_ice_flx( ptsu, phs, phi, palb ) |
---|
[6723] | 811 | !!--------------------------------------------------------------------- |
---|
| 812 | !! *** ROUTINE blk_ice_flx *** |
---|
| 813 | !! |
---|
[9019] | 814 | !! ** Purpose : provide the heat and mass fluxes at air-ice interface |
---|
[6723] | 815 | !! |
---|
| 816 | !! ** Method : compute heat and freshwater exchanged |
---|
| 817 | !! between atmosphere and sea-ice using bulk formulation |
---|
| 818 | !! formulea, ice variables and read atmmospheric fields. |
---|
| 819 | !! |
---|
| 820 | !! caution : the net upward water flux has with mm/day unit |
---|
| 821 | !!--------------------------------------------------------------------- |
---|
[6727] | 822 | REAL(wp), DIMENSION(:,:,:), INTENT(in) :: ptsu ! sea ice surface temperature |
---|
[9019] | 823 | REAL(wp), DIMENSION(:,:,:), INTENT(in) :: phs ! snow thickness |
---|
| 824 | REAL(wp), DIMENSION(:,:,:), INTENT(in) :: phi ! ice thickness |
---|
[6727] | 825 | REAL(wp), DIMENSION(:,:,:), INTENT(in) :: palb ! ice albedo (all skies) |
---|
[6723] | 826 | !! |
---|
[6727] | 827 | INTEGER :: ji, jj, jl ! dummy loop indices |
---|
[9454] | 828 | REAL(wp) :: zst3 ! local variable |
---|
[6727] | 829 | REAL(wp) :: zcoef_dqlw, zcoef_dqla ! - - |
---|
[13284] | 830 | REAL(wp) :: zztmp, z1_rLsub ! - - |
---|
[9454] | 831 | REAL(wp), DIMENSION(jpi,jpj,jpl) :: z1_st ! inverse of surface temperature |
---|
[9019] | 832 | REAL(wp), DIMENSION(jpi,jpj,jpl) :: z_qlw ! long wave heat flux over ice |
---|
| 833 | REAL(wp), DIMENSION(jpi,jpj,jpl) :: z_qsb ! sensible heat flux over ice |
---|
| 834 | REAL(wp), DIMENSION(jpi,jpj,jpl) :: z_dqlw ! long wave heat sensitivity over ice |
---|
| 835 | REAL(wp), DIMENSION(jpi,jpj,jpl) :: z_dqsb ! sensible heat sensitivity over ice |
---|
[9656] | 836 | REAL(wp), DIMENSION(jpi,jpj) :: zevap, zsnw ! evaporation and snw distribution after wind blowing (SI3) |
---|
[9019] | 837 | REAL(wp), DIMENSION(jpi,jpj) :: zrhoa |
---|
[13284] | 838 | REAL(wp), DIMENSION(jpi,jpj) :: ztri |
---|
[14717] | 839 | REAL(wp), DIMENSION(jpi,jpj) :: zcptrain, zcptsnw, zcptn ! Heat content per unit mass (J/kg) |
---|
[6723] | 840 | !!--------------------------------------------------------------------- |
---|
| 841 | ! |
---|
[9019] | 842 | zcoef_dqlw = 4.0 * 0.95 * Stef ! local scalars |
---|
| 843 | zcoef_dqla = -Ls * 11637800. * (-5897.8) |
---|
[6723] | 844 | ! |
---|
[6727] | 845 | zrhoa(:,:) = rho_air( sf(jp_tair)%fnow(:,:,1), sf(jp_humi)%fnow(:,:,1), sf(jp_slp)%fnow(:,:,1) ) |
---|
[6723] | 846 | ! |
---|
[14717] | 847 | ! Heat content per unit mass (J/kg) |
---|
| 848 | zcptrain(:,:) = ( sf(jp_tair)%fnow(:,:,1) - rt0 ) * rcp * tmask(:,:,1) |
---|
| 849 | zcptsnw (:,:) = ( MIN( sf(jp_tair)%fnow(:,:,1), rt0 ) - rt0 ) * rcpi * tmask(:,:,1) |
---|
| 850 | zcptn (:,:) = sst_m(:,:) * rcp * tmask(:,:,1) |
---|
| 851 | ! |
---|
[6723] | 852 | zztmp = 1. / ( 1. - albo ) |
---|
[9454] | 853 | WHERE( ptsu(:,:,:) /= 0._wp ) ; z1_st(:,:,:) = 1._wp / ptsu(:,:,:) |
---|
| 854 | ELSEWHERE ; z1_st(:,:,:) = 0._wp |
---|
| 855 | END WHERE |
---|
[7753] | 856 | ! ! ========================== ! |
---|
| 857 | DO jl = 1, jpl ! Loop over ice categories ! |
---|
| 858 | ! ! ========================== ! |
---|
[6723] | 859 | DO jj = 1 , jpj |
---|
| 860 | DO ji = 1, jpi |
---|
| 861 | ! ----------------------------! |
---|
| 862 | ! I Radiative FLUXES ! |
---|
| 863 | ! ----------------------------! |
---|
[9454] | 864 | zst3 = ptsu(ji,jj,jl) * ptsu(ji,jj,jl) * ptsu(ji,jj,jl) |
---|
[6723] | 865 | ! Short Wave (sw) |
---|
| 866 | qsr_ice(ji,jj,jl) = zztmp * ( 1. - palb(ji,jj,jl) ) * qsr(ji,jj) |
---|
| 867 | ! Long Wave (lw) |
---|
| 868 | z_qlw(ji,jj,jl) = 0.95 * ( sf(jp_qlw)%fnow(ji,jj,1) - Stef * ptsu(ji,jj,jl) * zst3 ) * tmask(ji,jj,1) |
---|
| 869 | ! lw sensitivity |
---|
| 870 | z_dqlw(ji,jj,jl) = zcoef_dqlw * zst3 |
---|
| 871 | |
---|
| 872 | ! ----------------------------! |
---|
| 873 | ! II Turbulent FLUXES ! |
---|
| 874 | ! ----------------------------! |
---|
| 875 | |
---|
[9019] | 876 | ! ... turbulent heat fluxes with Ch_atm recalculated in blk_ice_tau |
---|
[6723] | 877 | ! Sensible Heat |
---|
[9019] | 878 | z_qsb(ji,jj,jl) = zrhoa(ji,jj) * cpa * Ch_atm(ji,jj) * wndm_ice(ji,jj) * (ptsu(ji,jj,jl) - sf(jp_tair)%fnow(ji,jj,1)) |
---|
[6723] | 879 | ! Latent Heat |
---|
[9019] | 880 | qla_ice(ji,jj,jl) = rn_efac * MAX( 0.e0, zrhoa(ji,jj) * Ls * Ch_atm(ji,jj) * wndm_ice(ji,jj) * & |
---|
[9454] | 881 | & ( 11637800. * EXP( -5897.8 * z1_st(ji,jj,jl) ) / zrhoa(ji,jj) - sf(jp_humi)%fnow(ji,jj,1) ) ) |
---|
[6723] | 882 | ! Latent heat sensitivity for ice (Dqla/Dt) |
---|
| 883 | IF( qla_ice(ji,jj,jl) > 0._wp ) THEN |
---|
[9454] | 884 | dqla_ice(ji,jj,jl) = rn_efac * zcoef_dqla * Ch_atm(ji,jj) * wndm_ice(ji,jj) * & |
---|
| 885 | & z1_st(ji,jj,jl)*z1_st(ji,jj,jl) * EXP(-5897.8 * z1_st(ji,jj,jl)) |
---|
[6723] | 886 | ELSE |
---|
| 887 | dqla_ice(ji,jj,jl) = 0._wp |
---|
| 888 | ENDIF |
---|
| 889 | |
---|
| 890 | ! Sensible heat sensitivity (Dqsb_ice/Dtn_ice) |
---|
[9019] | 891 | z_dqsb(ji,jj,jl) = zrhoa(ji,jj) * cpa * Ch_atm(ji,jj) * wndm_ice(ji,jj) |
---|
[6723] | 892 | |
---|
| 893 | ! ----------------------------! |
---|
| 894 | ! III Total FLUXES ! |
---|
| 895 | ! ----------------------------! |
---|
| 896 | ! Downward Non Solar flux |
---|
| 897 | qns_ice (ji,jj,jl) = z_qlw (ji,jj,jl) - z_qsb (ji,jj,jl) - qla_ice (ji,jj,jl) |
---|
| 898 | ! Total non solar heat flux sensitivity for ice |
---|
| 899 | dqns_ice(ji,jj,jl) = - ( z_dqlw(ji,jj,jl) + z_dqsb(ji,jj,jl) + dqla_ice(ji,jj,jl) ) |
---|
| 900 | END DO |
---|
| 901 | ! |
---|
| 902 | END DO |
---|
| 903 | ! |
---|
| 904 | END DO |
---|
| 905 | ! |
---|
[9727] | 906 | tprecip(:,:) = sf(jp_prec)%fnow(:,:,1) * rn_pfac * tmask(:,:,1) ! total precipitation [kg/m2/s] |
---|
| 907 | sprecip(:,:) = sf(jp_snow)%fnow(:,:,1) * rn_pfac * tmask(:,:,1) ! solid precipitation [kg/m2/s] |
---|
[9019] | 908 | CALL iom_put( 'snowpre', sprecip ) ! Snow precipitation |
---|
| 909 | CALL iom_put( 'precip' , tprecip ) ! Total precipitation |
---|
[6723] | 910 | |
---|
| 911 | ! --- evaporation --- ! |
---|
[9935] | 912 | z1_rLsub = 1._wp / rLsub |
---|
| 913 | evap_ice (:,:,:) = rn_efac * qla_ice (:,:,:) * z1_rLsub ! sublimation |
---|
| 914 | devap_ice(:,:,:) = rn_efac * dqla_ice(:,:,:) * z1_rLsub ! d(sublimation)/dT |
---|
| 915 | zevap (:,:) = rn_efac * ( emp(:,:) + tprecip(:,:) ) ! evaporation over ocean |
---|
[6723] | 916 | |
---|
[7753] | 917 | ! --- evaporation minus precipitation --- ! |
---|
| 918 | zsnw(:,:) = 0._wp |
---|
[13284] | 919 | CALL ice_var_snwblow( (1.-at_i_b(:,:)), zsnw ) ! snow distribution over ice after wind blowing |
---|
[9019] | 920 | emp_oce(:,:) = ( 1._wp - at_i_b(:,:) ) * zevap(:,:) - ( tprecip(:,:) - sprecip(:,:) ) - sprecip(:,:) * (1._wp - zsnw ) |
---|
[7753] | 921 | emp_ice(:,:) = SUM( a_i_b(:,:,:) * evap_ice(:,:,:), dim=3 ) - sprecip(:,:) * zsnw |
---|
| 922 | emp_tot(:,:) = emp_oce(:,:) + emp_ice(:,:) |
---|
[6723] | 923 | |
---|
[7753] | 924 | ! --- heat flux associated with emp --- ! |
---|
[14717] | 925 | qemp_oce(:,:) = - ( 1._wp - at_i_b(:,:) ) * zevap(:,:) * zcptn(:,:) & ! evap at sst |
---|
| 926 | & + ( tprecip(:,:) - sprecip(:,:) ) * zcptrain(:,:) & ! liquid precip at Tair |
---|
| 927 | & + sprecip(:,:) * ( 1._wp - zsnw ) * ( zcptsnw (:,:) - rLfus ) ! solid precip at min(Tair,Tsnow) |
---|
| 928 | qemp_ice(:,:) = sprecip(:,:) * zsnw * ( zcptsnw (:,:) - rLfus ) ! solid precip (only) |
---|
[6723] | 929 | |
---|
[7753] | 930 | ! --- total solar and non solar fluxes --- ! |
---|
[9019] | 931 | qns_tot(:,:) = ( 1._wp - at_i_b(:,:) ) * qns_oce(:,:) + SUM( a_i_b(:,:,:) * qns_ice(:,:,:), dim=3 ) & |
---|
| 932 | & + qemp_ice(:,:) + qemp_oce(:,:) |
---|
| 933 | qsr_tot(:,:) = ( 1._wp - at_i_b(:,:) ) * qsr_oce(:,:) + SUM( a_i_b(:,:,:) * qsr_ice(:,:,:), dim=3 ) |
---|
[6723] | 934 | |
---|
[7753] | 935 | ! --- heat content of precip over ice in J/m3 (to be used in 1D-thermo) --- ! |
---|
[14717] | 936 | qprec_ice(:,:) = rhos * ( zcptsnw(:,:) - rLfus ) |
---|
[6723] | 937 | |
---|
[7504] | 938 | ! --- heat content of evap over ice in W/m2 (to be used in 1D-thermo) --- |
---|
| 939 | DO jl = 1, jpl |
---|
[9935] | 940 | qevap_ice(:,:,jl) = 0._wp ! should be -evap_ice(:,:,jl)*( ( Tice - rt0 ) * rcpi * tmask(:,:,1) ) |
---|
[9019] | 941 | ! ! But we do not have Tice => consider it at 0degC => evap=0 |
---|
[7504] | 942 | END DO |
---|
| 943 | |
---|
[13284] | 944 | ! --- shortwave radiation transmitted thru the surface scattering layer (W/m2) --- ! |
---|
| 945 | IF( nn_qtrice == 0 ) THEN |
---|
| 946 | ! formulation derived from Grenfell and Maykut (1977), where transmission rate |
---|
| 947 | ! 1) depends on cloudiness |
---|
| 948 | ! 2) is 0 when there is any snow |
---|
| 949 | ! 3) tends to 1 for thin ice |
---|
| 950 | ztri(:,:) = 0.18 * ( 1.0 - cloud_fra(:,:) ) + 0.35 * cloud_fra(:,:) ! surface transmission when hi>10cm |
---|
| 951 | DO jl = 1, jpl |
---|
| 952 | WHERE ( phs(:,:,jl) <= 0._wp .AND. phi(:,:,jl) < 0.1_wp ) ! linear decrease from hi=0 to 10cm |
---|
| 953 | qtr_ice_top(:,:,jl) = qsr_ice(:,:,jl) * ( ztri(:,:) + ( 1._wp - ztri(:,:) ) * ( 1._wp - phi(:,:,jl) * 10._wp ) ) |
---|
| 954 | ELSEWHERE( phs(:,:,jl) <= 0._wp .AND. phi(:,:,jl) >= 0.1_wp ) ! constant (ztri) when hi>10cm |
---|
| 955 | qtr_ice_top(:,:,jl) = qsr_ice(:,:,jl) * ztri(:,:) |
---|
| 956 | ELSEWHERE ! zero when hs>0 |
---|
| 957 | qtr_ice_top(:,:,jl) = 0._wp |
---|
| 958 | END WHERE |
---|
| 959 | ENDDO |
---|
| 960 | ELSEIF( nn_qtrice == 1 ) THEN |
---|
| 961 | ! formulation is derived from the thesis of M. Lebrun (2019). |
---|
| 962 | ! It represents the best fit using several sets of observations |
---|
| 963 | ! It comes with snow conductivities adapted to freezing/melting conditions (see icethd_zdf_bl99.F90) |
---|
| 964 | qtr_ice_top(:,:,:) = 0.3_wp * qsr_ice(:,:,:) |
---|
| 965 | ENDIF |
---|
[6723] | 966 | ! |
---|
[12276] | 967 | |
---|
| 968 | IF( iom_use('evap_ao_cea') .OR. iom_use('hflx_evap_cea') ) THEN |
---|
[14717] | 969 | CALL iom_put( 'evap_ao_cea' , zevap(:,:) * ( 1._wp - at_i_b(:,:) ) * tmask(:,:,1) ) ! ice-free oce evap (cell average) |
---|
| 970 | CALL iom_put( 'hflx_evap_cea', zevap(:,:) * ( 1._wp - at_i_b(:,:) ) * tmask(:,:,1) * zcptn(:,:) ) ! heat flux from evap (cell average) |
---|
[12276] | 971 | ENDIF |
---|
[14717] | 972 | IF( iom_use('rain') .OR. iom_use('rain_ao_cea') .OR. iom_use('hflx_rain_cea') ) THEN |
---|
| 973 | CALL iom_put( 'rain' , tprecip(:,:) - sprecip(:,:) ) ! liquid precipitation |
---|
| 974 | CALL iom_put( 'rain_ao_cea' , ( tprecip(:,:) - sprecip(:,:) ) * ( 1._wp - at_i_b(:,:) ) ) ! liquid precipitation over ocean (cell average) |
---|
| 975 | CALL iom_put( 'hflx_rain_cea', ( tprecip(:,:) - sprecip(:,:) ) * zcptrain(:,:) ) ! heat flux from rain (cell average) |
---|
[12276] | 976 | ENDIF |
---|
[14717] | 977 | IF( iom_use('snow_ao_cea') .OR. iom_use('snow_ai_cea') .OR. & |
---|
| 978 | & iom_use('hflx_snow_cea') .OR. iom_use('hflx_snow_ao_cea') .OR. iom_use('hflx_snow_ai_cea') ) THEN |
---|
| 979 | CALL iom_put( 'snow_ao_cea' , sprecip(:,:) * ( 1._wp - zsnw(:,:) ) ) ! Snow over ice-free ocean (cell average) |
---|
| 980 | CALL iom_put( 'snow_ai_cea' , sprecip(:,:) * zsnw(:,:) ) ! Snow over sea-ice (cell average) |
---|
| 981 | CALL iom_put( 'hflx_snow_cea' , sprecip(:,:) * ( zcptsnw(:,:) - rLfus ) ) ! heat flux from snow (cell average) |
---|
| 982 | CALL iom_put( 'hflx_snow_ao_cea', sprecip(:,:) * ( zcptsnw(:,:) - rLfus ) * ( 1._wp - zsnw(:,:) ) ) ! heat flux from snow (over ocean) |
---|
| 983 | CALL iom_put( 'hflx_snow_ai_cea', sprecip(:,:) * ( zcptsnw(:,:) - rLfus ) * zsnw(:,:) ) ! heat flux from snow (over ice) |
---|
[12276] | 984 | ENDIF |
---|
[14717] | 985 | IF( iom_use('hflx_prec_cea') ) THEN ! heat flux from precip (cell average) |
---|
| 986 | CALL iom_put('hflx_prec_cea' , sprecip(:,:) * ( zcptsnw (:,:) - rLfus ) & |
---|
| 987 | & + ( tprecip(:,:) - sprecip(:,:) ) * zcptrain(:,:) ) |
---|
| 988 | ENDIF |
---|
[12276] | 989 | ! |
---|
[14719] | 990 | IF( iom_use('subl_ai_cea') .OR. iom_use('hflx_subl_cea') ) THEN |
---|
| 991 | CALL iom_put( 'subl_ai_cea' , SUM( a_i_b(:,:,:) * evap_ice(:,:,:), dim=3 ) * tmask(:,:,1) ) ! Sublimation over sea-ice (cell average) |
---|
| 992 | CALL iom_put( 'hflx_subl_cea', SUM( a_i_b(:,:,:) * qevap_ice(:,:,:), dim=3 ) * tmask(:,:,1) ) ! Heat flux from sublimation (cell average) |
---|
| 993 | ENDIF |
---|
| 994 | |
---|
[6723] | 995 | IF(ln_ctl) THEN |
---|
| 996 | CALL prt_ctl(tab3d_1=qla_ice , clinfo1=' blk_ice: qla_ice : ', tab3d_2=z_qsb , clinfo2=' z_qsb : ', kdim=jpl) |
---|
| 997 | CALL prt_ctl(tab3d_1=z_qlw , clinfo1=' blk_ice: z_qlw : ', tab3d_2=dqla_ice, clinfo2=' dqla_ice : ', kdim=jpl) |
---|
| 998 | CALL prt_ctl(tab3d_1=z_dqsb , clinfo1=' blk_ice: z_dqsb : ', tab3d_2=z_dqlw , clinfo2=' z_dqlw : ', kdim=jpl) |
---|
| 999 | CALL prt_ctl(tab3d_1=dqns_ice, clinfo1=' blk_ice: dqns_ice : ', tab3d_2=qsr_ice , clinfo2=' qsr_ice : ', kdim=jpl) |
---|
| 1000 | CALL prt_ctl(tab3d_1=ptsu , clinfo1=' blk_ice: ptsu : ', tab3d_2=qns_ice , clinfo2=' qns_ice : ', kdim=jpl) |
---|
| 1001 | CALL prt_ctl(tab2d_1=tprecip , clinfo1=' blk_ice: tprecip : ', tab2d_2=sprecip , clinfo2=' sprecip : ') |
---|
| 1002 | ENDIF |
---|
| 1003 | ! |
---|
| 1004 | END SUBROUTINE blk_ice_flx |
---|
[6727] | 1005 | |
---|
[6723] | 1006 | |
---|
[10531] | 1007 | SUBROUTINE blk_ice_qcn( ld_virtual_itd, ptsu, ptb, phs, phi ) |
---|
[9019] | 1008 | !!--------------------------------------------------------------------- |
---|
| 1009 | !! *** ROUTINE blk_ice_qcn *** |
---|
[6723] | 1010 | !! |
---|
[9019] | 1011 | !! ** Purpose : Compute surface temperature and snow/ice conduction flux |
---|
| 1012 | !! to force sea ice / snow thermodynamics |
---|
[10534] | 1013 | !! in the case conduction flux is emulated |
---|
[9019] | 1014 | !! |
---|
| 1015 | !! ** Method : compute surface energy balance assuming neglecting heat storage |
---|
| 1016 | !! following the 0-layer Semtner (1976) approach |
---|
[6727] | 1017 | !! |
---|
[9019] | 1018 | !! ** Outputs : - ptsu : sea-ice / snow surface temperature (K) |
---|
| 1019 | !! - qcn_ice : surface inner conduction flux (W/m2) |
---|
| 1020 | !! |
---|
| 1021 | !!--------------------------------------------------------------------- |
---|
[10531] | 1022 | LOGICAL , INTENT(in ) :: ld_virtual_itd ! single-category option |
---|
[9076] | 1023 | REAL(wp), DIMENSION(:,:,:), INTENT(inout) :: ptsu ! sea ice / snow surface temperature |
---|
| 1024 | REAL(wp), DIMENSION(:,:) , INTENT(in ) :: ptb ! sea ice base temperature |
---|
| 1025 | REAL(wp), DIMENSION(:,:,:), INTENT(in ) :: phs ! snow thickness |
---|
| 1026 | REAL(wp), DIMENSION(:,:,:), INTENT(in ) :: phi ! sea ice thickness |
---|
[6723] | 1027 | ! |
---|
[9019] | 1028 | INTEGER , PARAMETER :: nit = 10 ! number of iterations |
---|
| 1029 | REAL(wp), PARAMETER :: zepsilon = 0.1_wp ! characteristic thickness for enhanced conduction |
---|
[6723] | 1030 | ! |
---|
[9019] | 1031 | INTEGER :: ji, jj, jl ! dummy loop indices |
---|
| 1032 | INTEGER :: iter ! local integer |
---|
| 1033 | REAL(wp) :: zfac, zfac2, zfac3 ! local scalars |
---|
| 1034 | REAL(wp) :: zkeff_h, ztsu, ztsu0 ! |
---|
| 1035 | REAL(wp) :: zqc, zqnet ! |
---|
| 1036 | REAL(wp) :: zhe, zqa0 ! |
---|
| 1037 | REAL(wp), DIMENSION(jpi,jpj,jpl) :: zgfac ! enhanced conduction factor |
---|
| 1038 | !!--------------------------------------------------------------------- |
---|
| 1039 | |
---|
| 1040 | ! -------------------------------------! |
---|
| 1041 | ! I Enhanced conduction factor ! |
---|
| 1042 | ! -------------------------------------! |
---|
[10531] | 1043 | ! Emulates the enhancement of conduction by unresolved thin ice (ld_virtual_itd = T) |
---|
[9019] | 1044 | ! Fichefet and Morales Maqueda, JGR 1997 |
---|
[6723] | 1045 | ! |
---|
[9019] | 1046 | zgfac(:,:,:) = 1._wp |
---|
| 1047 | |
---|
[10531] | 1048 | IF( ld_virtual_itd ) THEN |
---|
[9019] | 1049 | ! |
---|
[9935] | 1050 | zfac = 1._wp / ( rn_cnd_s + rcnd_i ) |
---|
[9019] | 1051 | zfac2 = EXP(1._wp) * 0.5_wp * zepsilon |
---|
| 1052 | zfac3 = 2._wp / zepsilon |
---|
| 1053 | ! |
---|
| 1054 | DO jl = 1, jpl |
---|
| 1055 | DO jj = 1 , jpj |
---|
| 1056 | DO ji = 1, jpi |
---|
[9935] | 1057 | zhe = ( rn_cnd_s * phi(ji,jj,jl) + rcnd_i * phs(ji,jj,jl) ) * zfac ! Effective thickness |
---|
[9019] | 1058 | IF( zhe >= zfac2 ) zgfac(ji,jj,jl) = MIN( 2._wp, 0.5_wp * ( 1._wp + LOG( zhe * zfac3 ) ) ) ! Enhanced conduction factor |
---|
| 1059 | END DO |
---|
| 1060 | END DO |
---|
| 1061 | END DO |
---|
| 1062 | ! |
---|
[10531] | 1063 | ENDIF |
---|
[9019] | 1064 | |
---|
| 1065 | ! -------------------------------------------------------------! |
---|
| 1066 | ! II Surface temperature and conduction flux ! |
---|
| 1067 | ! -------------------------------------------------------------! |
---|
[6723] | 1068 | ! |
---|
[9935] | 1069 | zfac = rcnd_i * rn_cnd_s |
---|
[6723] | 1070 | ! |
---|
[9019] | 1071 | DO jl = 1, jpl |
---|
| 1072 | DO jj = 1 , jpj |
---|
| 1073 | DO ji = 1, jpi |
---|
| 1074 | ! |
---|
| 1075 | zkeff_h = zfac * zgfac(ji,jj,jl) / & ! Effective conductivity of the snow-ice system divided by thickness |
---|
[9935] | 1076 | & ( rcnd_i * phs(ji,jj,jl) + rn_cnd_s * MAX( 0.01, phi(ji,jj,jl) ) ) |
---|
[9019] | 1077 | ztsu = ptsu(ji,jj,jl) ! Store current iteration temperature |
---|
| 1078 | ztsu0 = ptsu(ji,jj,jl) ! Store initial surface temperature |
---|
[9910] | 1079 | zqa0 = qsr_ice(ji,jj,jl) - qtr_ice_top(ji,jj,jl) + qns_ice(ji,jj,jl) ! Net initial atmospheric heat flux |
---|
[6727] | 1080 | ! |
---|
[9019] | 1081 | DO iter = 1, nit ! --- Iterative loop |
---|
| 1082 | zqc = zkeff_h * ( ztsu - ptb(ji,jj) ) ! Conduction heat flux through snow-ice system (>0 downwards) |
---|
| 1083 | zqnet = zqa0 + dqns_ice(ji,jj,jl) * ( ztsu - ptsu(ji,jj,jl) ) - zqc ! Surface energy budget |
---|
| 1084 | ztsu = ztsu - zqnet / ( dqns_ice(ji,jj,jl) - zkeff_h ) ! Temperature update |
---|
| 1085 | END DO |
---|
| 1086 | ! |
---|
| 1087 | ptsu (ji,jj,jl) = MIN( rt0, ztsu ) |
---|
| 1088 | qcn_ice(ji,jj,jl) = zkeff_h * ( ptsu(ji,jj,jl) - ptb(ji,jj) ) |
---|
| 1089 | qns_ice(ji,jj,jl) = qns_ice(ji,jj,jl) + dqns_ice(ji,jj,jl) * ( ptsu(ji,jj,jl) - ztsu0 ) |
---|
[9910] | 1090 | qml_ice(ji,jj,jl) = ( qsr_ice(ji,jj,jl) - qtr_ice_top(ji,jj,jl) + qns_ice(ji,jj,jl) - qcn_ice(ji,jj,jl) ) & |
---|
[9019] | 1091 | & * MAX( 0._wp , SIGN( 1._wp, ptsu(ji,jj,jl) - rt0 ) ) |
---|
[6723] | 1092 | |
---|
[9938] | 1093 | ! --- Diagnose the heat loss due to changing non-solar flux (as in icethd_zdf_bl99) --- ! |
---|
| 1094 | hfx_err_dif(ji,jj) = hfx_err_dif(ji,jj) - ( dqns_ice(ji,jj,jl) * ( ptsu(ji,jj,jl) - ztsu0 ) ) * a_i_b(ji,jj,jl) |
---|
| 1095 | |
---|
[9019] | 1096 | END DO |
---|
[6723] | 1097 | END DO |
---|
[9019] | 1098 | ! |
---|
| 1099 | END DO |
---|
| 1100 | ! |
---|
| 1101 | END SUBROUTINE blk_ice_qcn |
---|
| 1102 | |
---|
[6723] | 1103 | |
---|
[7355] | 1104 | SUBROUTINE Cdn10_Lupkes2012( Cd ) |
---|
| 1105 | !!---------------------------------------------------------------------- |
---|
| 1106 | !! *** ROUTINE Cdn10_Lupkes2012 *** |
---|
| 1107 | !! |
---|
[9019] | 1108 | !! ** Purpose : Recompute the neutral air-ice drag referenced at 10m |
---|
| 1109 | !! to make it dependent on edges at leads, melt ponds and flows. |
---|
[7355] | 1110 | !! After some approximations, this can be resumed to a dependency |
---|
| 1111 | !! on ice concentration. |
---|
| 1112 | !! |
---|
| 1113 | !! ** Method : The parameterization is taken from Lupkes et al. (2012) eq.(50) |
---|
| 1114 | !! with the highest level of approximation: level4, eq.(59) |
---|
| 1115 | !! The generic drag over a cell partly covered by ice can be re-written as follows: |
---|
| 1116 | !! |
---|
| 1117 | !! Cd = Cdw * (1-A) + Cdi * A + Ce * (1-A)**(nu+1/(10*beta)) * A**mu |
---|
| 1118 | !! |
---|
| 1119 | !! Ce = 2.23e-3 , as suggested by Lupkes (eq. 59) |
---|
| 1120 | !! nu = mu = beta = 1 , as suggested by Lupkes (eq. 59) |
---|
| 1121 | !! A is the concentration of ice minus melt ponds (if any) |
---|
| 1122 | !! |
---|
| 1123 | !! This new drag has a parabolic shape (as a function of A) starting at |
---|
| 1124 | !! Cdw(say 1.5e-3) for A=0, reaching 1.97e-3 for A~0.5 |
---|
| 1125 | !! and going down to Cdi(say 1.4e-3) for A=1 |
---|
| 1126 | !! |
---|
[7507] | 1127 | !! It is theoretically applicable to all ice conditions (not only MIZ) |
---|
[7355] | 1128 | !! => see Lupkes et al (2013) |
---|
| 1129 | !! |
---|
| 1130 | !! ** References : Lupkes et al. JGR 2012 (theory) |
---|
| 1131 | !! Lupkes et al. GRL 2013 (application to GCM) |
---|
| 1132 | !! |
---|
| 1133 | !!---------------------------------------------------------------------- |
---|
| 1134 | REAL(wp), DIMENSION(:,:), INTENT(inout) :: Cd |
---|
| 1135 | REAL(wp), PARAMETER :: zCe = 2.23e-03_wp |
---|
| 1136 | REAL(wp), PARAMETER :: znu = 1._wp |
---|
| 1137 | REAL(wp), PARAMETER :: zmu = 1._wp |
---|
| 1138 | REAL(wp), PARAMETER :: zbeta = 1._wp |
---|
| 1139 | REAL(wp) :: zcoef |
---|
| 1140 | !!---------------------------------------------------------------------- |
---|
| 1141 | zcoef = znu + 1._wp / ( 10._wp * zbeta ) |
---|
| 1142 | |
---|
| 1143 | ! generic drag over a cell partly covered by ice |
---|
[7507] | 1144 | !!Cd(:,:) = Cd_oce(:,:) * ( 1._wp - at_i_b(:,:) ) + & ! pure ocean drag |
---|
| 1145 | !! & Cd_ice * at_i_b(:,:) + & ! pure ice drag |
---|
| 1146 | !! & zCe * ( 1._wp - at_i_b(:,:) )**zcoef * at_i_b(:,:)**zmu ! change due to sea-ice morphology |
---|
[7355] | 1147 | |
---|
| 1148 | ! ice-atm drag |
---|
[7507] | 1149 | Cd(:,:) = Cd_ice + & ! pure ice drag |
---|
| 1150 | & zCe * ( 1._wp - at_i_b(:,:) )**zcoef * at_i_b(:,:)**(zmu-1._wp) ! change due to sea-ice morphology |
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[7355] | 1151 | |
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| 1152 | END SUBROUTINE Cdn10_Lupkes2012 |
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[9019] | 1153 | |
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| 1154 | |
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| 1155 | SUBROUTINE Cdn10_Lupkes2015( Cd, Ch ) |
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| 1156 | !!---------------------------------------------------------------------- |
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| 1157 | !! *** ROUTINE Cdn10_Lupkes2015 *** |
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| 1158 | !! |
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| 1159 | !! ** pUrpose : Alternative turbulent transfert coefficients formulation |
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| 1160 | !! between sea-ice and atmosphere with distinct momentum |
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| 1161 | !! and heat coefficients depending on sea-ice concentration |
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| 1162 | !! and atmospheric stability (no meltponds effect for now). |
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| 1163 | !! |
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| 1164 | !! ** Method : The parameterization is adapted from Lupkes et al. (2015) |
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| 1165 | !! and ECHAM6 atmospheric model. Compared to Lupkes2012 scheme, |
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| 1166 | !! it considers specific skin and form drags (Andreas et al. 2010) |
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| 1167 | !! to compute neutral transfert coefficients for both heat and |
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| 1168 | !! momemtum fluxes. Atmospheric stability effect on transfert |
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| 1169 | !! coefficient is also taken into account following Louis (1979). |
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| 1170 | !! |
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| 1171 | !! ** References : Lupkes et al. JGR 2015 (theory) |
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| 1172 | !! Lupkes et al. ECHAM6 documentation 2015 (implementation) |
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| 1173 | !! |
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| 1174 | !!---------------------------------------------------------------------- |
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| 1175 | ! |
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| 1176 | REAL(wp), DIMENSION(:,:), INTENT(inout) :: Cd |
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| 1177 | REAL(wp), DIMENSION(:,:), INTENT(inout) :: Ch |
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[10511] | 1178 | REAL(wp), DIMENSION(jpi,jpj) :: ztm_su, zst, zqo_sat, zqi_sat |
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[9019] | 1179 | ! |
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| 1180 | ! ECHAM6 constants |
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| 1181 | REAL(wp), PARAMETER :: z0_skin_ice = 0.69e-3_wp ! Eq. 43 [m] |
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| 1182 | REAL(wp), PARAMETER :: z0_form_ice = 0.57e-3_wp ! Eq. 42 [m] |
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| 1183 | REAL(wp), PARAMETER :: z0_ice = 1.00e-3_wp ! Eq. 15 [m] |
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| 1184 | REAL(wp), PARAMETER :: zce10 = 2.80e-3_wp ! Eq. 41 |
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| 1185 | REAL(wp), PARAMETER :: zbeta = 1.1_wp ! Eq. 41 |
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| 1186 | REAL(wp), PARAMETER :: zc = 5._wp ! Eq. 13 |
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| 1187 | REAL(wp), PARAMETER :: zc2 = zc * zc |
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| 1188 | REAL(wp), PARAMETER :: zam = 2. * zc ! Eq. 14 |
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| 1189 | REAL(wp), PARAMETER :: zah = 3. * zc ! Eq. 30 |
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| 1190 | REAL(wp), PARAMETER :: z1_alpha = 1._wp / 0.2_wp ! Eq. 51 |
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| 1191 | REAL(wp), PARAMETER :: z1_alphaf = z1_alpha ! Eq. 56 |
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| 1192 | REAL(wp), PARAMETER :: zbetah = 1.e-3_wp ! Eq. 26 |
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| 1193 | REAL(wp), PARAMETER :: zgamma = 1.25_wp ! Eq. 26 |
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| 1194 | REAL(wp), PARAMETER :: z1_gamma = 1._wp / zgamma |
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| 1195 | REAL(wp), PARAMETER :: r1_3 = 1._wp / 3._wp |
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| 1196 | ! |
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| 1197 | INTEGER :: ji, jj ! dummy loop indices |
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| 1198 | REAL(wp) :: zthetav_os, zthetav_is, zthetav_zu |
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| 1199 | REAL(wp) :: zrib_o, zrib_i |
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| 1200 | REAL(wp) :: zCdn_skin_ice, zCdn_form_ice, zCdn_ice |
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| 1201 | REAL(wp) :: zChn_skin_ice, zChn_form_ice |
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| 1202 | REAL(wp) :: z0w, z0i, zfmi, zfmw, zfhi, zfhw |
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| 1203 | REAL(wp) :: zCdn_form_tmp |
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| 1204 | !!---------------------------------------------------------------------- |
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| 1205 | |
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[10511] | 1206 | ! mean temperature |
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| 1207 | WHERE( at_i_b(:,:) > 1.e-20 ) ; ztm_su(:,:) = SUM( t_su(:,:,:) * a_i_b(:,:,:) , dim=3 ) / at_i_b(:,:) |
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| 1208 | ELSEWHERE ; ztm_su(:,:) = rt0 |
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| 1209 | ENDWHERE |
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| 1210 | |
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[9019] | 1211 | ! Momentum Neutral Transfert Coefficients (should be a constant) |
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| 1212 | zCdn_form_tmp = zce10 * ( LOG( 10._wp / z0_form_ice + 1._wp ) / LOG( rn_zu / z0_form_ice + 1._wp ) )**2 ! Eq. 40 |
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| 1213 | zCdn_skin_ice = ( vkarmn / LOG( rn_zu / z0_skin_ice + 1._wp ) )**2 ! Eq. 7 |
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| 1214 | zCdn_ice = zCdn_skin_ice ! Eq. 7 (cf Lupkes email for details) |
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| 1215 | !zCdn_ice = 1.89e-3 ! old ECHAM5 value (cf Eq. 32) |
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| 1216 | |
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| 1217 | ! Heat Neutral Transfert Coefficients |
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| 1218 | zChn_skin_ice = vkarmn**2 / ( LOG( rn_zu / z0_ice + 1._wp ) * LOG( rn_zu * z1_alpha / z0_skin_ice + 1._wp ) ) ! Eq. 50 + Eq. 52 (cf Lupkes email for details) |
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| 1219 | |
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| 1220 | ! Atmospheric and Surface Variables |
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[10511] | 1221 | zst(:,:) = sst_m(:,:) + rt0 ! convert SST from Celcius to Kelvin |
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| 1222 | zqo_sat(:,:) = 0.98_wp * q_sat( zst(:,:) , sf(jp_slp)%fnow(:,:,1) ) ! saturation humidity over ocean [kg/kg] |
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| 1223 | zqi_sat(:,:) = 0.98_wp * q_sat( ztm_su(:,:), sf(jp_slp)%fnow(:,:,1) ) ! saturation humidity over ice [kg/kg] |
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[9019] | 1224 | ! |
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| 1225 | DO jj = 2, jpjm1 ! reduced loop is necessary for reproducibility |
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| 1226 | DO ji = fs_2, fs_jpim1 |
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| 1227 | ! Virtual potential temperature [K] |
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[10511] | 1228 | zthetav_os = zst(ji,jj) * ( 1._wp + rctv0 * zqo_sat(ji,jj) ) ! over ocean |
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| 1229 | zthetav_is = ztm_su(ji,jj) * ( 1._wp + rctv0 * zqi_sat(ji,jj) ) ! ocean ice |
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| 1230 | zthetav_zu = t_zu (ji,jj) * ( 1._wp + rctv0 * q_zu(ji,jj) ) ! at zu |
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[9019] | 1231 | |
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| 1232 | ! Bulk Richardson Number (could use Ri_bulk function from aerobulk instead) |
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| 1233 | zrib_o = grav / zthetav_os * ( zthetav_zu - zthetav_os ) * rn_zu / MAX( 0.5, wndm(ji,jj) )**2 ! over ocean |
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| 1234 | zrib_i = grav / zthetav_is * ( zthetav_zu - zthetav_is ) * rn_zu / MAX( 0.5, wndm_ice(ji,jj) )**2 ! over ice |
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| 1235 | |
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| 1236 | ! Momentum and Heat Neutral Transfert Coefficients |
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| 1237 | zCdn_form_ice = zCdn_form_tmp * at_i_b(ji,jj) * ( 1._wp - at_i_b(ji,jj) )**zbeta ! Eq. 40 |
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| 1238 | zChn_form_ice = zCdn_form_ice / ( 1._wp + ( LOG( z1_alphaf ) / vkarmn ) * SQRT( zCdn_form_ice ) ) ! Eq. 53 |
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| 1239 | |
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| 1240 | ! Momentum and Heat Stability functions (possibility to use psi_m_ecmwf instead) |
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| 1241 | z0w = rn_zu * EXP( -1._wp * vkarmn / SQRT( Cdn_oce(ji,jj) ) ) ! over water |
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| 1242 | z0i = z0_skin_ice ! over ice (cf Lupkes email for details) |
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| 1243 | IF( zrib_o <= 0._wp ) THEN |
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| 1244 | zfmw = 1._wp - zam * zrib_o / ( 1._wp + 3._wp * zc2 * Cdn_oce(ji,jj) * SQRT( -zrib_o * ( rn_zu / z0w + 1._wp ) ) ) ! Eq. 10 |
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| 1245 | zfhw = ( 1._wp + ( zbetah * ( zthetav_os - zthetav_zu )**r1_3 / ( Chn_oce(ji,jj) * MAX(0.01, wndm(ji,jj)) ) & ! Eq. 26 |
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| 1246 | & )**zgamma )**z1_gamma |
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| 1247 | ELSE |
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| 1248 | zfmw = 1._wp / ( 1._wp + zam * zrib_o / SQRT( 1._wp + zrib_o ) ) ! Eq. 12 |
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| 1249 | zfhw = 1._wp / ( 1._wp + zah * zrib_o / SQRT( 1._wp + zrib_o ) ) ! Eq. 28 |
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| 1250 | ENDIF |
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| 1251 | |
---|
| 1252 | IF( zrib_i <= 0._wp ) THEN |
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| 1253 | zfmi = 1._wp - zam * zrib_i / (1._wp + 3._wp * zc2 * zCdn_ice * SQRT( -zrib_i * ( rn_zu / z0i + 1._wp))) ! Eq. 9 |
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| 1254 | zfhi = 1._wp - zah * zrib_i / (1._wp + 3._wp * zc2 * zCdn_ice * SQRT( -zrib_i * ( rn_zu / z0i + 1._wp))) ! Eq. 25 |
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| 1255 | ELSE |
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| 1256 | zfmi = 1._wp / ( 1._wp + zam * zrib_i / SQRT( 1._wp + zrib_i ) ) ! Eq. 11 |
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| 1257 | zfhi = 1._wp / ( 1._wp + zah * zrib_i / SQRT( 1._wp + zrib_i ) ) ! Eq. 27 |
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| 1258 | ENDIF |
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| 1259 | |
---|
| 1260 | ! Momentum Transfert Coefficients (Eq. 38) |
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| 1261 | Cd(ji,jj) = zCdn_skin_ice * zfmi + & |
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| 1262 | & zCdn_form_ice * ( zfmi * at_i_b(ji,jj) + zfmw * ( 1._wp - at_i_b(ji,jj) ) ) / MAX( 1.e-06, at_i_b(ji,jj) ) |
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| 1263 | |
---|
| 1264 | ! Heat Transfert Coefficients (Eq. 49) |
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| 1265 | Ch(ji,jj) = zChn_skin_ice * zfhi + & |
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| 1266 | & zChn_form_ice * ( zfhi * at_i_b(ji,jj) + zfhw * ( 1._wp - at_i_b(ji,jj) ) ) / MAX( 1.e-06, at_i_b(ji,jj) ) |
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| 1267 | ! |
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| 1268 | END DO |
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| 1269 | END DO |
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[10425] | 1270 | CALL lbc_lnk_multi( 'sbcblk', Cd, 'T', 1., Ch, 'T', 1. ) |
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[9019] | 1271 | ! |
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| 1272 | END SUBROUTINE Cdn10_Lupkes2015 |
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| 1273 | |
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[7355] | 1274 | #endif |
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| 1275 | |
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[6723] | 1276 | !!====================================================================== |
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| 1277 | END MODULE sbcblk |
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