cfgs/METO_GO/EXPREF/file_def_nemo-oce-CMIP6-INVALID_PERIOD.xml

+You can't use the standard diagnostic options with the current cycling period.
+Choose the "Custom" option, copy the file_def*.xml files that
+you want to use into the Rose app and adjust the meaning period
+accordingly. 

cfgs/METO_GO/EXPREF/iodef.xml

+<?xml version="1.0"?>
+<simulation> 
+
+<!-- ============================================================================================ -->
+<!-- XIOS context                                                                                 -->
+<!-- ============================================================================================ -->
+
+  <context id="xios" >
+
+      <variable_definition>
+	
+	  <variable id="info_level"                type="int">-1</variable>
+	  <variable id="using_server"              type="bool">true</variable>
+	  <variable id="using_oasis"               type="bool">false</variable>
+	  <variable id="oasis_codes_id"            type="string" >oceanx</variable>
+	
+      </variable_definition>
+  </context>
+
+<!-- ============================================================================================ -->
+<!-- NEMO  CONTEXT add and suppress the components you need                                       -->
+<!-- ============================================================================================ -->
+
+  <context id="nemo" src="./context_nemo.xml"/>       <!--  NEMO       -->
+
+</simulation>

cfgs/METO_GO/EXPREF/iodef_coupled.xml

+<?xml version="1.0"?>
+<simulation> 
+
+<!-- ============================================================================================ -->
+<!-- XIOS context                                                                                 -->
+<!-- ============================================================================================ -->
+
+  <context id="xios" >
+
+      <variable_definition>
+	
+	  <variable id="info_level"                type="int">-1</variable>
+	  <variable id="using_server"              type="bool">true</variable>
+	  <variable id="using_oasis"               type="bool">true</variable>
+	  <variable id="oasis_codes_id"            type="string" >toyoce</variable>
+	
+      </variable_definition>
+  </context>
+
+<!-- ============================================================================================ -->
+<!-- NEMO  CONTEXT add and suppress the components you need                                       -->
+<!-- ============================================================================================ -->
+
+  <context id="nemo" src="./context_nemo.xml"/>       <!--  NEMO       -->
+
+</simulation>

cfgs/SHARED/domain_def_nemo.xml

@@ -189,12 +189,14 @@
   <domain id="grid_F_inner" long_name="grid F inner"/>
 
   <!--   zonal mean grid   -->
-  <domain_group id="gznl">
-    <domain id="gznl" long_name="gznl"/>
-    <domain id="ptr" domain_ref="gznl" >
-      <zoom_domain id="ptr" ibegin="0000" jbegin="0" ni="1" nj="0000" />
-    </domain>
-  </domain_group>
+  <domain id="gznl" long_name="gznl"/>
+
+  <domain id="ptr" domain_ref="gznl" >
+    <zoom_domain id="ptr" ibegin="0000" jbegin="0" ni="1" nj="0000" />
+  </domain>
+  
+  <domain id="znl_T" domain_ref="gznl" > <zoom_domain id="znl_T"/> </domain>
+  <domain id="znl_W" domain_ref="gznl" > <zoom_domain id="znl_W"/> </domain>
 
 
   <!--   other grids   -->

cfgs/SHARED/field_def_nemo-ice.xml

@@ -50,10 +50,11 @@
       <field id="icevpnd"      long_name="melt pond volume"                                        standard_name="sea_ice_meltpond_volume"                   unit="m" />
       <field id="icehlid"      long_name="melt pond lid depth"                                     standard_name="sea_ice_meltpondlid_depth"                 unit="m" />
       <field id="icevlid"      long_name="melt pond lid volume"                                    standard_name="sea_ice_meltpondlid_volume"                unit="m" />
-      <field id="dvpn_mlt"     long_name="pond volume tendency due to surface melt"                standard_name="sea_ice_pondvolume_tendency_melt"          unit="kg/m2/s" />
-      <field id="dvpn_lid"     long_name="pond volume tendency due to exchanges with lid"          standard_name="sea_ice_pondvolume_tendency_lids"          unit="kg/m2/s" />
-      <field id="dvpn_rnf"     long_name="pond volume tendency due to runoff"                      standard_name="sea_ice_pondvolume_tendency_runoff"        unit="kg/m2/s" />
-      <field id="dvpn_drn"     long_name="pond volume tendency due to drainage"                    standard_name="sea_ice_pondvolume_tendency_drainage"      unit="kg/m2/s" />
+      <field id="iceepnd"      long_name="melt pond effective concentration"                       standard_name="sea_ice_meltpond_effective_concentration"  unit=""  />
+      <field id="dvpn_mlt"     long_name="pond volume tendency due to surface melt"                standard_name="sea_ice_pondvolume_tendency_melt"          unit="cm/d" />
+      <field id="dvpn_lid"     long_name="pond volume tendency due to exchanges with lid"          standard_name="sea_ice_pondvolume_tendency_lids"          unit="cm/d" />
+      <field id="dvpn_rnf"     long_name="pond volume tendency due to runoff"                      standard_name="sea_ice_pondvolume_tendency_runoff"        unit="cm/d" />
+      <field id="dvpn_drn"     long_name="pond volume tendency due to drainage"                    standard_name="sea_ice_pondvolume_tendency_drainage"      unit="cm/d" />
 
       <!-- heat -->
       <field id="icetemp"      long_name="Mean ice temperature"                                                                                              unit="degC" detect_missing_value="true" />
@@ -95,6 +96,10 @@
       <field id="yield12"      long_name="yield surface tensor component 12"                       standard_name="yield12"                                   unit="N/m"  />
       <field id="beta_evp"     long_name="Relaxation parameter of ice rheology (beta)"             standard_name="relaxation_parameter_of_ice_rheology"      unit=""  />
 
+      <field id="isig1"        long_name="1st principal stress component for EVP rhg"                                                                        unit=""     />
+      <field id="isig2"        long_name="2nd principal stress component for EVP rhg"                                                                        unit=""     />
+      <field id="isig3"        long_name="convergence measure for EVP rheology (must be around 1)"                                                           unit=""     />
+
       <!-- surface heat fluxes -->
       <field id="qt_ice"       long_name="total heat flux at ice surface"                          standard_name="surface_downward_heat_flux_in_air"         unit="W/m2" />
       <field id="qsr_ice"      long_name="solar heat flux at ice surface"                          standard_name="surface_downwelling_shortwave_flux_in_air" unit="W/m2" />
@@ -189,8 +194,15 @@
       <field id="icedrift_heat" long_name="Ice heat drift (conservation check)"   unit="W/m2"    />
 
       <!-- sbcssm variables -->
-      <field id="sst_m"    unit="degC" />
-      <field id="sss_m"    unit="psu"  />
+      <field id="sst_m_pot"    unit="degC" />
+      
+      <!-- EOS-80 -->
+      <field id="sss_m_pra"    unit="psu"  />
+      <!-- TEOS-10 -->
+      <field id="sss_m_abs"    unit="g/kg"  />
+      <!-- SEOS -->
+      <field id="sss_m_seos"   unit="psu"  />
+      
       <field id="ssu_m"    unit="m/s"  />
       <field id="ssv_m"    unit="m/s"  />
       <field id="ssh_m"    unit="m"    />
@@ -407,9 +419,17 @@
       <field field_ref="iceapnd"          name="siapnd" />
       <field field_ref="icehpnd"          name="sihpnd" />
       <field field_ref="icevpnd"          name="sivpnd" />
+      <field field_ref="iceepnd"          name="siepnd" />
       <field field_ref="iceage"           name="siage"  />
-      <field field_ref="sst_m"            name="sst_m"  />
-      <field field_ref="sss_m"            name="sss_m"  />
+      
+      <field id="sst_m_pot"    unit="degC" />
+      
+      <!-- EOS-80 -->
+      <field id="sss_m_pra"    unit="psu"  />
+      <!-- TEOS-10 -->
+      <field id="sss_m_abs"    unit="g/kg"  />
+      <!-- SEOS -->
+      <field id="sss_m_seos"   unit="psu"  />
 
       <!-- heat -->
       <field field_ref="icetemp"          name="sitemp" />
@@ -435,7 +455,7 @@
       <field field_ref="sheastr"          name="sheastr" />
       <field field_ref="sig1_pnorm"       name="sig1_pnorm"/>
       <field field_ref="sig2_pnorm"       name="sig2_pnorm"/>
-      <field field_ref="icedlt"           name="sidelt" />
+      <field field_ref="icedlt"           name="sidelta" />
 
       <!-- heat fluxes -->
       <field field_ref="qt_oce_ai"        name="qt_oce_ai"  />

cfgs/SHARED/grid_def_nemo.xml

@@ -418,5 +418,43 @@
       <duplicate_scalar />
     </axis>
   </grid>
+  
+  <grid id="grid_EqT" >
+    <domain id="EqT" />
+  </grid>
+  <!--  -->
+  <grid id="gznl_T_2D">
+    <domain id="ptr" />
+  </grid>
+  <!--  -->
+  <grid id="gznl_T_3D">
+    <domain id="ptr" />
+    <axis axis_ref="deptht" />
+  </grid>
+  <!--  -->
+  <grid id="gznl_W_2D">
+    <domain id="ptr" />
+  </grid>
+  <!--  -->
+  <grid id="gznl_W_3D">
+    <domain id="ptr" />
+    <axis axis_ref="depthw" />
+  </grid>
+  <grid id="vert_sum">
+    <domain id="grid_T"/>
+    <scalar>
+      <reduce_axis operation="sum" />
+    </scalar>
+  </grid>
+  <grid id="zoom_300">
+    <domain id="grid_T" />
+    <axis axis_ref="deptht300"/>
+  </grid>
+  <grid id="zoom_300_sum">
+    <domain id="grid_T" />
+    <scalar>
+      <reduce_axis operation="sum" />
+    </scalar>
+  </grid>
 
 </grid_definition>

cfgs/SHARED/namelist_ice_ref

@@ -24,10 +24,10 @@
    jpl              =   5             !  number of ice  categories
    nlay_i           =   2             !  number of ice  layers
    nlay_s           =   2             !  number of snow layers
-   ln_virtual_itd   =   .false.       !  virtual ITD mono-category parameterization (jpl=1 only)
-                                      !     i.e. enhanced thermal conductivity & virtual thin ice melting
-   ln_icedyn        = .true.          !  ice dynamics (T) or not (F)
-   ln_icethd        = .true.          !  ice thermo   (T) or not (F)
+   ln_virtual_itd   =   .false.,       !  virtual ITD mono-category parameterization (jpl=1 only)
+                                      !     i.e. enhan.false.ced thermal conductivity & virtual thin ice melting
+   ln_icedyn        = .true.,          !  ice dynamics (T) or not (F)
+   ln_icethd        = .true.,          !  ice thermo   (T) or not (F)
    rn_amax_n        =   0.997         !  maximum tolerated ice concentration NH
    rn_amax_s        =   0.997         !  maximum tolerated ice concentration SH
    cn_icerst_in     = "restart_ice"   !  suffix of ice restart name (input)
@@ -38,9 +38,9 @@
 !------------------------------------------------------------------------------
 &namitd         !   Ice discretization
 !------------------------------------------------------------------------------
-   ln_cat_hfn       = .true.          !  ice categories are defined by a function following rn_himean**(-0.05)
+   ln_cat_hfn       = .true.,          !  ice categories are defined by a function following rn_himean**(-0.05)
       rn_himean     =   2.0           !  expected domain-average ice thickness (m)
-   ln_cat_usr       = .false.         !  ice categories are defined by rn_catbnd below (m)
+   ln_cat_usr       = .false.,         !  ice categories are defined by rn_catbnd below (m)
       rn_catbnd     =   0.,0.45,1.1,2.1,3.7,6.0  
    rn_himin         =   0.1           !  minimum ice thickness (m) allowed
    rn_himax         =  99.0           !  maximum ice thickness (m) allowed
@@ -48,14 +48,14 @@
 !------------------------------------------------------------------------------
 &namdyn         !   Ice dynamics
 !------------------------------------------------------------------------------
-   ln_dynALL        = .true.          !  dyn.: full ice dynamics                  (rheology + advection + ridging/rafting + correction)
-   ln_dynRHGADV     = .false.         !  dyn.: no ridge/raft & no corrections     (rheology + advection)
-   ln_dynADV1D      = .false.         !  dyn.: only advection 1D                  (Schar & Smolarkiewicz 1996 test case)
-   ln_dynADV2D      = .false.         !  dyn.: only advection 2D w prescribed vel.(rn_uvice + advection)
+   ln_dynALL        = .true.,          !  dyn.: full ice dynamics                  (rheology + advection + ridging/rafting + correction)
+   ln_dynRHGADV     = .false.,         !  dyn.: no ridge/raft & no corrections     (rheology + advection)
+   ln_dynADV1D      = .false.,         !  dyn.: only advection 1D                  (Schar & Smolarkiewicz 1996 test case)
+   ln_dynADV2D      = .false.,         !  dyn.: only advection 2D w prescribed vel.(rn_uvice + advection)
       rn_uice       =   0.5           !        prescribed ice u-velocity
       rn_vice       =   0.5           !        prescribed ice v-velocity
    rn_ishlat        =   2.            !  lbc : free slip (0) ; partial slip (0-2) ; no slip (2) ; strong slip (>2)
-   ln_landfast_L16  = .false.         !  landfast: parameterization from Lemieux 2016
+   ln_landfast_L16  = .false.,         !  landfast: parameterization from Lemieux 2016
       rn_lf_depfra  =   0.125         !        fraction of ocean depth that ice must reach to initiate landfast
                                       !          recommended range: [0.1 ; 0.25]
       rn_lf_bfr     =  15.            !        maximum bottom stress per unit volume [N/m3]
@@ -72,30 +72,30 @@
 &namdyn_rdgrft  !   Ice ridging/rafting
 !------------------------------------------------------------------------------
           ! -- ice_rdgrft_strength -- !
-   ln_str_H79       = .true.          !  ice strength param.: Hibler_79   => P = pstar*<h>*exp(-c_rhg*A)
+   ln_str_H79       = .true.,          !  ice strength param.: Hibler_79   => P = pstar*<h>*exp(-c_rhg*A)
       rn_pstar      =   2.0e+04       !     ice strength thickness parameter [N/m2]
       rn_crhg       =  20.0           !     ice strength conc. parameter (-)
-   ln_str_R75       = .false.         !  ice strength param.: Rothrock_75 => P = fn of potential energy
+   ln_str_R75       = .false.,         !  ice strength param.: Rothrock_75 => P = fn of potential energy
       rn_pe_rdg     =  17.0           !     coef accouting for frictional dissipation
-   ln_str_CST       = .false.         !  ice strength param.: Constant
+   ln_str_CST       = .false.,         !  ice strength param.: Constant
       rn_str        =   0.0           !     ice strength value
-   ln_str_smooth    = .true.          !  spatial smoothing of the ice strength
+   ln_str_smooth    = .true.,          !  spatial smoothing of the ice strength
                    ! -- ice_rdgrft -- !
-   ln_distf_lin     = .true.          !  redistribution function of ridged ice: linear (Hibler 1980)
-   ln_distf_exp     = .false.         !  redistribution function of ridged ice: exponential => not coded yet
+   ln_distf_lin     = .true.,         !  redistribution function of ridged ice: linear (Hibler, 1980)
+   ln_distf_exp     = .false.,        !  redistribution function of ridged ice: exponential (Lipscomb et al., 2007)
       rn_murdg      =   3.0           !     e-folding scale of ridged ice (m**.5)
    rn_csrdg         =   0.5           !  fraction of shearing energy contributing to ridging
               ! -- ice_rdgrft_prep -- !
-   ln_partf_lin     = .false.         !  Linear ridging participation function (Thorndike et al, 1975)
+   ln_partf_lin     = .false.,         !  Linear ridging participation function (Thorndike et al., 1975)
       rn_gstar      =   0.15          !     fractional area of thin ice being ridged 
-   ln_partf_exp     = .true.          !  Exponential ridging participation function (Lipscomb, 2007)
+   ln_partf_exp     = .true.,          !  Exponential ridging participation function (Lipscomb et al., 2007)
       rn_astar      =   0.03          !     exponential measure of ridging ice fraction [set to 0.05 if hstar=100]
-   ln_ridging       = .true.          !  ridging activated (T) or not (F)
+   ln_ridging       = .true.,          !  ridging activated (T) or not (F)
       rn_hstar      =  25.0           !     determines the maximum thickness of ridged ice [m] (Hibler, 1980)
       rn_porordg    =   0.3           !     porosity of newly ridged ice (Lepparanta et al., 1995)
       rn_fsnwrdg    =   0.5           !     snow volume fraction that survives in ridging
       rn_fpndrdg    =   1.0           !     pond fraction that survives in ridging (small a priori)
-   ln_rafting       = .true.          !  rafting activated (T) or not (F)
+   ln_rafting       = .true.,          !  rafting activated (T) or not (F)
       rn_hraft      =   0.75          !     threshold thickness for rafting [m]
       rn_craft      =   5.0           !     squeezing coefficient used in the rafting function
       rn_fsnwrft    =   0.5           !     snow volume fraction that survives in rafting
@@ -104,9 +104,9 @@
 !------------------------------------------------------------------------------
 &namdyn_rhg     !   Ice rheology
 !------------------------------------------------------------------------------
-   ln_rhg_EVP       = .true.          !  EVP rheology
-   ln_rhg_EAP       = .false.         !  EAP rheology
-      ln_aEVP       = .true.          !     adaptive rheology (Kimmritz et al. 2016 & 2017)
+   ln_rhg_EVP       = .true.,          !  EVP rheology
+   ln_rhg_EAP       = .false.,         !  EAP rheology
+      ln_aEVP       = .true.,          !     adaptive rheology (Kimmritz et al. 2016 & 2017)
       rn_creepl     =   2.0e-9        !     creep limit [1/s]
       rn_ecc        =   2.0           !     eccentricity of the elliptical yield curve          
       nn_nevp       = 100             !     number of EVP subcycles                             
@@ -117,7 +117,7 @@
                                       !     = 1  check at the main time step (output xml: uice_cvg)
                                       !     = 2  check at both main and rheology time steps (additional output: ice_cvg.nc)
                                       !          this option 2 asks a lot of communications between cpu
-   ln_rhg_VP        = .false.         !  VP rheology
+   ln_rhg_VP        = .false.,         !  VP rheology
       nn_vp_nout    = 10              !     number of outer iterations
       nn_vp_ninn    = 1500            !     number of inner iterations
       nn_vp_chkcvg  = 5               !     iteration step for convergence check
@@ -125,8 +125,8 @@
 !------------------------------------------------------------------------------
 &namdyn_adv     !   Ice advection
 !------------------------------------------------------------------------------
-   ln_adv_Pra       = .true.          !  Advection scheme (Prather)
-   ln_adv_UMx       = .false.         !  Advection scheme (Ultimate-Macho)
+   ln_adv_Pra       = .true.,          !  Advection scheme (Prather)
+   ln_adv_UMx       = .false.,         !  Advection scheme (Ultimate-Macho)
       nn_UMx        =   5             !     order of the scheme for UMx (1-5 ; 20=centered 2nd order)
 /
 !------------------------------------------------------------------------------
@@ -144,8 +144,8 @@
                                       !     = 0  Average N(cat) fluxes then apply the average over the N(cat) ice
                                       !     = 1  Average N(cat) fluxes then redistribute over the N(cat) ice using T-ice and albedo sensitivity
                                       !     = 2  Redistribute a single flux over categories
-   ln_cndflx        = .false.         !  Use conduction flux as surface boundary conditions (i.e. for Jules coupling)
-      ln_cndemulate = .false.         !     emulate conduction flux (if not provided in the inputs)
+   ln_cndflx        = .false.,         !  Use conduction flux as surface boundary conditions (i.e. for Jules coupling)
+      ln_cndemulate = .false.,         !     emulate conduction flux (if not provided in the inputs)
    nn_qtrice        =   0             !  Solar flux transmitted thru the surface scattering layer:
                                       !     = 0  Grenfell and Maykut 1977 (depends on cloudiness and is 0 when there is snow) 
                                       !     = 1  Lebrun 2019 (equals 0.3 anytime with different melting/dry snw conductivities)
@@ -153,26 +153,26 @@
 !------------------------------------------------------------------------------
 &namthd         !   Ice thermodynamics
 !------------------------------------------------------------------------------
-   ln_icedH         = .true.          !  activate ice thickness change from growing/melting (T) or not (F)
-   ln_icedA         = .true.          !  activate lateral melting param. (T) or not (F)
-   ln_icedO         = .true.          !  activate ice growth in open-water (T) or not (F)
-   ln_icedS         = .true.          !  activate brine drainage (T) or not (F)
+   ln_icedH         = .true.,          !  activate ice thickness change from growing/melting (T) or not (F)
+   ln_icedA         = .true.,          !  activate lateral melting param. (T) or not (F)
+   ln_icedO         = .true.,          !  activate ice growth in open-water (T) or not (F)
+   ln_icedS         = .true.,          !  activate brine drainage (T) or not (F)
    !
-   ln_leadhfx       = .true.          !  heat in the leads is used to melt sea-ice before warming the ocean
+   ln_leadhfx       = .true.,          !  heat in the leads is used to melt sea-ice before warming the ocean
 /
 !------------------------------------------------------------------------------
 &namthd_zdf     !   Ice heat diffusion
 !------------------------------------------------------------------------------
-   ln_zdf_BL99      = .true.          !  Heat diffusion follows Bitz and Lipscomb 1999
-   ln_cndi_U64      = .false.         !  sea ice thermal conductivity: k = k0 + beta.S/T            (Untersteiner, 1964)
-   ln_cndi_P07      = .true.          !  sea ice thermal conductivity: k = k0 + beta1.S/T - beta2.T (Pringle et al., 2007)
+   ln_zdf_BL99      = .true.,          !  Heat diffusion follows Bitz and Lipscomb 1999
+   ln_cndi_U64      = .false.,         !  sea ice thermal conductivity: k = k0 + beta.S/T            (Untersteiner, 1964)
+   ln_cndi_P07      = .true.,          !  sea ice thermal conductivity: k = k0 + beta1.S/T - beta2.T (Pringle et al., 2007)
    rn_cnd_s         =   0.31          !  thermal conductivity of the snow (0.31 W/m/K, Maykut and Untersteiner, 1971)
                                       !     Obs: 0.1-0.5 (Lecomte et al, JAMES 2013)
    rn_kappa_i       =   1.0           !  radiation attenuation coefficient in sea ice                     [1/m]
    rn_kappa_s       =  10.0           !  nn_qtrice = 0: radiation attenuation coefficient in snow         [1/m]
    rn_kappa_smlt    =   7.0           !  nn_qtrice = 1: radiation attenuation coefficient in melting snow [1/m]
    rn_kappa_sdry    =  10.0           !                 radiation attenuation coefficient in dry snow     [1/m]
-   ln_zdf_chkcvg    = .false.         !  check convergence of heat diffusion scheme (outputs: tice_cvgerr, tice_cvgstp)
+   ln_zdf_chkcvg    = .false.,         !  check convergence of heat diffusion scheme (outputs: tice_cvgerr, tice_cvgstp)
 /
 !------------------------------------------------------------------------------
 &namthd_da      !   Ice lateral melting
@@ -189,7 +189,7 @@
 &namthd_do      !   Ice growth in open water
 !------------------------------------------------------------------------------
    rn_hinew         =   0.1           !  thickness for new ice formation in open water (m), must be larger than rn_himin
-   ln_frazil        = .false.         !  Frazil ice parameterization (ice collection as a function of wind)
+   ln_frazil        = .false.,         !  Frazil ice parameterization (ice collection as a function of wind)
       rn_maxfraz    =   1.0           !     maximum fraction of frazil ice collecting at the ice base
       rn_vfraz      =   0.417         !     thresold drift speed for frazil ice collecting at the ice bottom (m/s)
       rn_Cfraz      =   5.0           !     squeezing coefficient for frazil ice collecting at the ice bottom
@@ -212,22 +212,25 @@
 !------------------------------------------------------------------------------
 &namthd_pnd     !   Melt ponds
 !------------------------------------------------------------------------------
-   ln_pnd            = .true.         !  activate melt ponds or not
-      ln_pnd_TOPO    = .false.        !  topographic melt ponds
-      ln_pnd_LEV     = .true.         !  level ice melt ponds
+   ln_pnd            = .true.,         !  activate melt ponds or not
+      ln_pnd_TOPO    = .false.,        !  topographic melt ponds
+      ln_pnd_LEV     = .true.,         !  level ice melt ponds
          rn_apnd_min =   0.15         !     minimum meltwater fraction contributing to pond growth (TOPO and LEV)
          rn_apnd_max =   0.85         !     maximum meltwater fraction contributing to pond growth (TOPO and LEV)
          rn_pnd_flush=   0.1          !     pond flushing efficiency (tuning parameter) (LEV)
-      ln_pnd_CST     = .false.        !  constant  melt ponds
+      ln_pnd_CST     = .false.,        !  constant  melt ponds
          rn_apnd     =   0.2          !     prescribed pond fraction, at Tsu=0 degC
          rn_hpnd     =   0.05         !     prescribed pond depth,    at Tsu=0 degC
-      ln_pnd_lids    = .true.         !  frozen lids on top of the ponds (only for ln_pnd_LEV)
-      ln_pnd_alb     = .true.         !  effect of melt ponds on ice albedo
+      ln_pnd_lids    = .true.,         !  frozen lids on top of the ponds (only for ln_pnd_LEV)
+      ln_pnd_alb     = .true.,         !  effect of melt ponds on ice albedo
+      nn_pnd_brsal   = 0              !  brine salinity formulation 0 = Consistent expression with SI3 
+                                      !                                 (linear liquidus)
+                                      !                             1 = used in GOSI9
 /
 !------------------------------------------------------------------------------
 &namini         !   Ice initialization
 !------------------------------------------------------------------------------
-   ln_iceini        = .true.          !  activate ice initialization (T) or not (F)
+   ln_iceini        = .true.,          !  activate ice initialization (T) or not (F)
    nn_iceini_file   =   0             !     0 = Initialise sea ice based on SSTs
                                       !     1 = Initialise sea ice from single category netcdf file
                                       !     2 = Initialise sea ice from multi category restart file
@@ -280,12 +283,12 @@
 !------------------------------------------------------------------------------
 &namdia         !   Diagnostics
 !------------------------------------------------------------------------------
-   ln_icediachk     = .false.         !  check online heat, mass & salt budgets
+   ln_icediachk     = .false.,         !  check online heat, mass & salt budgets
       !                               !   rate of ice spuriously gained/lost at each time step => rn_icechk=1 <=> 1.e-6 m/hour
       rn_icechk_cel =  1.             !     check at each gridcell          (1.e-06m/h)=> stops the code if violated (and writes a file)
       rn_icechk_glo =  1.e-04         !     check over the entire ice cover (1.e-10m/h)=> only prints warnings
-   ln_icediahsb     = .false.         !  output the heat, mass & salt budgets (T) or not (F)
-   ln_icectl        = .false.         !  ice points output for debug (T or F)
+   ln_icediahsb     = .false.,         !  output the heat, mass & salt budgets (T) or not (F)
+   ln_icectl        = .false.,         !  ice points output for debug (T or F)
       iiceprt       =  10             !     i-index for debug
       jiceprt       =  10             !     j-index for debug
 /

cfgs/SHARED/namelist_top_ref

@@ -13,8 +13,8 @@
 !-----------------------------------------------------------------------
 &namtrc_run      !   run information
 !-----------------------------------------------------------------------
-   ln_top_euler  = .false.   !  use Euler time-stepping for TOP
-   ln_rsttr      = .false.   !  start from a restart file (T) or not (F)
+   ln_top_euler  = .false.,  !  use Euler time-stepping for TOP
+   ln_rsttr      = .false.,  !  start from a restart file (T) or not (F)
    nn_rsttr      =   0       !  restart control = 0 initial time step is not compared to the restart file value
                              !                  = 1 do not use the value in the restart file
                              !                  = 2 calendar parameters read in the restart file
@@ -28,19 +28,19 @@
 !-----------------------------------------------------------------------
    jp_bgc        =  0           !  Number of passive tracers of the BGC model
    !
-   ln_pisces     =  .false.     !  Run PISCES BGC model 
-   ln_my_trc     =  .false.     !  Run MY_TRC BGC model
-   ln_age        =  .false.     !  Run the sea water age tracer
-   ln_cfc11      =  .false.     !  Run the CFC11 passive tracer
-   ln_cfc12      =  .false.     !  Run the CFC12 passive tracer
-   ln_sf6        =  .false.     !  Run the SF6 passive tracer
-   ln_c14        =  .false.     !  Run the Radiocarbon passive tracer
+   ln_pisces     =  .false.,    !  Run PISCES BGC model 
+   ln_my_trc     =  .false.,    !  Run MY_TRC BGC model
+   ln_age        =  .false.,    !  Run the sea water age tracer
+   ln_cfc11      =  .false.,    !  Run the CFC11 passive tracer
+   ln_cfc12      =  .false.,    !  Run the CFC12 passive tracer
+   ln_sf6        =  .false.,    !  Run the SF6 passive tracer
+   ln_c14        =  .false.,    !  Run the Radiocarbon passive tracer
    !
-   ln_trcdta     =  .false.  !  Initialisation from data input file (T) or not (F)
-   ln_trcdmp     =  .false.  !  add a damping termn (T) or not (F)
-   ln_trcdmp_clo =  .false.  !  damping term (T) or not (F) on closed seas
-   ln_trcbc      =  .false.  !  Surface, Lateral or Open Boundaries conditions
-   ln_trcais     =  .false.  !  Antarctic Ice Sheet nutrient supply
+   ln_trcdta     =  .false., !  Initialisation from data input file (T) or not (F)
+   ln_trcdmp     =  .false., !  add a damping termn (T) or not (F)
+   ln_trcdmp_clo =  .false., !  damping term (T) or not (F) on closed seas
+   ln_trcbc      =  .false., !  Surface, Lateral or Open Boundaries conditions
+   ln_trcais     =  .false., !  Antarctic Ice Sheet nutrient supply
    !
    jp_dia3d      = 0         ! Number of 3D diagnostic variables
    jp_dia2d      = 0         ! Number of 2D diagnostic variables
@@ -66,25 +66,25 @@
 !-----------------------------------------------------------------------
 &namtrc_adv      !   advection scheme for passive tracer                (default: NO selection)
 !-----------------------------------------------------------------------
-   ln_trcadv_OFF =  .false.  !  No passive tracer advection
-   ln_trcadv_cen =  .false.  !  2nd order centered scheme
+   ln_trcadv_OFF =  .false., !  No passive tracer advection
+   ln_trcadv_cen =  .false., !  2nd order centered scheme
       nn_cen_h   =  4               !  =2/4, horizontal 2nd order CEN / 4th order CEN
       nn_cen_v   =  4               !  =2/4, vertical   2nd order CEN / 4th order COMPACT
-   ln_trcadv_fct =  .false.  !  FCT scheme
+   ln_trcadv_fct =  .false., !  FCT scheme
       nn_fct_h   =  2               !  =2/4, horizontal 2nd / 4th order 
       nn_fct_v   =  2               !  =2/4, vertical   2nd / COMPACT 4th order 
-   ln_trcadv_mus =  .false.  !  MUSCL scheme
-      ln_mus_ups =  .false.         !  use upstream scheme near river mouths
-   ln_trcadv_ubs =  .false.  !  UBS scheme
+   ln_trcadv_mus =  .false., !  MUSCL scheme
+      ln_mus_ups =  .false.,        !  use upstream scheme near river mouths
+   ln_trcadv_ubs =  .false., !  UBS scheme
       nn_ubs_v   =  2               !  =2  , vertical 2nd order FCT
-   ln_trcadv_qck =  .false.  !  QUICKEST scheme
+   ln_trcadv_qck =  .false., !  QUICKEST scheme
 /
 !-----------------------------------------------------------------------
 &namtrc_ldf      !   lateral diffusion scheme for passive tracer        (default: NO selection)
 !-----------------------------------------------------------------------
 !                            !  Type of the operator:
-   ln_trcldf_OFF   =  .false.    !  No explicit diffusion
-   ln_trcldf_tra   =  .false.    !  use active tracer setting
+   ln_trcldf_OFF   =  .false.,   !  No explicit diffusion
+   ln_trcldf_tra   =  .false.,   !  use active tracer setting
    !                         !  Coefficient (defined with namtra_ldf coefficient)
    rn_ldf_multi    = 1.          !  multiplier of aht for TRC mixing coefficient
    rn_fact_lap     = 1.          !  Equatorial enhanced zonal eddy diffusivity (lap only)
@@ -92,7 +92,7 @@
 !-----------------------------------------------------------------------
 &namtrc_rad      !  treatment of negative concentrations 
 !-----------------------------------------------------------------------
-   ln_trcrad     =  .true.   !  artificially correct negative concentrations (T) or not (F)
+   ln_trcrad     =  .true.,  !  artificially correct negative concentrations (T) or not (F)
 /
 !-----------------------------------------------------------------------
 &namtrc_snk      !  Sedimentation of particles
@@ -102,7 +102,7 @@
 !-----------------------------------------------------------------------
 &namtrc_dcy      !  Diurnal cycle
 !-----------------------------------------------------------------------
-   ln_trcdc2dm   =  .false.   !  Diurnal cycle for TOP
+   ln_trcdc2dm   =  .false.,  !  Diurnal cycle for TOP
 /
 !-----------------------------------------------------------------------
 &namtrc_opt      !  light availability in the water column
@@ -111,7 +111,7 @@
 !                !                  !  (if <0  months)  !   name    !   (logical)  !  (T/F) ! 'monthly' ! filename ! pairing  ! filename      !
    sn_par        = 'par.orca'       ,     24            , 'fr_par'  ,  .true.      , .true. , 'yearly'  , ''       , ''       , ''
    cn_dir        = './'        ! root directory for the location of the dynamical files
-   ln_varpar     =  .true.     ! Read PAR from file
+   ln_varpar     =  .true.,    ! Read PAR from file
    parlux        =  0.43       ! Fraction of shortwave as PAR
    light_loc     = 'center'    ! Light location in the water cell ('center', 'integral')
 /
@@ -138,8 +138,8 @@
    nn_trd_trc    =  5475     !  time step frequency and tracers trends
    nn_ctls_trc   =   0       !  control surface type in mixed-layer trends (0,1 or n<jpk)
    rn_ucf_trc    =   1       !  unit conversion factor (=1 -> /seconds ; =86400. -> /day)
-   ln_trdmld_trc_restart = .false. !  restart for ML diagnostics
-   ln_trdmld_trc_instant = .true.  !  flag to diagnose trends of instantantaneous or mean ML T/S
+   ln_trdmld_trc_restart = .false.,!  restart for ML diagnostics
+   ln_trdmld_trc_instant = .true., !  flag to diagnose trends of instantantaneous or mean ML T/S
    ln_trdtrc( 1) = .true.
    ln_trdtrc( 2) = .true.
    ln_trdtrc(23) = .true.
@@ -158,7 +158,7 @@
    cn_dir_sbc    =  './'     !  root directory for the location of SURFACE data files
    cn_dir_cbc    =  './'     !  root directory for the location of COASTAL data files
    cn_dir_obc    =  './'     !  root directory for the location of OPEN data files
-   ln_rnf_ctl    = .false.   !  Remove runoff dilution on tracers with absent river load
+   ln_rnf_ctl    = .false.,  !  Remove runoff dilution on tracers with absent river load
    rn_sbc_time   =  86400.   !  Time scaling factor for SBC data (seconds in a day)
    rn_cbc_time   =  86400.   !  Time scaling factor for CBC data (seconds in a day)
 !  cn_tronam(1)  = 'var1'    !  Tracer-name to variable-name translation
@@ -173,7 +173,7 @@
                              !  = 0 NO damping of tracers at open boudaries
                              !  = 1 Only for tracers forced with external data
                              !  = 2 Damping applied to all tracers
-   ln_zintobc    = .false.   ! T if a vertical interpolation is required. Variables gdep[t] and e3[t] must exist in the file 
+   ln_zintobc    = .false.,  ! T if a vertical interpolation is required. Variables gdep[t] and e3[t] must exist in the file 
                              !  automatically defined to T if the number of vertical levels in bdy dta /= jpk
 /
 !-----------------------------------------------------------------------

sette/BATCH_TEMPLATE/batch-X64_JUNO

+#!/bin/bash 
+#!
+#BSUB -q p_short
+#BSUB -n TOTAL_NPROCS
+#BSUB -J NEMO_SETTE
+#BSUB -o job_sette.out
+#BSUB -e job_sette.out
+#BSUB -P R000
+#BSUB -x
+
+###############################################################
+# Test specific settings. Do not hand edit these lines; the fcm_job.sh script will set these
+# (via sed operating on this template job file). 
+#
+  OCEANCORES=NPROCS
+  XIOS_NUMPROCS=NXIOPROCS
+  export SETTE_DIR=DEF_SETTE_DIR
+
+###############################################################
+#
+# load sette functions (only post_test_tidyup needed)
+#
+  . ${SETTE_DIR}/all_functions.sh
+
+
+# Don't remove neither change the following line 
+# BODY
+
+#
+# These variables are needed by post_test_tidyup function in all_functions.sh
+#
+  export EXE_DIR=DEF_EXE_DIR
+  export INPUT_DIR=DEF_INPUT_DIR
+  export CONFIG_DIR=DEF_CONFIG_DIR
+  export TOOLS_DIR=DEF_TOOLS_DIR
+  export NEMO_VALIDATION_DIR=DEF_NEMO_VALIDATION
+  export NEW_CONF=DEF_NEW_CONF
+  export CMP_NAM=DEF_CMP_NAM
+  export TEST_NAME=DEF_TEST_NAME
+#
+# end of set up
+
+# Load environment if exists
+env_file=`find ${TOOLS_DIR}/../arch -name arch-${CMP_NAM}.env`
+if [ -f "${env_file}" ] ; then
+   echo "Load environment file arch-${CMP_NAM}.env"
+   . ${env_file}
+fi
+
+###############################################################
+
+# Local settings for CMCC cluster
+#
+export I_MPI_HYDRA_BRANCH_COUNT=`cat $LSB_DJOB_HOSTFILE | uniq  | wc -l`
+export MPIRUN="mpiexec.hydra"
+
+# local xios setting for MPMD
+export LD_LIBRARY_PATH=${XIOS}/lib:${LD_LIBRARY_PATH}
+XIOS_SERVER_PATHNAME="${XIOS}/bin/xios_server.exe"
+
+echo "Start JOBID ${LSB_JOBID}"
+
+###############################################################
+#
+# change to the working directory 
+#
+cd ${EXE_DIR}
+
+#
+  echo Running on host `hostname`
+  echo Time is `date`
+  echo Directory is `pwd`
+# 
+#  Run the parallel MPI executable 
+#
+  startTime=$(date +%s)
+  if [ MPI_FLAG == "yes" ]; then
+     if [ ${USING_MPMD} == "yes" ] && [ ${XIOS_NUMPROCS} -gt 0 ]; then
+        # XIOS detached mode
+        xioscmdfile="xioscmdfile"
+        #
+        echo "# Configuration file for mpiexec.hydra" > $xioscmdfile
+        echo "-n ${OCEANCORES} ./nemo" >> $xioscmdfile
+        echo "-n ${XIOS_NUMPROCS} ${XIOS_SERVER_PATHNAME}" >> $xioscmdfile
+
+        time ${MPIRUN} -configfile $xioscmdfile
+
+     else
+        # XIOS attached mode
+        time ${MPIRUN} ./nemo          
+     fi
+  else
+#  Run the serial executable
+     time ./nemo
+  fi
+  endTime=$(date +%s)
+  totalTime=$(($endTime-$startTime))
+  echo "Model finished after $totalTime seconds for test $TEST_NAME"
+#
+  post_test_tidyup
+
+# END_BODY
+# Don't remove neither change the previous line 
+
+  exit

src/ICE/ice.F90

@@ -241,6 +241,7 @@ MODULE ice
    REAL(wp), PUBLIC ::   rn_hpnd          !: prescribed pond depth    (0<rn_hpnd<1)
    LOGICAL,  PUBLIC ::   ln_pnd_lids      !: Allow ponds to have frozen lids
    LOGICAL , PUBLIC ::   ln_pnd_alb       !: melt ponds affect albedo
+   INTEGER , PUBLIC ::   nn_pnd_brsal     !: brine salinity formulation 0 = Consistent expression with SI3 (linear liquidus) ; 1 = used in GOSI9 
 
    !                                     !!** ice-diagnostics namelist (namdia) **
    LOGICAL , PUBLIC ::   ln_icediachk     !: flag for ice diag (T) or not (F)
@@ -452,6 +453,11 @@ MODULE ice
    REAL(wp), PUBLIC, ALLOCATABLE, SAVE, DIMENSION(:,:,:) ::   qcn_ice_top     !: Surface conduction flux (W/m2)
    !
    !!----------------------------------------------------------------------
+   !! * Only for atmospheric coupling
+   !!----------------------------------------------------------------------
+   REAL(wp), PUBLIC, ALLOCATABLE, SAVE, DIMENSION(:,:,:) ::   a_i_last_couple !: Ice fractional area at last coupling time
+   !
+   !!----------------------------------------------------------------------
    !! NEMO/ICE 4.0 , NEMO Consortium (2018)
    !! $Id: ice.F90 15388 2021-10-17 11:33:47Z clem $
    !! Software governed by the CeCILL license (see ./LICENSE)
@@ -550,6 +556,10 @@ CONTAINS
       ii = ii + 1
       ALLOCATE( t_si(jpi,jpj,jpl) , tm_si(jpi,jpj) , qcn_ice_bot(jpi,jpj,jpl) , qcn_ice_top(jpi,jpj,jpl) , STAT = ierr(ii) )
 
+      ! * For atmospheric coupling
+      ii = ii + 1
+      ALLOCATE( a_i_last_couple(jpi,jpj,jpl) , STAT=ierr(ii) )
+
       ice_alloc = MAXVAL( ierr(:) )
       IF( ice_alloc /= 0 )   CALL ctl_stop( 'STOP', 'ice_alloc: failed to allocate arrays.' )
       !

src/ICE/icerst.F90

@@ -26,6 +26,7 @@ MODULE icerst
    !
    USE in_out_manager ! I/O manager
    USE iom            ! I/O manager library
+   USE ioipsl  , ONLY : ju2ymds                     ! for calendar
    USE lib_mpp        ! MPP library
    USE lib_fortran    ! fortran utilities (glob_sum + no signed zero)
 
@@ -51,6 +52,9 @@ CONTAINS
       !!----------------------------------------------------------------------
       INTEGER, INTENT(in) ::   kt       ! number of iteration
       !
+      INTEGER             ::   iyear, imonth, iday
+      REAL (wp)           ::   zsec
+      REAL (wp)           ::   zfjulday
       CHARACTER(len=20)   ::   clkt     ! ocean time-step define as a character
       CHARACTER(len=50)   ::   clname   ! ice output restart file name
       CHARACTER(len=256)  ::   clpath   ! full path to ice output restart file
@@ -67,8 +71,15 @@ CONTAINS
          &                             .OR. ( kt == nitend - nn_fsbc + 1 .AND. .NOT. lrst_ice ) ) THEN
          IF( nitrst <= nitend .AND. nitrst > 0 ) THEN
             ! beware of the format used to write kt (default is i8.8, that should be large enough...)
-            IF( nitrst > 99999999 ) THEN   ;   WRITE(clkt, *       ) nitrst
-            ELSE                           ;   WRITE(clkt, '(i8.8)') nitrst
+            IF ( ln_rstdate ) THEN
+               zfjulday = fjulday + (2*nn_fsbc+1)*rdt / rday
+               IF( ABS(zfjulday - REAL(NINT(zfjulday),wp)) < 0.1 / rday )   zfjulday = REAL(NINT(zfjulday),wp)   ! avoid truncation error
+               CALL ju2ymds( zfjulday, iyear, imonth, iday, zsec )           
+               WRITE(clkt, '(i4.4,2i2.2)') iyear, imonth, iday
+            ELSE
+               IF( nitrst > 99999999 ) THEN   ;   WRITE(clkt, *       ) nitrst
+               ELSE                           ;   WRITE(clkt, '(i8.8)') nitrst
+               ENDIF
             ENDIF
             ! create the file
             clname = TRIM(cexper)//"_"//TRIM(ADJUSTL(clkt))//"_"//TRIM(cn_icerst_out)
@@ -313,6 +324,11 @@ CONTAINS
             ENDIF
          ENDIF
 
+         ! If this is a coupled model we need to pick up a_i for use as a_i_last_couple
+         IF (ln_cpl) then
+            a_i_last_couple = a_i
+         ENDIF
+         
          IF(.NOT.lrxios) CALL iom_delay_rst( 'READ', 'ICE', numrir )   ! read only ice delayed global communication variables
          !                 ! ---------------------------------- !
       ELSE                 ! == case of a simplified restart == !

src/ICE/icestp.F90

@@ -275,7 +275,7 @@ CONTAINS
          CALL ice_istate( nit000, Kbb, Kmm, Kaa )   ! start from rest or read a file
       ENDIF
       CALL ice_var_glo2eqv
-      CALL ice_var_agg(1)
+      CALL ice_var_agg(2)
       !
       CALL ice_dyn_init                ! set ice dynamics parameters
       !

src/ICE/icetab.F90

@@ -32,14 +32,15 @@ MODULE icetab
    !!----------------------------------------------------------------------
 CONTAINS
 
-   SUBROUTINE tab_3d_2d( ndim1d, tab_ind, tab1d, tab2d )
+   SUBROUTINE tab_3d_2d( ndim1d, tab_ind, tab2d, tab3d )
       !!----------------------------------------------------------------------
-      !!                  ***  ROUTINE tab_2d_1d  ***
+      !!                  ***  ROUTINE tab_3d_2d  ***
       !!----------------------------------------------------------------------
       INTEGER                         , INTENT(in   ) ::   ndim1d   ! 1d size
       INTEGER , DIMENSION(ndim1d)     , INTENT(in   ) ::   tab_ind  ! input index
-      REAL(wp), DIMENSION(jpi,jpj,jpl), INTENT(in   ) ::   tab2d    ! input 2D field
-      REAL(wp), DIMENSION(ndim1d,jpl) , INTENT(inout) ::   tab1d    ! output 1D field
+
+      REAL(wp), DIMENSION(jpi,jpj,jpl), INTENT(in   ) ::   tab3d    ! input 3D field
+      REAL(wp), DIMENSION(ndim1d,jpl) , INTENT(inout) ::   tab2d    ! output 2D field
       !
       INTEGER ::   jl, jn, jid, jjd
       !!----------------------------------------------------------------------
@@ -47,7 +48,7 @@ CONTAINS
          DO jn = 1, ndim1d
             jid          = MOD( tab_ind(jn) - 1 , jpi ) + 1
             jjd          =    ( tab_ind(jn) - 1 ) / jpi + 1
-            tab1d(jn,jl) = tab2d(jid,jjd,jl)
+            tab2d(jn,jl) = tab3d(jid,jjd,jl)
          END DO
       END DO
    END SUBROUTINE tab_3d_2d
@@ -72,14 +73,14 @@ CONTAINS
    END SUBROUTINE tab_2d_1d
 
 
-   SUBROUTINE tab_2d_3d( ndim1d, tab_ind, tab1d, tab2d )
+   SUBROUTINE tab_2d_3d( ndim1d, tab_ind, tab2d, tab3d )
       !!----------------------------------------------------------------------
-      !!                  ***  ROUTINE tab_2d_1d  ***
+      !!                  ***  ROUTINE tab_2d_3d  ***
       !!----------------------------------------------------------------------
       INTEGER                         , INTENT(in   ) ::   ndim1d    ! 1D size
       INTEGER , DIMENSION(ndim1d)     , INTENT(in   ) ::   tab_ind   ! input index
-      REAL(wp), DIMENSION(ndim1d,jpl) , INTENT(in   ) ::   tab1d     ! input 1D field
-      REAL(wp), DIMENSION(jpi,jpj,jpl), INTENT(inout) ::   tab2d     ! output 2D field
+      REAL(wp), DIMENSION(ndim1d,jpl) , INTENT(in   ) ::   tab2d     ! input 2D field
+      REAL(wp), DIMENSION(jpi,jpj,jpl), INTENT(inout) ::   tab3d     ! output 3D field
       !
       INTEGER ::   jl, jn, jid, jjd
       !!----------------------------------------------------------------------
@@ -87,7 +88,7 @@ CONTAINS
          DO jn = 1, ndim1d
             jid               = MOD( tab_ind(jn) - 1 ,  jpi ) + 1
             jjd               =    ( tab_ind(jn) - 1 ) / jpi  + 1
-            tab2d(jid,jjd,jl) = tab1d(jn,jl)
+            tab3d(jid,jjd,jl) = tab2d(jn,jl)
          END DO
       END DO
    END SUBROUTINE tab_2d_3d

src/ICE/icethd_dh.F90

@@ -192,8 +192,8 @@ CONTAINS
 
       ! Snow melting
       ! ------------
-      ! If heat still available (zq_top > 0)
-      ! then all snw precip has been melted and we need to melt more snow
+      ! Melt snow layers, starting with newly fallen snow layer 0 
+      ! and moving downward, until zq_top=0
       DO jk = 0, nlay_s
          DO ji = 1, npti
             IF( zh_s(ji,jk) > 0._wp .AND. zq_top(ji) > 0._wp ) THEN
@@ -216,10 +216,10 @@ CONTAINS
          END DO
       END DO
 
-      ! Snow sublimation
-      !-----------------
-      ! qla_ice is always >=0 (upwards), heat goes to the atmosphere, therefore snow sublimates
-      !    comment: not counted in mass/heat exchange in iceupdate.F90 since this is an exchange with atm. (not ocean)
+      ! Snow sublimation and deposition
+      !--------------------------------
+      ! when evap_ice_1d > 0 (upwards) snow sublimates and snow thickness decreases
+      ! when evap_ice_1d < 0 (downwards) deposition occurs and snow thickness increases
       zdeltah   (1:npti) = 0._wp ! total snow thickness that sublimates, < 0
       zevap_rema(1:npti) = 0._wp
       DO ji = 1, npti
@@ -486,29 +486,6 @@ CONTAINS
          END DO
       END DO
 
-      ! Snow load on ice
-      ! -----------------
-      ! When snow load exceeds Archimede's limit and sst is positive,
-      ! snow-ice formation (next bloc) can lead to negative ice enthalpy.
-      ! Therefore we consider here that this excess of snow falls into the ocean
-      zdeltah(1:npti) = h_s_1d(1:npti) + h_i_1d(1:npti) * (rhoi-rho0) * r1_rhos
-      DO jk = 0, nlay_s
-         DO ji = 1, npti
-            IF( zdeltah(ji) > 0._wp .AND. sst_1d(ji) > 0._wp ) THEN
-               ! snow layer thickness that falls into the ocean
-               zdum = MIN( zdeltah(ji) , zh_s(ji,jk) )
-               ! mass & energy loss to the ocean
-               hfx_res_1d(ji) = hfx_res_1d(ji) - ze_s(ji,jk) * zdum * a_i_1d(ji) * r1_Dt_ice  ! heat flux to the ocean [W.m-2], < 0
-               wfx_res_1d(ji) = wfx_res_1d(ji) + rhos        * zdum * a_i_1d(ji) * r1_Dt_ice  ! mass flux
-               ! update thickness and energy
-               h_s_1d(ji)    = MAX( 0._wp, h_s_1d(ji)  - zdum )
-               zh_s  (ji,jk) = MAX( 0._wp, zh_s(ji,jk) - zdum )
-               ! update snow thickness that still has to fall
-               zdeltah(ji)   = MAX( 0._wp, zdeltah(ji) - zdum )
-            ENDIF
-         END DO
-      END DO
-
       ! Snow-Ice formation
       ! ------------------
       ! When snow load exceeds Archimede's limit, snow-ice interface goes down under sea-level,

src/ICE/icethd_pnd.F90

@@ -140,10 +140,10 @@ CONTAINS
       !------------------------------------
       !  Diagnostics
       !------------------------------------
-      CALL iom_put( 'dvpn_mlt', diag_dvpn_mlt ) ! input from melting
-      CALL iom_put( 'dvpn_lid', diag_dvpn_lid ) ! exchanges with lid
-      CALL iom_put( 'dvpn_drn', diag_dvpn_drn ) ! vertical drainage
-      CALL iom_put( 'dvpn_rnf', diag_dvpn_rnf ) ! runoff + overflow
+      IF( iom_use('dvpn_mlt'  ) ) CALL iom_put( 'dvpn_mlt', diag_dvpn_mlt ) ! input from melting
+      IF( iom_use('dvpn_lid'  ) ) CALL iom_put( 'dvpn_lid', diag_dvpn_lid ) ! exchanges with lid
+      IF( iom_use('dvpn_drn'  ) ) CALL iom_put( 'dvpn_drn', diag_dvpn_drn ) ! vertical drainage
+      IF( iom_use('dvpn_rnf'  ) ) CALL iom_put( 'dvpn_rnf', diag_dvpn_rnf ) ! runoff + overflow
       !
       DEALLOCATE( diag_dvpn_mlt   , diag_dvpn_lid   , diag_dvpn_drn   , diag_dvpn_rnf    )
       DEALLOCATE( diag_dvpn_mlt_1d, diag_dvpn_lid_1d, diag_dvpn_drn_1d, diag_dvpn_rnf_1d )
@@ -544,7 +544,7 @@ CONTAINS
       ! a_ip      -> apond
       ! a_ip_frac -> apnd
 
-      CALL ctl_stop( 'STOP', 'icethd_pnd : topographic melt ponds are still an ongoing work' )
+      !CALL ctl_stop( 'STOP', 'icethd_pnd : topographic melt ponds are still an ongoing work' )
 
       !---------------------------------------------------------------
       ! Initialise
@@ -644,12 +644,6 @@ CONTAINS
                !--------------------------
                ! Pond lid growth and melt
                !--------------------------
-               ! Mean surface temperature
-               zTavg = 0._wp
-               DO jl = 1, jpl
-                  zTavg = zTavg + t_su(ji,jj,jl)*a_i(ji,jj,jl)
-               END DO
-               zTavg = zTavg / a_i(ji,jj,jl) !!! could get a division by zero here
 
                DO jl = 1, jpl-1
 
@@ -692,8 +686,8 @@ CONTAINS
                         ! differential growth of base of surface floating ice layer
                         zdTice = MAX( - ( t_su(ji,jj,jl) - zTd ) , 0._wp ) ! > 0
                         zomega = rcnd_i * zdTice / zrhoi_L
-                        zdHui  = SQRT( 2._wp * zomega * rDt_ice + ( v_il(ji,jj,jl) / a_i(ji,jj,jl) )**2 ) &
-                               - v_il(ji,jj,jl) / a_i(ji,jj,jl)
+                        zdHui  = SQRT( 2._wp * zomega * rDt_ice + ( v_il(ji,jj,jl) / a_ip(ji,jj,jl) )**2 ) &
+                               - v_il(ji,jj,jl) / a_ip(ji,jj,jl)
                         zdvice = min( zdHui*a_ip(ji,jj,jl) , v_ip(ji,jj,jl) )
 
                         IF ( zdvice > epsi10 ) THEN
@@ -1319,7 +1313,9 @@ CONTAINS
        !-----------------------------------------------------------------
        ! brine salinity and liquid fraction
        !-----------------------------------------------------------------
-
+       
+      SELECT CASE( nn_pnd_brsal )
+      CASE( 0 )
        DO k = 1, nlay_i
 
           Sbr    = - Tin(k) / rTmlt ! Consistent expression with SI3 (linear liquidus)
@@ -1328,6 +1324,16 @@ CONTAINS
           phi(k) = salin(k) / Sbr
 
        END DO
+       
+      CASE( 1 )
+       DO k = 1, nlay_i
+       
+          Sbr  = - 18.7 * Tin(k) - 0.519 * Tin(k)**2 - 0.00535 * Tin(k) **3
+          phi(k) = salin(k) / Sbr
+
+       END DO
+       
+      END SELECT
 
        !-----------------------------------------------------------------
        ! permeability
@@ -1354,7 +1360,7 @@ CONTAINS
       NAMELIST/namthd_pnd/  ln_pnd, ln_pnd_LEV , rn_apnd_min, rn_apnd_max, rn_pnd_flush, &
          &                          ln_pnd_CST , rn_apnd, rn_hpnd,         &
          &                          ln_pnd_TOPO,                           &
-         &                          ln_pnd_lids, ln_pnd_alb
+         &                          ln_pnd_lids, ln_pnd_alb, nn_pnd_brsal
       !!-------------------------------------------------------------------
       !
       READ  ( numnam_ice_ref, namthd_pnd, IOSTAT = ios, ERR = 901)
@@ -1379,6 +1385,7 @@ CONTAINS
          WRITE(numout,*) '            Prescribed pond depth                                 rn_hpnd      = ', rn_hpnd
          WRITE(numout,*) '         Frozen lids on top of melt ponds                         ln_pnd_lids  = ', ln_pnd_lids
          WRITE(numout,*) '         Melt ponds affect albedo or not                          ln_pnd_alb   = ', ln_pnd_alb
+         WRITE(numout,*) '         Brine salinity formulation                               nn_pnd_brsal = ', nn_pnd_brsal
       ENDIF
       !
       !                             !== set the choice of ice pond scheme ==!

src/ICE/icethd_zdf_bl99.F90

@@ -939,7 +939,7 @@ CONTAINS
          ELSE
             cnd_ice_1d(ji) = 2._wp * ztcond_i(ji,0) / zhi_ssl ! cnd_ice is capped by: cond_i/zhi_ssl
          ENDIF
-         t1_ice_1d(ji) = isnow(ji) * t_s_1d(ji,1) + ( 1._wp - isnow(ji) ) * t_i_1d(ji,1)
+         t1_ice_1d(ji) = isnow_comb(ji) * t_s_1d(ji,1) + ( 1._wp - isnow_comb(ji) ) * t_i_1d(ji,1)
       END DO
       !
       IF( k_cnd == np_cnd_EMU ) THEN