MODULE limdia !!====================================================================== !! *** MODULE limdia *** !! diagnostics of ice model !!====================================================================== !! To add a new field !! 1) in lim_dia : add its definition for both hemispheres if wished !! 2) add the new titles in lim_dia_init !!---------------------------------------------------------------------- #if defined key_lim3 !!---------------------------------------------------------------------- !! 'key_lim3' : LIM3 sea-ice model !!---------------------------------------------------------------------- !! lim_dia : computation of the time evolution of keys var. !! lim_dia_init : initialization and namelist read !!---------------------------------------------------------------------- !! * Modules used USE phycst USE in_out_manager USE par_ice ! ice parameters USE sbc_ice ! ice variables USE daymod USE dom_ice USE ice USE iceini USE limistate USE dom_oce USE sbc_oce ! Surface boundary condition: ocean fields USE dom_oce USE lib_mpp IMPLICIT NONE PRIVATE !! * Routine accessibility PUBLIC lim_dia ! called by ice_step !! * Shared module variables INTEGER, PUBLIC :: & ntmoy = 1 , & !: instantaneous values of ice evolution or averaging ntmoy ninfo = 1 !: frequency of ouputs on file ice_evolu in case of averaging !! * Module variables INTEGER, PARAMETER :: & ! Parameters for outputs to files "evolu" jpinfmx = 100 , & ! maximum number of key variables jpchinf = 5 , & ! ??? jpchsep = jpchinf + 2 ! ??? INTEGER :: & nfrinf = 4 , & ! number of variables written in one line nferme , & ! last time step at which the var. are written on file nvinfo , & ! number of total variables nbvt , & ! number of time variables naveg ! number of step for accumulation before averaging CHARACTER(len=8) :: & fmtinf = '1PE13.5 ' ! format of the output values CHARACTER(len=30) :: & fmtw , & ! formats fmtr , & ! ??? fmtitr ! ??? CHARACTER(len=jpchsep), DIMENSION(jpinfmx) :: & titvar ! title of key variables REAL(wp), DIMENSION(jpinfmx) :: & vinfom ! temporary working space REAL(wp) :: & epsi06 = 1.e-06 REAL(wp), DIMENSION(jpi,jpj) :: & aire ! masked grid cell area !! * Substitutions # include "vectopt_loop_substitute.h90" !!---------------------------------------------------------------------- !! NEMO/LIM3 3.3 , UCL - NEMO Consortium (2010) !! $Id$ !! Software governed by the CeCILL licence (NEMOGCM/NEMO_CeCILL.txt) !!---------------------------------------------------------------------- CONTAINS SUBROUTINE lim_dia !!-------------------------------------------------------------------- !! *** ROUTINE lim_dia *** !! !! ** Purpose : Computation and outputs on file ice.evolu !! the temporal evolution of some key variables !! !! History : !! 8.0 ! 97-06 (Louvain-La-Neuve) Original code !! 8.5 ! 02-09 (C. Ethe , G. Madec ) F90: Free form and module !! 9.0 ! 05-06 (M. Vancoppenolle LLN) Rehabilitation and fixing a few bugs !! 01-07 (M. Vancoppenolle LLN) added new fields + fram strait !! export !!------------------------------------------------------------------- !! * Local variables INTEGER :: jv,ji,jj,jl ! dummy loop indices REAL(wp), DIMENSION(jpinfmx) :: & vinfor ! temporary working space REAL(wp) :: & zshift_date , & ! date from the minimum ice extent zday, zday_min, & ! current day, day of minimum extent zafy, zamy, & ! temporary area of fy and my ice zindb !!------------------------------------------------------------------- ! 0) date from the minimum of ice extent !--------------------------------------- zday_min = 273.0 ! zday_min = date of minimum extent, here September 30th zday = FLOAT(numit-nit000) * rdt_ice / ( 86400.0 * FLOAT(nn_fsbc) ) IF (zday.GT.zday_min) THEN zshift_date = zday - zday_min ELSE zshift_date = zday - (365.0 - zday_min) ENDIF IF( numit == nstart ) CALL lim_dia_init ! initialisation of ice_evolu file ! temporal diagnostics vinfor(1) = REAL(numit) vinfor(2) = nyear ! put everything to zero DO jv = nbvt + 1, nvinfo vinfor(jv) = 0.0 END DO !!------------------------------------------------------------------- !! 1) Northern hemisphere !!------------------------------------------------------------------- !! 1.1) Diagnostics independent on age !!------------------------------------ DO jj = njeq, jpjm1 DO ji = fs_2, fs_jpim1 ! vector opt. IF( tms(ji,jj) == 1 ) THEN vinfor(3) = vinfor(3) + at_i(ji,jj)*aire(ji,jj) / 1.0e12 !ice area IF (at_i(ji,jj).GT.0.15) vinfor(5) = vinfor(5) + aire(ji,jj) / 1.0e12 !ice extent vinfor(7) = vinfor(7) + vt_i(ji,jj)*aire(ji,jj) / 1.0e12 !ice volume vinfor(9) = vinfor(9) + vt_s(ji,jj)*aire(ji,jj) / 1.0e12 !snow volume vinfor(15) = vinfor(15) + ot_i(ji,jj) *vt_i(ji,jj)*aire(ji,jj) / 1.0e12 !mean age vinfor(29) = vinfor(29) + smt_i(ji,jj)*vt_i(ji,jj)*aire(ji,jj) / 1.0e12 !mean salinity ! the computation of this diagnostic is not reliable vinfor(31) = vinfor(31) + vt_i(ji,jj)*( u_ice(ji,jj)*u_ice(ji,jj) + & v_ice(ji,jj)*v_ice(ji,jj) )*aire(ji,jj)/1.0e12 vinfor(53) = vinfor(53) + emps(ji,jj)*aire(ji,jj) / 1.0e12 !salt flux vinfor(55) = vinfor(55) + fsbri(ji,jj)*aire(ji,jj) / 1.0e12 !brine drainage flux vinfor(57) = vinfor(57) + fseqv(ji,jj)*aire(ji,jj) / 1.0e12 !equivalent salt flux vinfor(59) = vinfor(59) +(sst_m(ji,jj)+rt0)*at_i(ji,jj)*aire(ji,jj) / 1.0e12 !SST vinfor(61) = vinfor(61) + sss_m(ji,jj)*at_i(ji,jj)*aire(ji,jj) / 1.0e12 !SSS vinfor(65) = vinfor(65) + et_s(ji,jj)/1.0e9*aire(ji,jj) / 1.0e12 ! snow temperature vinfor(67) = vinfor(67) + et_i(ji,jj)/1.0e9*aire(ji,jj) / 1.0e12 ! ice heat content vinfor(69) = vinfor(69) + v_i(ji,jj,1)*aire(ji,jj) / 1.0e12 !ice volume vinfor(71) = vinfor(71) + v_i(ji,jj,2)*aire(ji,jj) / 1.0e12 !ice volume vinfor(73) = vinfor(73) + v_i(ji,jj,3)*aire(ji,jj) / 1.0e12 !ice volume vinfor(75) = vinfor(75) + v_i(ji,jj,4)*aire(ji,jj) / 1.0e12 !ice volume vinfor(77) = vinfor(77) + v_i(ji,jj,5)*aire(ji,jj) / 1.0e12 !ice volume vinfor(79) = 0.0 vinfor(81) = vinfor(81) + emp(ji,jj)*aire(ji,jj) / 1.0e12 ! mass flux ENDIF END DO END DO DO jl = ice_cat_bounds(1,1), ice_cat_bounds(1,2) DO jj = njeq, jpjm1 DO ji = fs_2, fs_jpim1 ! vector opt. IF( tms(ji,jj) == 1 ) THEN vinfor(11) = vinfor(11) + v_i(ji,jj,jl)*aire(ji,jj) / 1.0e12 !undef def ice volume ENDIF END DO END DO END DO vinfor(13) = 0.0 vinfor(15) = vinfor(15) / MAX(vinfor(7),epsi06) ! these have to be divided by total ice volume to have the vinfor(29) = vinfor(29) / MAX(vinfor(7),epsi06) ! right value vinfor(31) = SQRT( vinfor(31) / MAX( vinfor(7) , epsi06 ) ) vinfor(67) = vinfor(67) / MAX(vinfor(7),epsi06) vinfor(53) = vinfor(53) / MAX(vinfor(5),epsi06) ! these have to be divided by total ice extent to have the vinfor(55) = vinfor(55) / MAX(vinfor(5),epsi06) ! right value vinfor(57) = vinfor(57) / MAX(vinfor(5),epsi06) ! vinfor(79) = vinfor(79) / MAX(vinfor(5),epsi06) ! zindb = 1.0 - MAX(0.0,SIGN(1.0,-vinfor(3))) ! vinfor(59) = zindb*vinfor(59) / MAX(vinfor(3),epsi06) ! divide by ice area vinfor(61) = zindb*vinfor(61) / MAX(vinfor(3),epsi06) ! zindb = 1.0 - MAX(0.0,SIGN(1.0,-vinfor(9))) ! vinfor(65) = zindb*vinfor(65) / MAX(vinfor(9),epsi06) ! divide it by snow volume DO jl = 1, jpl DO jj = njeq, jpjm1 DO ji = fs_2, fs_jpim1 ! vector opt. IF( tms(ji,jj) == 1 ) THEN vinfor(33) = vinfor(33) + d_v_i_trp(ji,jj,jl)*aire(ji,jj) / 1.0e12 !ice volume vinfor(35) = vinfor(35) + d_v_i_thd(ji,jj,jl)*aire(ji,jj) / 1.0e12 !ice volume ENDIF END DO END DO END DO DO jj = njeq, jpjm1 DO ji = fs_2, fs_jpim1 ! vector opt. IF( tms(ji,jj) == 1 ) THEN vinfor(37) = vinfor(37) + diag_sni_gr(ji,jj)*aire(ji,jj) / 1.0e12 !th growth rates vinfor(39) = vinfor(39) + diag_lat_gr(ji,jj)*aire(ji,jj) / 1.0e12 vinfor(41) = vinfor(41) + diag_bot_gr(ji,jj)*aire(ji,jj) / 1.0e12 vinfor(43) = vinfor(43) + diag_dyn_gr(ji,jj)*aire(ji,jj) / 1.0e12 vinfor(45) = vinfor(45) + dv_dt_thd(ji,jj,5)*aire(ji,jj) / 1.0e12 vinfor(47) = vinfor(47) + v_newice(ji,jj) *aire(ji,jj) / 1.0e12 / rdt_ice ! volume acc in OW ENDIF END DO END DO DO jl = 1, jpl DO jj = njeq, jpjm1 DO ji = fs_2, fs_jpim1 ! vector opt. IF( tms(ji,jj) == 1 ) THEN vinfor(63) = vinfor(63) + t_su(ji,jj,jl)*a_i(ji,jj,jl)*aire(ji,jj) / 1.0e12 ENDIF END DO END DO END DO vinfor(63) = vinfor(63) / MAX(vinfor(3),epsi06) ! these have to be divided by total ice area !! 1.2) Diagnostics dependent on age !!------------------------------------ DO jj = njeq, jpjm1 DO ji = fs_2, fs_jpim1 ! vector opt. IF( tms(ji,jj) == 1 ) THEN zafy = 0.0 zamy = 0.0 DO jl = 1, jpl IF ((o_i(ji,jj,jl) - zshift_date).LT.0.0) THEN vinfor(17) = vinfor(17) + a_i(ji,jj,jl)*aire(ji,jj) / 1.0e12 ! FY ice area vinfor(25) = vinfor(25) + v_i(ji,jj,jl)*aire(ji,jj) / 1.0e12 ! FY ice volume vinfor(49) = vinfor(49) + sm_i(ji,jj,jl)*v_i(ji,jj,jl)*aire(ji,jj) / 1.0e12 !FY ice salinity zafy = zafy + a_i(ji,jj,jl) ENDIF IF ((o_i(ji,jj,jl) - zshift_date).GT.0.0) THEN vinfor(19) = vinfor(19) + a_i(ji,jj,jl)*aire(ji,jj) / 1.0e12 ! MY ice area vinfor(27) = vinfor(27) + v_i(ji,jj,jl)*aire(ji,jj) / 1.0e12 ! MY ice volume vinfor(51) = vinfor(51) + sm_i(ji,jj,jl)*v_i(ji,jj,jl)*aire(ji,jj) / 1.0e12 !MY ice salinity zamy = zamy + a_i(ji,jj,jl) ENDIF END DO IF ((at_i(ji,jj).GT.0.15).AND.(zafy.GT.zamy)) THEN vinfor(21) = vinfor(21) + aire(ji,jj) / 1.0e12 ! Seasonal ice extent ENDIF IF ((at_i(ji,jj).GT.0.15).AND.(zafy.LE.zamy)) THEN vinfor(23) = vinfor(23) + aire(ji,jj) / 1.0e12 ! Perennial ice extent ENDIF ENDIF END DO END DO zindb = 1.0 - MAX(0.0,SIGN(1.0,-vinfor(25))) !=0 if no multiyear ice 1 if yes vinfor(49) = zindb*vinfor(49) / MAX(vinfor(25),epsi06) zindb = 1.0 - MAX(0.0,SIGN(1.0,-vinfor(27))) !=0 if no multiyear ice 1 if yes vinfor(51) = zindb*vinfor(51) / MAX(vinfor(27),epsi06) !! Fram Strait Export !! 83 = area export !! 84 = volume export !! Fram strait in ORCA2 = 5 points !! export = -v_ice*e1t*ddtb*at_i or -v_ice*e1t*ddtb*at_i*h_i jj = 136 ! C grid vinfor(83) = 0.0 vinfor(84) = 0.0 DO ji = 134, 138 vinfor(83) = vinfor(83) - v_ice(ji,jj) * & e1t(ji,jj)*at_i(ji,jj)*rdt_ice / 1.0e12 vinfor(84) = vinfor(84) - v_ice(ji,jj) * & e1t(ji,jj)*vt_i(ji,jj)*rdt_ice / 1.0e12 END DO !!------------------------------------------------------------------- !! 2) Southern hemisphere !!------------------------------------------------------------------- !! 2.1) Diagnostics independent on age !!------------------------------------ DO jj = 2, njeqm1 DO ji = fs_2, fs_jpim1 ! vector opt. IF( tms(ji,jj) == 1 ) THEN vinfor(4) = vinfor(4) + at_i(ji,jj)*aire(ji,jj) / 1.0e12 !ice area IF (at_i(ji,jj).GT.0.15) vinfor(6) = vinfor(6) + aire(ji,jj) / 1.0e12 !ice extent vinfor(8) = vinfor(8) + vt_i(ji,jj)*aire(ji,jj) / 1.0e12 !ice volume vinfor(10) = vinfor(10) + vt_s(ji,jj)*aire(ji,jj) / 1.0e12 !snow volume vinfor(16) = vinfor(16) + ot_i(ji,jj)*vt_i(ji,jj)*aire(ji,jj) / 1.0e12 !mean age vinfor(30) = vinfor(30) + smt_i(ji,jj)*vt_i(ji,jj)*aire(ji,jj) / 1.0e12 !mean salinity ! this diagnostic is not well computed (weighted by vol instead ! of area) vinfor(32) = vinfor(32) + vt_i(ji,jj)*( u_ice(ji,jj)*u_ice(ji,jj) + & v_ice(ji,jj)*v_ice(ji,jj) )*aire(ji,jj)/1.0e12 !ice vel vinfor(54) = vinfor(54) + at_i(ji,jj)*emps(ji,jj)*aire(ji,jj) / 1.0e12 ! Total salt flux vinfor(56) = vinfor(56) + at_i(ji,jj)*fsbri(ji,jj)*aire(ji,jj) / 1.0e12 ! Brine drainage salt flux vinfor(58) = vinfor(58) + at_i(ji,jj)*fseqv(ji,jj)*aire(ji,jj) / 1.0e12 ! Equivalent salt flux vinfor(60) = vinfor(60) +(sst_m(ji,jj)+rt0)*at_i(ji,jj)*aire(ji,jj) / 1.0e12 !SST vinfor(62) = vinfor(62) + sss_m(ji,jj)*at_i(ji,jj)*aire(ji,jj) / 1.0e12 !SSS vinfor(66) = vinfor(66) + et_s(ji,jj)/1.0e9*aire(ji,jj) / 1.0e12 ! snow temperature vinfor(68) = vinfor(68) + et_i(ji,jj)/1.0e9*aire(ji,jj) / 1.0e12 ! ice enthalpy vinfor(70) = vinfor(70) + v_i(ji,jj,1)*aire(ji,jj) / 1.0e12 !ice volume vinfor(72) = vinfor(72) + v_i(ji,jj,2)*aire(ji,jj) / 1.0e12 !ice volume vinfor(74) = vinfor(74) + v_i(ji,jj,3)*aire(ji,jj) / 1.0e12 !ice volume vinfor(76) = vinfor(76) + v_i(ji,jj,4)*aire(ji,jj) / 1.0e12 !ice volume vinfor(78) = vinfor(78) + v_i(ji,jj,5)*aire(ji,jj) / 1.0e12 !ice volume vinfor(80) = 0.0 vinfor(82) = vinfor(82) + emp(ji,jj)*aire(ji,jj) / 1.0e12 ! mass flux ENDIF END DO END DO DO jl = ice_cat_bounds(1,1), ice_cat_bounds(1,2) DO jj = 2, njeqm1 DO ji = fs_2, fs_jpim1 ! vector opt. vinfor(12) = vinfor(12) + v_i(ji,jj,jl)*aire(ji,jj) / 1.0e12 !undef def ice volume END DO END DO END DO vinfor(14) = 0.0 zindb = 1.0 - MAX(0.0,SIGN(1.0,-vinfor(8))) vinfor(16) = zindb * vinfor(16) / MAX(vinfor(8),epsi06) ! these have to be divided by ice vol vinfor(30) = zindb * vinfor(30) / MAX(vinfor(8),epsi06) ! vinfor(32) = zindb * SQRT( vinfor(32) / MAX( vinfor(8) , epsi06 ) ) vinfor(68) = zindb * vinfor(68) / MAX(vinfor(8),epsi06) ! zindb = 1.0 - MAX(0.0,SIGN(1.0,-vinfor(6))) vinfor(54) = zindb * vinfor(54) / MAX(vinfor(6),epsi06) ! these have to be divided by ice extt vinfor(56) = zindb * vinfor(56) / MAX(vinfor(6),epsi06) ! vinfor(58) = zindb * vinfor(58) / MAX(vinfor(6),epsi06) ! vinfor(80) = zindb * vinfor(80) / MAX(vinfor(6),epsi06) ! ! vinfor(84) = vinfor(84) / vinfor(6) ! zindb = 1.0 - MAX(0.0,SIGN(1.0,-vinfor(4))) ! vinfor(60) = zindb*vinfor(60) / ( MAX(vinfor(4), epsi06) ) ! divide by ice area vinfor(62) = zindb*vinfor(62) / ( MAX(vinfor(4), epsi06) ) ! zindb = 1.0 - MAX(0.0,SIGN(1.0,-vinfor(10))) ! vinfor(66) = zindb*vinfor(66) / MAX(vinfor(10),epsi06) ! divide it by snow volume DO jl = 1, jpl DO jj = 2, njeqm1 DO ji = fs_2, fs_jpim1 ! vector opt. IF( tms(ji,jj) == 1 ) THEN vinfor(34) = vinfor(34) + d_v_i_trp(ji,jj,jl)*aire(ji,jj) / 1.0e12 !ice volume vinfor(36) = vinfor(36) + d_v_i_thd(ji,jj,jl)*aire(ji,jj) / 1.0e12 !ice volume ENDIF END DO END DO END DO DO jj = 2, njeqm1 DO ji = fs_2, fs_jpim1 ! vector opt. IF( tms(ji,jj) == 1 ) THEN vinfor(38) = vinfor(38) + diag_sni_gr(ji,jj)*aire(ji,jj) / 1.0e12 !th growth rates vinfor(40) = vinfor(40) + diag_lat_gr(ji,jj)*aire(ji,jj) / 1.0e12 vinfor(42) = vinfor(42) + diag_bot_gr(ji,jj)*aire(ji,jj) / 1.0e12 vinfor(44) = vinfor(44) + diag_dyn_gr(ji,jj)*aire(ji,jj) / 1.0e12 vinfor(46) = vinfor(46) + dv_dt_thd(ji,jj,5)*aire(ji,jj) / 1.0e12 vinfor(48) = vinfor(48) + v_newice(ji,jj) *aire(ji,jj) / 1.0e12 / rdt_ice ! volume acc in OW ENDIF END DO END DO DO jl = 1, jpl DO jj = 2, njeqm1 DO ji = fs_2, fs_jpim1 ! vector opt. IF( tms(ji,jj) == 1 ) THEN vinfor(64) = vinfor(64) + t_su(ji,jj,jl)*a_i(ji,jj,jl)*aire(ji,jj) / 1.0e12 ENDIF END DO END DO END DO zindb = 1.0 - MAX(0.0,SIGN(1.0,-vinfor(4))) ! vinfor(64) = zindb * vinfor(64) / MAX(vinfor(4),epsi06) ! divide by ice extt !! 2.2) Diagnostics dependent on age !!------------------------------------ DO jj = 2, njeqm1 DO ji = fs_2, fs_jpim1 ! vector opt. IF( tms(ji,jj) == 1 ) THEN zafy = 0.0 zamy = 0.0 DO jl = 1, jpl IF ((o_i(ji,jj,jl) - zshift_date).LT.0.0) THEN vinfor(18) = vinfor(18) + a_i(ji,jj,jl)*aire(ji,jj) / 1.0e12 ! FY ice area vinfor(26) = vinfor(26) + v_i(ji,jj,jl)*aire(ji,jj) / 1.0e12 ! FY ice volume zafy = zafy + a_i(ji,jj,jl) vinfor(50) = vinfor(50) + sm_i(ji,jj,jl)*v_i(ji,jj,jl)*aire(ji,jj) / 1.0e12 !FY ice salinity ENDIF IF ((o_i(ji,jj,jl) - zshift_date).GT.0.0) THEN vinfor(20) = vinfor(20) + a_i(ji,jj,jl)*aire(ji,jj) / 1.0e12 ! MY ice area vinfor(28) = vinfor(28) + v_i(ji,jj,jl)*aire(ji,jj) / 1.0e12 vinfor(52) = vinfor(52) + sm_i(ji,jj,jl)*v_i(ji,jj,jl)*aire(ji,jj) / 1.0e12 !FY ice salinity zamy = zamy + a_i(ji,jj,jl) ENDIF END DO ! jl IF ((at_i(ji,jj).GT.0.15).AND.(zafy.GT.zamy)) THEN vinfor(22) = vinfor(22) + aire(ji,jj) / 1.0e12 ! Seasonal ice extent ENDIF IF ((at_i(ji,jj).GT.0.15).AND.(zafy.LE.zamy)) THEN vinfor(24) = vinfor(24) + aire(ji,jj) / 1.0e12 ! Perennial ice extent ENDIF ENDIF ! tms END DO ! jj END DO ! ji zindb = 1.0 - MAX(0.0,SIGN(1.0,-vinfor(26))) !=0 if no multiyear ice 1 if yes vinfor(50) = zindb*vinfor(50) / MAX(vinfor(26),epsi06) zindb = 1.0 - MAX(0.0,SIGN(1.0,-vinfor(28))) !=0 if no multiyear ice 1 if yes vinfor(52) = zindb*vinfor(52) / MAX(vinfor(28),epsi06) ! Accumulation before averaging DO jv = 1, nvinfo vinfom(jv) = vinfom(jv) + vinfor(jv) END DO naveg = naveg + 1 ! oututs on file ice_evolu !MV IF( MOD( numit , ninfo ) == 0 ) THEN WRITE(numevo_ice,fmtw) ( titvar(jv), vinfom(jv)/naveg, jv = 1, nvinfo ) naveg = 0 DO jv = 1, nvinfo vinfom(jv)=0.0 END DO !MV ENDIF END SUBROUTINE lim_dia SUBROUTINE lim_dia_init !!------------------------------------------------------------------- !! *** ROUTINE lim_dia_init *** !! !! ** Purpose : Preparation of the file ice_evolu for the output of !! the temporal evolution of key variables !! !! ** input : Namelist namicedia !! !! history : !! 8.5 ! 03-08 (C. Ethe) original code !! 9.0 ! 08-03 (M. Vancoppenolle) LIM3 !!------------------------------------------------------------------- NAMELIST/namicedia/fmtinf, nfrinf, ninfo, ntmoy INTEGER :: jv , & ! dummy loop indice & ntot , & & ndeb , & & irecl REAL(wp) :: zxx0, zxx1 ! temporary scalars CHARACTER(len=jpchinf) :: titinf CHARACTER(len=50) :: clname !!------------------------------------------------------------------- ! Read Namelist namicedia REWIND ( numnam_ice ) READ ( numnam_ice , namicedia ) IF(lwp) THEN WRITE(numout,*) WRITE(numout,*) 'lim_dia_init : ice parameters for ice diagnostics ' WRITE(numout,*) '~~~~~~~~~~~~' WRITE(numout,*) ' format of the output values fmtinf = ', fmtinf WRITE(numout,*) ' number of variables written in one line nfrinf = ', nfrinf WRITE(numout,*) ' Instantaneous values of ice evolution or averaging ntmoy = ', ntmoy WRITE(numout,*) ' frequency of ouputs on file ice_evolu in case of averaging ninfo = ', ninfo ENDIF ! masked grid cell area aire(:,:) = area(:,:) * tms(:,:) ! Titles of ice key variables : titvar(1) = 'NoIt' ! iteration number titvar(2) = 'T yr' ! time step in years nbvt = 2 ! number of time variables titvar(3) = 'AI_N' ! sea ice area in the northern Hemisp.(10^12 km2) titvar(4) = 'AI_S' ! sea ice area in the southern Hemisp.(10^12 km2) titvar(5) = 'EI_N' ! sea ice extent (15%) in the northern Hemisp.(10^12 km2) titvar(6) = 'EI_S' ! sea ice extent (15%) in the southern Hemisp.(10^12 km2) titvar(7) = 'VI_N' ! sea ice volume in the northern Hemisp.(10^3 km3) titvar(8) = 'VI_S' ! sea ice volume in the southern Hemisp.(10^3 km3) titvar(9) = 'VS_N' ! snow volume over sea ice in the northern Hemisp.(10^3 km3) titvar(10)= 'VS_S' ! snow volume over sea ice in the northern Hemisp.(10^3 km3) titvar(11)= 'VuIN' ! undeformed sea ice volume in the northern Hemisp.(10^3 km3) titvar(12)= 'VuIS' ! undeformed sea ice volume in the southern Hemisp.(10^3 km3) titvar(13)= 'VdIN' ! deformed sea ice volume in the northern Hemisp.(10^3 km3) titvar(14)= 'VdIS' ! deformed sea ice volume in the southern Hemisp.(10^3 km3) titvar(15)= 'OI_N' ! sea ice mean age in the northern Hemisp.(years) titvar(16)= 'OI_S' ! sea ice mean age in the southern Hemisp.(years) titvar(17)= 'AFYN' ! total FY ice area northern Hemisp.(10^12 km2) titvar(18)= 'AFYS' ! total FY ice area southern Hemisp.(10^12 km2) titvar(19)= 'AMYN' ! total MY ice area northern Hemisp.(10^12 km2) titvar(20)= 'AMYS' ! total MY ice area southern Hemisp.(10^12 km2) titvar(21)= 'EFYN' ! total FY ice extent northern Hemisp.(10^12 km2) (with more 50% FY ice) titvar(22)= 'EFYS' ! total FY ice extent southern Hemisp.(10^12 km2) (with more 50% FY ice) titvar(23)= 'EMYN' ! total MY ice extent northern Hemisp.(10^12 km2) (with more 50% MY ice) titvar(24)= 'EMYS' ! total MY ice extent southern Hemisp.(10^12 km2) (with more 50% MY ice) titvar(25)= 'VFYN' ! total undeformed FY ice volume northern Hemisp.(10^3 km3) titvar(26)= 'VFYS' ! total undeformed FY ice volume southern Hemisp.(10^3 km3) titvar(27)= 'VMYN' ! total undeformed MY ice volume northern Hemisp.(10^3 km3) titvar(28)= 'VMYS' ! total undeformed MY ice volume southern Hemisp.(10^3 km3) titvar(29)= 'IS_N' ! sea ice mean salinity in the northern hemisphere (ppt) titvar(30)= 'IS_S' ! sea ice mean salinity in the southern hemisphere (ppt) titvar(31)= 'IVeN' ! sea ice mean velocity in the northern hemisphere (m/s) titvar(32)= 'IVeS' ! sea ice mean velocity in the southern hemisphere (m/s) titvar(33)= 'DVDN' ! variation of sea ice volume due to dynamics in the northern hemisphere titvar(34)= 'DVDS' ! variation of sea ice volume due to dynamics in the southern hemisphere titvar(35)= 'DVTN' ! variation of sea ice volume due to thermo in the northern hemisphere titvar(36)= 'DVTS' ! variation of sea ice volume due to thermo in the southern hemisphere titvar(37)= 'TG1N' ! thermodynamic vertical growth rate in the northern hemisphere, cat 1 titvar(38)= 'TG1S' ! thermodynamic vertical growth rate in the souhtern hemisphere, cat 1 titvar(39)= 'TG2N' ! thermodynamic vertical growth rate in the northern hemisphere, cat 2 titvar(40)= 'TG2S' ! thermodynamic vertical growth rate in the souhtern hemisphere, cat 2 titvar(41)= 'TG3N' ! thermodynamic vertical growth rate in the northern hemisphere, cat 3 titvar(42)= 'TG3S' ! thermodynamic vertical growth rate in the souhtern hemisphere, cat 3 titvar(43)= 'TG4N' ! thermodynamic vertical growth rate in the northern hemisphere, cat 4 titvar(44)= 'TG4S' ! thermodynamic vertical growth rate in the souhtern hemisphere, cat 4 titvar(45)= 'TG5N' ! thermodynamic vertical growth rate in the northern hemisphere, cat 5 titvar(46)= 'TG5S' ! thermodynamic vertical growth rate in the souhtern hemisphere, cat 5 titvar(47)= 'LA_N' ! lateral accretion growth rate, northern hemisphere titvar(48)= 'LA_S' ! lateral accretion growth rate, southern hemisphere titvar(49)= 'SF_N' ! Salinity FY, NH titvar(50)= 'SF_S' ! Salinity FY, SH titvar(51)= 'SF_N' ! Salinity MY, NH titvar(52)= 'SF_S' ! Salinity MY, SH titvar(53)= 'Fs_N' ! Total salt flux NH titvar(54)= 'Fs_S' ! Total salt flux SH titvar(55)= 'FsbN' ! Salt - brine drainage flux NH titvar(56)= 'FsbS' ! Salt - brine drainage flux SH titvar(57)= 'FseN' ! Salt - Equivalent salt flux NH titvar(58)= 'FseS' ! Salt - Equivalent salt flux SH titvar(59)= 'SSTN' ! SST, NH titvar(60)= 'SSTS' ! SST, SH titvar(61)= 'SSSN' ! SSS, NH titvar(62)= 'SSSS' ! SSS, SH titvar(63)= 'TsuN' ! Tsu, NH titvar(64)= 'TsuS' ! Tsu, SH titvar(65)= 'TsnN' ! Tsn, NH titvar(66)= 'TsnS' ! Tsn, SH titvar(67)= 'ei_N' ! ei, NH titvar(68)= 'ei_S' ! ei, SH titvar(69)= 'vi1N' ! vi1, NH titvar(70)= 'vi1S' ! vi1, SH titvar(71)= 'vi2N' ! vi2, NH titvar(72)= 'vi2S' ! vi2, SH titvar(73)= 'vi3N' ! vi3, NH titvar(74)= 'vi3S' ! vi3, SH titvar(75)= 'vi4N' ! vi4, NH titvar(76)= 'vi4S' ! vi4, SH titvar(77)= 'vi5N' ! vi5, NH titvar(78)= 'vi5S' ! vi5, SH titvar(79)= 'vi6N' ! vi6, NH titvar(80)= 'vi6S' ! vi6, SH titvar(81)= 'fmaN' ! mass flux in the ocean, NH titvar(82)= 'fmaS' ! mass flux in the ocean, SH titvar(83)= 'AFSE' ! Fram Strait Area export titvar(84)= 'VFSE' ! Fram Strait Volume export nvinfo = 84 ! Definition et Ecriture de l'entete : nombre d'enregistrements ndeb = ( nstart - 1 ) / ninfo IF( nstart == 1 ) ndeb = -1 nferme = ( nstart - 1 + nitrun) / ninfo ntot = nferme - ndeb ndeb = ninfo * ( 1 + ndeb ) nferme = ninfo * nferme ! definition of formats WRITE( fmtw , '(A,I3,A2,I1,A)' ) '(', nfrinf, '(A', jpchsep, ','//fmtinf//'))' WRITE( fmtr , '(A,I3,A,I1,A)' ) '(', nfrinf, '(', jpchsep, 'X,'//fmtinf//'))' WRITE( fmtitr, '(A,I3,A,I1,A)' ) '(', nvinfo, 'A', jpchinf, ')' ! opening "ice_evolu" file IF ( lk_mpp ) THEN WRITE(clname,FMT="('ice.evolu_',I4.4)") narea-1 ELSE clname = 'ice.evolu' END IF irecl = ( jpchinf + 1 ) * nvinfo CALL ctl_opn( numevo_ice, clname, 'UNKNOWN', 'FORMATTED', 'SEQUENTIAL', & & irecl, numout, .TRUE., narea ) !- ecriture de 2 lignes d''entete : WRITE(numevo_ice,1000) fmtr, fmtw, fmtitr, nvinfo, ntot, 0, nfrinf zxx0 = 0.001 * REAL(ninfo) zxx1 = 0.001 * REAL(ndeb) WRITE(numevo_ice,1111) REAL(jpchinf), 0., zxx1, zxx0, 0., 0., 0 !- ecriture de 2 lignes de titre : WRITE(numevo_ice,'(A,I8,A,I8,A,I5)') & 'Evolution chronologique - Experience '//cexper & //' de', ndeb, ' a', nferme, ' pas', ninfo WRITE(numevo_ice,fmtitr) ( titvar(jv), jv = 1, nvinfo ) !--preparation de "titvar" pour l''ecriture parmi les valeurs numeriques : DO jv = 2 , nvinfo titinf = titvar(jv)(:jpchinf) titvar(jv) = ' '//titinf END DO !--Initialisation of the arrays for the accumulation DO jv = 1, nvinfo vinfom(jv) = 0. END DO naveg = 0 1000 FORMAT( 3(A20),4(1x,I6) ) 1111 FORMAT( 3(F7.1,1X,F7.3,1X),I3,A ) END SUBROUTINE lim_dia_init #else !!---------------------------------------------------------------------- !! Default option : NO LIM sea-ice model !!---------------------------------------------------------------------- CONTAINS SUBROUTINE lim_dia ! Empty routine END SUBROUTINE lim_dia #endif !!====================================================================== END MODULE limdia