Changeset 13540 for NEMO/branches/2020/r12377_ticket2386/cfgs/SHARED
- Timestamp:
- 2020-09-29T12:41:06+02:00 (4 years ago)
- Location:
- NEMO/branches/2020/r12377_ticket2386
- Files:
-
- 6 edited
Legend:
- Unmodified
- Added
- Removed
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NEMO/branches/2020/r12377_ticket2386
- Property svn:externals
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old new 3 3 ^/utils/build/mk@HEAD mk 4 4 ^/utils/tools@HEAD tools 5 ^/vendors/AGRIF/dev @HEADext/AGRIF5 ^/vendors/AGRIF/dev_r12970_AGRIF_CMEMS ext/AGRIF 6 6 ^/vendors/FCM@HEAD ext/FCM 7 7 ^/vendors/IOIPSL@HEAD ext/IOIPSL 8 8 9 9 # SETTE 10 ^/utils/CI/sette@ HEADsette10 ^/utils/CI/sette@13507 sette
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- Property svn:externals
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NEMO/branches/2020/r12377_ticket2386/cfgs/SHARED/field_def_nemo-ice.xml
r12377 r13540 49 49 <field id="icehpnd" long_name="melt pond depth" standard_name="sea_ice_meltpond_depth" unit="m" /> 50 50 <field id="icevpnd" long_name="melt pond volume" standard_name="sea_ice_meltpond_volume" unit="m" /> 51 <field id="icehlid" long_name="melt pond lid depth" standard_name="sea_ice_meltpondlid_depth" unit="m" /> 52 <field id="icevlid" long_name="melt pond lid volume" standard_name="sea_ice_meltpondlid_volume" unit="m" /> 51 53 52 54 <!-- heat --> … … 81 83 <field id="icediv" long_name="Divergence of the sea-ice velocity field" standard_name="divergence_of_sea_ice_velocity" unit="s-1" /> 82 84 <field id="iceshe" long_name="Maximum shear of sea-ice velocity field" standard_name="maximum_shear_of_sea_ice_velocity" unit="s-1" /> 83 85 <field id="beta_evp" long_name="Relaxation parameter of ice rheology (beta)" standard_name="relaxation_parameter_of_ice_rheology" unit="" /> 86 84 87 <!-- surface heat fluxes --> 85 88 <field id="qt_ice" long_name="total heat flux at ice surface" standard_name="surface_downward_heat_flux_in_air" unit="W/m2" /> … … 173 176 <field id="frq_m" unit="-" /> 174 177 178 <!-- rheology convergence tests --> 179 <field id="uice_cvg" long_name="sea ice velocity convergence" standard_name="sea_ice_velocity_convergence" unit="m/s" /> 180 175 181 <!-- ================= --> 176 182 <!-- Add-ons for SIMIP --> … … 211 217 <field id="dmisum" long_name="sea-ice mass change through surface melting" standard_name="tendency_of_sea_ice_amount_due_to_surface_melting" unit="kg/m2/s" /> 212 218 <field id="dmibom" long_name="sea-ice mass change through bottom melting" standard_name="tendency_of_sea_ice_amount_due_to_basal_melting" unit="kg/m2/s" /> 219 <field id="dmilam" long_name="sea-ice mass change through lateral melting" standard_name="tendency_of_sea_ice_amount_due_to_lateral_melting" unit="kg/m2/s" /> 213 220 <field id="dmsspr" long_name="snow mass change through snow fall" standard_name="snowfall_flux" unit="kg/m2/s" /> 214 221 <field id="dmsmel" long_name="snow mass change through melt" standard_name="surface_snow_melt_flux" unit="kg/m2/s" /> … … 289 296 <field id="iceapnd_cat" long_name="Ice melt pond concentration per category" unit="" /> 290 297 <field id="icehpnd_cat" long_name="Ice melt pond thickness per category" unit="m" detect_missing_value="true" /> 298 <field id="icehlid_cat" long_name="Ice melt pond lid thickness per category" unit="m" detect_missing_value="true" /> 291 299 <field id="iceafpnd_cat" long_name="Ice melt pond fraction per category" unit="" /> 300 <field id="iceaepnd_cat" long_name="Ice melt pond effective fraction per category" unit="" /> 292 301 <field id="icemask_cat" long_name="Fraction of time step with sea ice (per category)" unit="" /> 293 302 <field id="iceage_cat" long_name="Ice age per category" unit="days" detect_missing_value="true" /> … … 300 309 <field id="snwthic_cat_cmip" long_name="Snow thickness in thickness categories" standard_name="snow_thickness_over_categories" detect_missing_value="true" unit="m" > snwthic_cat * icemask_cat + $missval * (1.-icemask_cat) </field> 301 310 <field id="iceconc_cat_pct_cmip" long_name="Sea-ice area fractions in thickness categories" standard_name="sea_ice_area_fraction_over_categories" detect_missing_value="true" unit="%" > iceconc_cat*100. * icemask_cat + $missval * (1.-icemask_cat) </field> 311 312 <!-- heat diffusion convergence tests --> 313 <field id="tice_cvgerr" long_name="sea ice temperature convergence error" standard_name="sea_ice_temperature_convergence_err" unit="K" /> 314 <field id="tice_cvgstp" long_name="sea ice temperature convergence iterations" standard_name="sea_ice_temperature_convergence_stp" unit="" /> 302 315 303 316 </field_group> <!-- SBC_3D --> … … 560 573 <field field_ref="dmisum" name="sidmassmelttop" /> 561 574 <field field_ref="dmibom" name="sidmassmeltbot" /> 575 <field field_ref="dmilam" name="sidmassmeltlat" /> 562 576 <field field_ref="dmsspr" name="sndmasssnf" /> 563 577 <field field_ref="dmsmel" name="sndmassmelt" /> -
NEMO/branches/2020/r12377_ticket2386/cfgs/SHARED/field_def_nemo-oce.xml
r12377 r13540 1 <?xml version="1.0"?> 1 <?xml version="1.0"?> 2 2 <!-- $id$ --> 3 3 … … 16 16 Configuration of multiple-linear-regression analysis (diamlr) 17 17 ===================================================================================================== 18 18 19 19 This field group configures diamlr for tidal harmonic analysis of field 20 20 ssh: in addition to a regressor for fitting the mean value (diamlr_r101), … … 73 73 74 74 </field_group> 75 76 <!-- 75 76 <!-- 77 77 ============================================================================================================ 78 78 = definition of all existing variables = … … 101 101 </field_group> 102 102 103 <!-- 103 <!-- 104 104 ============================================================================================================ 105 105 Physical ocean model variables … … 108 108 109 109 <!-- T grid --> 110 110 111 111 <field_group id="grid_T" grid_ref="grid_T_2D" > 112 112 <field id="e3t" long_name="T-cell thickness" standard_name="cell_thickness" unit="m" grid_ref="grid_T_3D" /> 113 113 <field id="e3ts" long_name="T-cell thickness" field_ref="e3t" standard_name="cell_thickness" unit="m" grid_ref="grid_T_SFC"/> 114 114 <field id="e3t_0" long_name="Initial T-cell thickness" standard_name="ref_cell_thickness" unit="m" grid_ref="grid_T_3D" /> 115 <field id="e3tb" long_name="bottom T-cell thickness" standard_name="bottom_cell_thickness" unit="m" grid_ref="grid_T_2D"/> 115 <field id="e3tb" long_name="bottom T-cell thickness" standard_name="bottom_cell_thickness" unit="m" grid_ref="grid_T_2D"/> 116 116 <field id="e3t_300" field_ref="e3t" grid_ref="grid_T_zoom_300" detect_missing_value="true" /> 117 117 <field id="e3t_vsum300" field_ref="e3t_300" grid_ref="grid_T_vsum" detect_missing_value="true" /> 118 118 <field id="masscello" long_name="Sea Water Mass per unit area" standard_name="sea_water_mass_per_unit_area" unit="kg/m2" grid_ref="grid_T_3D"/> 119 <field id="volcello" long_name="Ocean Volume" standard_name="ocean_volume" unit="m3" grid_ref="grid_T_3D"/> 119 <field id="volcello" long_name="Ocean Volume" standard_name="ocean_volume" unit="m3" grid_ref="grid_T_3D"/> 120 120 <field id="toce" long_name="temperature" standard_name="sea_water_potential_temperature" unit="degC" grid_ref="grid_T_3D"/> 121 121 <field id="toce_e3t" long_name="temperature (thickness weighted)" unit="degC" grid_ref="grid_T_3D" > toce * e3t </field > … … 129 129 <!-- AGRIF sponge --> 130 130 <field id="agrif_spt" long_name=" AGRIF t-sponge coefficient" unit=" " /> 131 132 <!-- additions to diawri.F90 --> 133 <field id="socegrad" long_name="module of salinity gradient" unit="psu/m" grid_ref="grid_T_3D"/> 134 <field id="socegrad2" long_name="square of module of salinity gradient" unit="psu2/m2" grid_ref="grid_T_3D"/> 135 <field id="ke" long_name="kinetic energy" standard_name="specific_kinetic_energy_of_sea_water" unit="m2/s2" grid_ref="grid_T_3D" /> 136 <field id="ke_int" long_name="vertical integration of kinetic energy" unit="m3/s2" /> 137 <field id="relvor" long_name="relative vorticity" unit="s-1" grid_ref="grid_T_3D"/> 138 <field id="absvor" long_name="absolute vorticity" unit="s-1" grid_ref="grid_T_3D"/> 139 <field id="potvor" long_name="potential vorticity" unit="s-1" grid_ref="grid_T_3D"/> 140 <field id="salt2c" long_name="Salt content vertically integrated" unit="1e-3*kg/m2" /> 131 141 132 142 <!-- t-eddy viscosity coefficients (ldfdyn) --> … … 146 156 <field id="sst_cs" long_name="Delta SST of cool skin" unit="degC" /> 147 157 <field id="temp_3m" long_name="temperature at 3m" unit="degC" /> 148 158 149 159 <field id="sss" long_name="sea surface salinity" standard_name="sea_surface_salinity" unit="1e-3" /> 150 160 <field id="sss2" long_name="square of sea surface salinity" unit="1e-6" > sss * sss </field > … … 152 162 <field id="sssmin" long_name="min of sea surface salinity" field_ref="sss" operation="minimum" /> 153 163 <field id="sbs" long_name="sea bottom salinity" unit="0.001" /> 154 <field id="somint" long_name="vertical integral of salinity times density" standard_name="integral_wrt_depth_of_product_of_density_and_salinity" unit="(kg m2) x (1e-3)" /> 155 156 <field id="taubot" long_name="bottom stress module" unit="N/m2" /> 164 <field id="somint" long_name="vertical integral of salinity times density" standard_name="integral_wrt_depth_of_product_of_density_and_salinity" unit="(kg m2) x (1e-3)" /> 165 166 <field id="taubot" long_name="bottom stress module" unit="N/m2" /> 157 167 158 168 <!-- Case EOS = TEOS-10 : output potential temperature --> … … 177 187 <field id="alpha" long_name="thermal expansion" unit="degC-1" grid_ref="grid_T_3D" /> 178 188 <field id="beta" long_name="haline contraction" unit="1e3" grid_ref="grid_T_3D" /> 179 <field id="bn2" long_name="squared Brunt-Vaisala frequency" unit="s-1" grid_ref="grid_T_3D" />180 189 <field id="rhop" long_name="potential density (sigma0)" standard_name="sea_water_sigma_theta" unit="kg/m3" grid_ref="grid_T_3D" /> 181 190 182 191 <!-- Energy - horizontal divergence --> 183 <field id="eken" long_name="kinetic energy" standard_name="specific_kinetic_energy_of_sea_water" unit="m2/s2" grid_ref="grid_T_3D" />184 192 <field id="hdiv" long_name="horizontal divergence" unit="s-1" grid_ref="grid_T_3D" /> 185 193 … … 295 303 <field id="us_y" long_name="j component of Stokes drift" unit="m/s" /> 296 304 </field_group> 297 305 298 306 <!-- SBC --> 299 307 <field_group id="SBC" > <!-- time step automaticaly defined based on nn_fsbc --> … … 311 319 <field id="precip" long_name="Total precipitation" standard_name="precipitation_flux" unit="kg/m2/s" /> 312 320 <field id="wclosea" long_name="closed sea empmr correction" standard_name="closea_empmr" unit="kg/m2/s" /> 313 321 314 322 <field id="qt" long_name="Net Downward Heat Flux" standard_name="surface_downward_heat_flux_in_sea_water" unit="W/m2" /> 315 323 <field id="qns" long_name="non solar Downward Heat Flux" unit="W/m2" /> … … 321 329 <field id="taum" long_name="wind stress module" standard_name="magnitude_of_surface_downward_stress" unit="N/m2" /> 322 330 <field id="wspd" long_name="wind speed module" standard_name="wind_speed" unit="m/s" /> 323 331 324 332 <!-- * variable relative to atmospheric pressure forcing : available with ln_apr_dyn --> 325 333 <field id="ssh_ib" long_name="Inverse barometer sea surface height" standard_name="sea_surface_height_correction_due_to_air_pressure_at_low_frequency" unit="m" /> … … 369 377 <field id="taum_oce" long_name="wind stress module over open ocean" standard_name="magnitude_of_surface_downward_stress" unit="N/m2" /> 370 378 379 <!-- variables computed by the bulk parameterization algorithms (ln_blk) --> 380 <field id="Cd_oce" long_name="Drag coefficient over open ocean" standard_name="drag_coefficient_water" unit="" /> 381 <field id="Ce_oce" long_name="Evaporaion coefficient over open ocean" standard_name="evap_coefficient_water" unit="" /> 382 <field id="Ch_oce" long_name="Sensible heat coefficient over open ocean" standard_name="sensible_heat_coefficient_water" unit="" /> 383 <field id="theta_zt" long_name="Potential air temperature at z=zt" standard_name="potential_air_temperature_at_zt" unit="degC" /> 384 <field id="q_zt" long_name="Specific air humidity at z=zt" standard_name="specific_air_humidity_at_zt" unit="kg/kg" /> 385 <field id="theta_zu" long_name="Potential air temperature at z=zu" standard_name="potential_air_temperature_at_zu" unit="degC" /> 386 <field id="q_zu" long_name="Specific air humidity at z=zu" standard_name="specific_air_humidity_at_zu" unit="kg/kg" /> 387 <field id="ssq" long_name="Saturation specific humidity of air at z=0" standard_name="surface_air_saturation_spec_humidity" unit="kg/kg" /> 388 <field id="wspd_blk" long_name="Bulk wind speed at z=zu" standard_name="bulk_wind_speed_at_zu" unit="m/s" /> 389 <!-- ln_blk + key_si3 --> 390 <field id="Cd_ice" long_name="Drag coefficient over ice" standard_name="drag_coefficient_ice" unit="" /> 391 <field id="Ce_ice" long_name="Evaporaion coefficient over ice" standard_name="evap_coefficient_ice" unit="" /> 392 <field id="Ch_ice" long_name="Sensible heat coefficient over ice" standard_name="sensible_heat_coefficient_ice" unit="" /> 393 371 394 <!-- available key_oasis3 --> 372 395 <field id="snow_ao_cea" long_name="Snow over ice-free ocean (cell average)" standard_name="snowfall_flux" unit="kg/m2/s" /> … … 405 428 <!-- ice field (nn_ice=1) --> 406 429 <field id="ice_cover" long_name="Ice fraction" standard_name="sea_ice_area_fraction" unit="1" /> 407 430 408 431 <!-- dilution --> 409 432 <field id="emp_x_sst" long_name="Concentration/Dilution term on SST" unit="kg*degC/m2/s" /> 410 <field id="emp_x_sss" long_name="Concentration/Dilution term on SSS" unit="kg*1e-3/m2/s" /> 433 <field id="emp_x_sss" long_name="Concentration/Dilution term on SSS" unit="kg*1e-3/m2/s" /> 411 434 <field id="rnf_x_sst" long_name="Runoff term on SST" unit="kg*degC/m2/s" /> 412 435 <field id="rnf_x_sss" long_name="Runoff term on SSS" unit="kg*1e-3/m2/s" /> 413 436 414 437 <!-- sbcssm variables --> 415 438 <field id="sst_m" unit="degC" /> … … 422 445 423 446 </field_group> 424 447 425 448 426 449 </field_group> <!-- SBC --> 427 450 428 451 <!-- ABL --> 429 452 <field_group id="ABL" > <!-- time step automaticaly defined based on nn_fsbc --> … … 440 463 <field id="t_dta" long_name="DTA potential temperature" standard_name="dta_theta" unit="K" /> 441 464 <field id="q_dta" long_name="DTA specific humidity" standard_name="dta_qspe" unit="kg/kg" /> 442 <field id="coeft" long_name="ABL nudging coefficient" standard_name="coeft" unit="" /> 465 <field id="u_geo" long_name="GEO i-horizontal velocity" standard_name="geo_x_velocity" unit="m/s" /> 466 <field id="v_geo" long_name="GEO j-horizontal velocity" standard_name="geo_y_velocity" unit="m/s" /> 443 467 <field id="tke_abl" long_name="ABL turbulent kinetic energy" standard_name="abl_tke" unit="m2/s2" /> 444 468 <field id="avm_abl" long_name="ABL turbulent viscosity" standard_name="abl_avm" unit="m2/s" /> 445 469 <field id="avt_abl" long_name="ABL turbulent diffusivity" standard_name="abl_avt" unit="m2/s" /> 446 <field id="mxl_abl" long_name="ABL mixing length" standard_name="abl_mxl" unit="m" /> 470 <field id="mxlm_abl" long_name="ABL master mixing length" standard_name="abl_mxlm" unit="m" /> 471 <field id="mxld_abl" long_name="ABL dissipative mixing length" standard_name="abl_mxld" unit="m" /> 447 472 </field_group> 448 473 … … 456 481 <field id="uz1_dta" long_name="DTA i-horizontal velocity" standard_name="dta_x_velocity" unit="m/s" /> 457 482 <field id="vz1_dta" long_name="DTA j-horizontal velocity" standard_name="dta_y_velocity" unit="m/s" /> 458 <field id="uvz1_dta" long_name="DTA wind speed module" standard_name="dta_wind_speed" unit="m/s" > sqrt( uz1_dta^2 + vz1_dta^2 ) </field> 483 <field id="uvz1_dta" long_name="DTA wind speed module" standard_name="dta_wind_speed" unit="m/s" > sqrt( uz1_dta^2 + vz1_dta^2 ) </field> 459 484 <field id="tz1_dta" long_name="DTA potential temperature" standard_name="dta_theta" unit="K" /> 460 485 <field id="qz1_dta" long_name="DTA specific humidity" standard_name="dta_qspe" unit="kg/kg" /> … … 462 487 <field id="uz1_geo" long_name="GEO i-horizontal velocity" standard_name="geo_x_velocity" unit="m/s" /> 463 488 <field id="vz1_geo" long_name="GEO j-horizontal velocity" standard_name="geo_y_velocity" unit="m/s" /> 464 <field id="uvz1_geo" long_name="GEO wind speed module" standard_name="geo_wind_speed" unit="m/s" > sqrt( uz1_geo^2 + vz1_geo^2 ) </field> 489 <field id="uvz1_geo" long_name="GEO wind speed module" standard_name="geo_wind_speed" unit="m/s" > sqrt( uz1_geo^2 + vz1_geo^2 ) </field> 465 490 </field_group> 466 491 467 492 </field_group> <!-- ABL --> 468 493 469 494 470 495 <!-- U grid --> 471 496 472 497 <field_group id="grid_U" grid_ref="grid_U_2D"> 473 498 <field id="e2u" long_name="U-cell width in meridional direction" standard_name="cell_width" unit="m" /> … … 478 503 <field id="uoce_e3u" long_name="ocean current along i-axis (thickness weighted)" unit="m/s" grid_ref="grid_U_3D" > uoce * e3u </field> 479 504 <field id="uoce_e3u_vsum" long_name="ocean current along i-axis * e3u summed on the vertical" field_ref="uoce_e3u" unit="m3/s" grid_ref="grid_U_vsum"/> 480 <field id="uocetr_vsum" long_name="ocean transport along i-axis summed on the vertical" field_ref="e2u" unit="m3/s"> this * uoce_e3u_vsum </field> 505 <field id="uocetr_vsum" long_name="ocean transport along i-axis summed on the vertical" field_ref="e2u" unit="m3/s"> this * uoce_e3u_vsum </field> 481 506 482 507 <field id="uocetr_vsum_op" long_name="ocean current along i-axis * e3u * e2u summed on the vertical" read_access="true" freq_op="1mo" field_ref="e2u" unit="m3/s"> @uocetr_vsum </field> 483 <field id="uocetr_vsum_cumul" long_name="ocean current along i-axis * e3u * e2u cumulated from southwest point" freq_offset="_reset_" operation="instant" freq_op="1mo" unit="m3/s" /> 484 <field id="msftbarot" long_name="ocean_barotropic_mass_streamfunction" unit="kg s-1" > uocetr_vsum_cumul * $r au0 </field>508 <field id="uocetr_vsum_cumul" long_name="ocean current along i-axis * e3u * e2u cumulated from southwest point" freq_offset="_reset_" operation="instant" freq_op="1mo" unit="m3/s" /> 509 <field id="msftbarot" long_name="ocean_barotropic_mass_streamfunction" unit="kg s-1" > uocetr_vsum_cumul * $rho0 </field> 485 510 486 511 … … 534 559 <field id="udiff_salttr" long_name="ocean diffusion salt transport along i-axis" standard_name="ocean_salt_x_transport_due_to_diffusion" unit="1e-3*kg/s" /> 535 560 </field_group> 536 561 537 562 <!-- V grid --> 538 563 539 564 <field_group id="grid_V" grid_ref="grid_V_2D"> 540 565 <field id="e1v" long_name="V-cell width in longitudinal direction" standard_name="cell_width" unit="m" /> … … 593 618 <field id="vdiff_salttr" long_name="ocean diffusion salt transport along j-axis" standard_name="ocean_salt_y_transport_due_to_diffusion" unit="1e-3*kg/s" /> 594 619 </field_group> 595 620 596 621 <!-- W grid --> 597 622 598 623 <field_group id="grid_W" grid_ref="grid_W_3D"> 599 624 <field id="e3w" long_name="W-cell thickness" standard_name="cell_thickness" unit="m" /> 600 625 <field id="woce" long_name="ocean vertical velocity" standard_name="upward_sea_water_velocity" unit="m/s" /> 601 <field id="woce_e3w" long_name="ocean vertical velocity * e3w" unit="m2/s" > woce * e3w </field> 626 <field id="woce_e3w" long_name="ocean vertical velocity * e3w" unit="m2/s" > woce * e3w </field> 602 627 <field id="wocetr_eff" long_name="effective ocean vertical transport" unit="m3/s" /> 603 628 … … 609 634 610 635 <field id="avt" long_name="vertical eddy diffusivity" standard_name="ocean_vertical_heat_diffusivity" unit="m2/s" /> 611 <field id="avt_e3w" long_name="vertical heat diffusivity * e3w" unit="m3/s" > avt * e3w </field> 636 <field id="avt_e3w" long_name="vertical heat diffusivity * e3w" unit="m3/s" > avt * e3w </field> 612 637 <field id="logavt" long_name="logarithm of vertical eddy diffusivity" standard_name="ocean_vertical_heat_diffusivity" unit="m2/s" /> 613 638 <field id="avm" long_name="vertical eddy viscosity" standard_name="ocean_vertical_momentum_diffusivity" unit="m2/s" /> 614 <field id="avm_e3w" long_name="vertical eddy viscosity * e3w" unit="m3/s" > avm * e3w </field> 639 <field id="avm_e3w" long_name="vertical eddy viscosity * e3w" unit="m3/s" > avm * e3w </field> 615 640 616 641 <!-- avs: /= avt with ln_zdfddm=T --> 617 642 <field id="avs" long_name="salt vertical eddy diffusivity" standard_name="ocean_vertical_salt_diffusivity" unit="m2/s" /> 618 <field id="avs_e3w" long_name="vertical salt diffusivity * e3w" unit="m3/s" > avs * e3w </field> 643 <field id="avs_e3w" long_name="vertical salt diffusivity * e3w" unit="m3/s" > avs * e3w </field> 619 644 <field id="logavs" long_name="logarithm of salt vertical eddy diffusivity" standard_name="ocean_vertical_heat_diffusivity" unit="m2/s" /> 620 645 621 646 <!-- avt_evd and avm_evd: available with ln_zdfevd --> 622 647 <field id="avt_evd" long_name="convective enhancement of vertical diffusivity" standard_name="ocean_vertical_tracer_diffusivity_due_to_convection" unit="m2/s" /> 623 <field id="avt_evd_e3w" long_name="convective enhancement to vertical diffusivity * e3w " unit="m3/s" > avt_evd * e3w </field> 648 <field id="avt_evd_e3w" long_name="convective enhancement to vertical diffusivity * e3w " unit="m3/s" > avt_evd * e3w </field> 624 649 <field id="avm_evd" long_name="convective enhancement of vertical viscosity" standard_name="ocean_vertical_momentum_diffusivity_due_to_convection" unit="m2/s" /> 625 650 … … 634 659 <field id="wstokes" long_name="Stokes Drift vertical velocity" standard_name="upward_StokesDrift_velocity" unit="m/s" /> 635 660 636 <!-- variables available with diaar5 --> 661 <!-- variables available with diaar5 --> 637 662 <field id="w_masstr" long_name="vertical mass transport" standard_name="upward_ocean_mass_transport" unit="kg/s" /> 638 663 <field id="w_masstr2" long_name="square of vertical mass transport" standard_name="square_of_upward_ocean_mass_transport" unit="kg2/s2" /> 639 664 665 <!-- EOS --> 666 <field id="bn2" long_name="squared Brunt-Vaisala frequency" unit="s-2" /> 667 640 668 </field_group> 641 669 642 670 <!-- F grid --> 643 671 <!-- AGRIF sponge --> … … 683 711 <field id="uocetr_vsum_section" long_name="Total 2D transport in i-direction" field_ref="uoce_e3u_ave_vsum" grid_ref="grid_U_scalar" detect_missing_value="true"> this * e2u </field> 684 712 <field id="uocetr_strait" long_name="Total transport across lines in i-direction" field_ref="uocetr_vsum_section" grid_ref="grid_U_4strait" /> 685 <field id="u_masstr_strait" long_name="Sea water transport across line in i-direction" field_ref="uocetr_strait" grid_ref="grid_U_4strait_hsum" unit="kg/s"> this * maskMFO_u * $r au0 </field>713 <field id="u_masstr_strait" long_name="Sea water transport across line in i-direction" field_ref="uocetr_strait" grid_ref="grid_U_4strait_hsum" unit="kg/s"> this * maskMFO_u * $rho0 </field> 686 714 687 715 <field id="voce_e3v_ave" long_name="Monthly average of v*e3v" field_ref="voce_e3v" freq_op="1mo" freq_offset="_reset_" > @voce_e3v </field> … … 689 717 <field id="vocetr_vsum_section" long_name="Total 2D transport of in j-direction" field_ref="voce_e3v_ave_vsum" grid_ref="grid_V_scalar" detect_missing_value="true"> this * e1v </field> 690 718 <field id="vocetr_strait" long_name="Total transport across lines in j-direction" field_ref="vocetr_vsum_section" grid_ref="grid_V_4strait" /> 691 <field id="v_masstr_strait" long_name="Sea water transport across line in j-direction" field_ref="vocetr_strait" grid_ref="grid_V_4strait_hsum" unit="kg/s"> this * maskMFO_v * $r au0 </field>719 <field id="v_masstr_strait" long_name="Sea water transport across line in j-direction" field_ref="vocetr_strait" grid_ref="grid_V_4strait_hsum" unit="kg/s"> this * maskMFO_v * $rho0 </field> 692 720 693 721 <field id="masstr_strait" long_name="Sea water transport across line" grid_ref="grid_4strait" > u_masstr_strait + v_masstr_strait </field> 694 722 </field_group> 695 723 696 697 724 <!-- variables available with ln_floats --> 698 725 … … 709 736 <!-- variables available with iceberg trajectories --> 710 737 711 <field_group id="icbvar" domain_ref="grid_T" > 738 <field_group id="icbvar" domain_ref="grid_T" > 712 739 <field id="berg_melt" long_name="icb melt rate of icebergs" unit="kg/m2/s" /> 713 740 <field id="berg_melt_hcflx" long_name="icb heat flux to ocean due to melting heat content" unit="J/m2/s" /> … … 727 754 </field_group> 728 755 729 <!-- Poleward transport : ptr --> 730 <field_group id="diaptr" > 756 <!-- Poleward transport : ptr --> 757 <field_group id="diaptr" > 731 758 <field id="zomsf" long_name="Overturning Stream-Function : All basins" unit="Sv" grid_ref="grid_znl_W_3D" /> 732 759 <field id="zotem" long_name="Zonal Mean Temperature : All basins" unit="degree_C" grid_ref="grid_znl_T_3D" /> … … 736 763 <field id="sopstove" long_name="Overturning Salt Transport: All basins" unit="Giga g/s" grid_ref="grid_znl_T_2D" /> 737 764 <field id="sophtbtr" long_name="Barotropic Heat Transport: All basins" unit="PW" grid_ref="grid_znl_T_2D" /> 738 <field id="sopstbtr" long_name="Barotropic Salt Transport: All basins" unit="Giga g/s" grid_ref="grid_znl_T_2D" /> 765 <field id="sopstbtr" long_name="Barotropic Salt Transport: All basins" unit="Giga g/s" grid_ref="grid_znl_T_2D" /> 739 766 <field id="sophtadv" long_name="Advective Heat Transport: All basins" unit="PW" grid_ref="grid_znl_T_2D" /> 740 767 <field id="sopstadv" long_name="Advective Salt Transport: All basins" unit="Giga g/s" grid_ref="grid_znl_T_2D" /> … … 742 769 <field id="sopstldf" long_name="Diffusive Salt Transport: All basins" unit="Giga g/s" grid_ref="grid_znl_T_2D" /> 743 770 <field id="sophtvtr" long_name="Heat Transport : All basins" unit="PW" grid_ref="grid_znl_T_2D" /> 744 <field id="sopstvtr" long_name="Salt Transport : All basins" unit="Giga g/s" grid_ref="grid_znl_T_2D" /> 771 <field id="sopstvtr" long_name="Salt Transport : All basins" unit="Giga g/s" grid_ref="grid_znl_T_2D" /> 745 772 <field id="sophteiv" long_name="Heat Transport from mesoscale eddy advection: All basins" unit="PW" grid_ref="grid_znl_T_2D" /> 746 773 <field id="sopsteiv" long_name="Salt Transport from mesoscale eddy advection : All basins" unit="Giga g/s" grid_ref="grid_znl_T_2D" /> … … 758 785 759 786 760 <!-- 787 <!-- 761 788 ============================================================================================================ 762 789 Physical ocean model trend diagnostics : temperature, KE, PE, momentum … … 899 926 <field id="ketrd_zdf" long_name="ke-trend: vertical diffusion" unit="W/s^3" /> 900 927 <field id="ketrd_tau" long_name="ke-trend: wind stress " unit="W/s^3" grid_ref="grid_T_2D" /> 901 <field id="ketrd_bfr" long_name="ke-trend: bottom friction (explicit)" unit="W/s^3" /> 902 <field id="ketrd_bfri" long_name="ke-trend: bottom friction (implicit)" unit="W/s^3" /> 903 <field id="ketrd_atf" long_name="ke-trend: asselin time filter trend" unit="W/s^3" /> 928 <field id="ketrd_bfr" long_name="ke-trend: bottom friction (explicit)" unit="W/s^3" /> 929 <field id="ketrd_bfri" long_name="ke-trend: bottom friction (implicit)" unit="W/s^3" /> 930 <field id="ketrd_atf" long_name="ke-trend: asselin time filter trend" unit="W/s^3" /> 904 931 <field id="ketrd_convP2K" long_name="ke-trend: conversion (potential to kinetic)" unit="W/s^3" /> 905 <field id="KE" long_name="kinetic energy: u(n)*u(n+1)/2" unit="W/s^2" /> 932 <field id="KE" long_name="kinetic energy: u(n)*u(n+1)/2" unit="W/s^2" /> 906 933 907 934 <!-- variables available when explicit lateral mixing is used (ln_dynldf_OFF=F) --> 908 <field id="dispkexyfo" long_name="KE-trend: lateral mixing induced dissipation" standard_name="ocean_kinetic_energy_dissipation_per_unit_area_due_to_xy_friction" unit="W/m^2" grid_ref="grid_T_2D" /> 909 <field id="dispkevfo" long_name="KE-trend: vertical mixing induced dissipation" standard_name="ocean_kinetic_energy_dissipation_per_unit_area_due_to_vertical_friction" unit="W/m^2" grid_ref="grid_T_2D" /> 935 <field id="dispkexyfo" long_name="KE-trend: lateral mixing induced dissipation" standard_name="ocean_kinetic_energy_dissipation_per_unit_area_due_to_xy_friction" unit="W/m^2" grid_ref="grid_T_2D" /> 936 <field id="dispkevfo" long_name="KE-trend: vertical mixing induced dissipation" standard_name="ocean_kinetic_energy_dissipation_per_unit_area_due_to_vertical_friction" unit="W/m^2" grid_ref="grid_T_2D" /> 910 937 <!-- variables available with ln_traadv_eiv=T and ln_diaeiv=T --> 911 <field id="eketrd_eiv" long_name="EKE-trend due to parameterized eddy advection" standard_name="tendency_of_ocean_eddy_kinetic_energy_content_due_to_parameterized_eddy_advection" unit="W/m^2" grid_ref="grid_T_2D" /> 938 <field id="eketrd_eiv" long_name="EKE-trend due to parameterized eddy advection" standard_name="tendency_of_ocean_eddy_kinetic_energy_content_due_to_parameterized_eddy_advection" unit="W/m^2" grid_ref="grid_T_2D" /> 912 939 913 940 <!-- variables available with ln_PE_trd --> … … 926 953 <field id="petrd_bbc" long_name="pe-trend: geothermal heating" unit="W/m^3" /> 927 954 <field id="petrd_atf" long_name="pe-trend: asselin time filter" unit="W/m^3" /> 928 <field id="PEanom" long_name="potential energy anomaly" unit="1" /> 929 <field id="alphaPE" long_name="partial deriv. of PEanom wrt T" unit="degC-1" /> 930 <field id="betaPE" long_name="partial deriv. of PEanom wrt S" unit="1e3" /> 955 <field id="PEanom" long_name="potential energy anomaly" unit="1" /> 956 <field id="alphaPE" long_name="partial deriv. of PEanom wrt T" unit="degC-1" /> 957 <field id="betaPE" long_name="partial deriv. of PEanom wrt S" unit="1e3" /> 931 958 </field_group> 932 959 … … 945 972 <field id="utrd_zdf" long_name="i-trend: vertical diffusion" unit="m/s^2" /> 946 973 <field id="utrd_tau" long_name="i-trend: wind stress " unit="m/s^2" grid_ref="grid_U_2D" /> 947 <field id="utrd_bfr" long_name="i-trend: bottom friction (explicit)" unit="m/s^2" /> 948 <field id="utrd_bfri" long_name="i-trend: bottom friction (implicit)" unit="m/s^2" /> 949 <field id="utrd_tot" long_name="i-trend: total momentum trend before atf" unit="m/s^2" /> 950 <field id="utrd_atf" long_name="i-trend: asselin time filter trend" unit="m/s^2" /> 974 <field id="utrd_bfr" long_name="i-trend: bottom friction (explicit)" unit="m/s^2" /> 975 <field id="utrd_bfri" long_name="i-trend: bottom friction (implicit)" unit="m/s^2" /> 976 <field id="utrd_tot" long_name="i-trend: total momentum trend before atf" unit="m/s^2" /> 977 <field id="utrd_atf" long_name="i-trend: asselin time filter trend" unit="m/s^2" /> 951 978 </field_group> 952 979 … … 965 992 <field id="vtrd_zdf" long_name="j-trend: vertical diffusion" unit="m/s^2" /> 966 993 <field id="vtrd_tau" long_name="j-trend: wind stress " unit="m/s^2" grid_ref="grid_V_2D" /> 967 <field id="vtrd_bfr" long_name="j-trend: bottom friction (explicit)" unit="m/s^2" /> 968 <field id="vtrd_bfri" long_name="j-trend: bottom friction (implicit)" unit="m/s^2" /> 969 <field id="vtrd_tot" long_name="j-trend: total momentum trend before atf" unit="m/s^2" /> 970 <field id="vtrd_atf" long_name="j-trend: asselin time filter trend" unit="m/s^2" /> 994 <field id="vtrd_bfr" long_name="j-trend: bottom friction (explicit)" unit="m/s^2" /> 995 <field id="vtrd_bfri" long_name="j-trend: bottom friction (implicit)" unit="m/s^2" /> 996 <field id="vtrd_tot" long_name="j-trend: total momentum trend before atf" unit="m/s^2" /> 997 <field id="vtrd_atf" long_name="j-trend: asselin time filter trend" unit="m/s^2" /> 971 998 </field_group> 972 999 973 1000 974 <!-- 1001 <!-- 975 1002 ============================================================================================================ 976 1003 Definitions for iodef_demo.xml … … 990 1017 <field field_ref="strd_zdfp_li" name="osaltdiff" /> 991 1018 </field_group> 992 1019 993 1020 <field_group id="mooring" > 994 1021 <field field_ref="toce" name="thetao" long_name="sea_water_potential_temperature" /> … … 999 1026 <field field_ref="avt" name="difvho" long_name="ocean_vertical_heat_diffusivity" /> 1000 1027 <field field_ref="avm" name="difvmo" long_name="ocean_vertical_momentum_diffusivity" /> 1001 1028 1002 1029 <field field_ref="sst" name="tos" long_name="sea_surface_temperature" /> 1003 1030 <field field_ref="sst2" name="tossq" long_name="square_of_sea_surface_temperature" /> … … 1047 1074 <field field_ref="BLT" name="blt" long_name="Barrier Layer Thickness" /> 1048 1075 </field_group> 1049 1076 1050 1077 <field_group id="groupU" > 1051 1078 <field field_ref="uoce" name="uo" long_name="sea_water_x_velocity" /> 1052 1079 <field field_ref="utau" name="tauuo" long_name="surface_downward_x_stress" /> 1053 1080 </field_group> 1054 1081 1055 1082 <field_group id="groupV" > 1056 1083 <field field_ref="voce" name="vo" long_name="sea_water_y_velocity" /> 1057 1084 <field field_ref="vtau" name="tauvo" long_name="surface_downward_y_stress" /> 1058 1085 </field_group> 1059 1086 1060 1087 <field_group id="groupW" > 1061 1088 <field field_ref="woce" name="wo" long_name="ocean vertical velocity" /> … … 1100 1127 </field_group> 1101 1128 1102 <!-- 1129 <!-- 1103 1130 ============================================================================================================ 1104 1131 --> 1105 <!-- output variables for my configuration (example) --> 1106 1132 <!-- output variables for my configuration (example) --> 1133 1107 1134 <field_group id="myvarOCE" > 1108 <!-- grid T --> 1135 <!-- grid T --> 1109 1136 <field field_ref="e3t" name="e3t" long_name="vertical scale factor" /> 1110 1137 <field field_ref="sst" name="tos" long_name="sea_surface_temperature" /> 1111 1138 <field field_ref="sss" name="sos" long_name="sea_surface_salinity" /> 1112 1139 <field field_ref="ssh" name="zos" long_name="sea_surface_height_above_geoid" /> 1113 1114 <!-- grid U --> 1140 1141 <!-- grid U --> 1115 1142 <field field_ref="e3u" name="e3u" long_name="vertical scale factor" /> 1116 1143 <field field_ref="ssu" name="uos" long_name="sea_surface_x_velocity" /> 1117 1118 <!-- grid V --> 1144 1145 <!-- grid V --> 1119 1146 <field field_ref="e3v" name="e3v" long_name="vertical scale factor" /> 1120 <field field_ref="ssv" name="vos" long_name="sea_surface_y_velocity" /> 1121 </field_group> 1147 <field field_ref="ssv" name="vos" long_name="sea_surface_y_velocity" /> 1148 </field_group> 1122 1149 1123 1150 </field_definition> -
NEMO/branches/2020/r12377_ticket2386/cfgs/SHARED/namelist_ice_ref
r12377 r13540 43 43 ln_cat_usr = .false. ! ice categories are defined by rn_catbnd below (m) 44 44 rn_catbnd = 0.,0.45,1.1,2.1,3.7,6.0 45 rn_himin = 0.1 ! minimum ice thickness (m) used in remapping 45 rn_himin = 0.1 ! minimum ice thickness (m) allowed 46 rn_himax = 99.0 ! maximum ice thickness (m) allowed 46 47 / 47 48 !------------------------------------------------------------------------------ … … 56 57 rn_ishlat = 2. ! lbc : free slip (0) ; partial slip (0-2) ; no slip (2) ; strong slip (>2) 57 58 ln_landfast_L16 = .false. ! landfast: parameterization from Lemieux 2016 58 rn_ depfra= 0.125 ! fraction of ocean depth that ice must reach to initiate landfast59 rn_lf_depfra = 0.125 ! fraction of ocean depth that ice must reach to initiate landfast 59 60 ! recommended range: [0.1 ; 0.25] 60 rn_ icebfr = 15. ! maximum bottom stress per unit volume [N/m3]61 rn_lf relax= 1.e-5 ! relaxation time scale to reach static friction [s-1]62 rn_ tensile= 0.05 ! isotropic tensile strength [0-0.5??]61 rn_lf_bfr = 15. ! maximum bottom stress per unit volume [N/m3] 62 rn_lf_relax = 1.e-5 ! relaxation time scale to reach static friction [s-1] 63 rn_lf_tensile = 0.05 ! isotropic tensile strength [0-0.5??] 63 64 / 64 65 !------------------------------------------------------------------------------ … … 91 92 !------------------------------------------------------------------------------ 92 93 ln_rhg_EVP = .true. ! EVP rheology 93 ln_aEVP = . false.! adaptive rheology (Kimmritz et al. 2016 & 2017)94 ln_aEVP = .true. ! adaptive rheology (Kimmritz et al. 2016 & 2017) 94 95 rn_creepl = 2.0e-9 ! creep limit [1/s] 95 96 rn_ecc = 2.0 ! eccentricity of the elliptical yield curve 96 nn_nevp = 1 20 ! number of EVP subcycles97 nn_nevp = 100 ! number of EVP subcycles 97 98 rn_relast = 0.333 ! ratio of elastic timescale to ice time step: Telast = dt_ice * rn_relast 98 ! advised value: 1/3 (rn_nevp=120) or 1/9 (rn_nevp=300) 99 ! advised value: 1/3 (nn_nevp=100) or 1/9 (nn_nevp=300) 100 nn_rhg_chkcvg = 0 ! check convergence of rheology 101 ! = 0 no check 102 ! = 1 check at the main time step (output xml: uice_cvg) 103 ! = 2 check at both main and rheology time steps (additional output: ice_cvg.nc) 104 ! this option 2 asks a lot of communications between cpu 99 105 / 100 106 !------------------------------------------------------------------------------ 101 107 &namdyn_adv ! Ice advection 102 108 !------------------------------------------------------------------------------ 103 ln_adv_Pra = .true. ! Advection scheme (Prather)104 ln_adv_UMx = .false. 109 ln_adv_Pra = .true. ! Advection scheme (Prather) 110 ln_adv_UMx = .false. ! Advection scheme (Ultimate-Macho) 105 111 nn_UMx = 5 ! order of the scheme for UMx (1-5 ; 20=centered 2nd order) 106 112 / … … 109 115 !------------------------------------------------------------------------------ 110 116 rn_cio = 5.0e-03 ! ice-ocean drag coefficient (-) 111 rn_blow_s = 0.66 ! mesure of snow blowing into the leads 117 nn_snwfra = 2 ! calculate the fraction of ice covered by snow (for zdf and albedo) 118 ! = 0 fraction = 1 (if snow) or 0 (if no snow) 119 ! = 1 fraction = 1-exp(-0.2*rhos*hsnw) [MetO formulation] 120 ! = 2 fraction = hsnw / (hsnw+0.02) [CICE formulation] 121 rn_snwblow = 0.66 ! mesure of snow blowing into the leads 112 122 ! = 1 => no snow blowing, < 1 => some snow blowing 113 123 nn_flxdist = -1 ! Redistribute heat flux over ice categories … … 118 128 ln_cndflx = .false. ! Use conduction flux as surface boundary conditions (i.e. for Jules coupling) 119 129 ln_cndemulate = .false. ! emulate conduction flux (if not provided in the inputs) 130 nn_qtrice = 1 ! Solar flux transmitted thru the surface scattering layer: 131 ! = 0 Grenfell and Maykut 1977 (depends on cloudiness and is 0 when there is snow) 132 ! = 1 Lebrun 2019 (equals 0.3 anytime with different melting/dry snw conductivities) 120 133 / 121 134 !------------------------------------------------------------------------------ … … 126 139 ln_icedO = .true. ! activate ice growth in open-water (T) or not (F) 127 140 ln_icedS = .true. ! activate brine drainage (T) or not (F) 141 ! 142 ln_leadhfx = .true. ! heat in the leads is used to melt sea-ice before warming the ocean 128 143 / 129 144 !------------------------------------------------------------------------------ … … 135 150 rn_cnd_s = 0.31 ! thermal conductivity of the snow (0.31 W/m/K, Maykut and Untersteiner, 1971) 136 151 ! Obs: 0.1-0.5 (Lecomte et al, JAMES 2013) 137 rn_kappa_i = 1.0 ! radiation attenuation coefficient in sea ice [1/m] 152 rn_kappa_i = 1.0 ! radiation attenuation coefficient in sea ice [1/m] 153 rn_kappa_s = 10.0 ! nn_qtrice = 0: radiation attenuation coefficient in snow [1/m] 154 rn_kappa_smlt = 7.0 ! nn_qtrice = 1: radiation attenuation coefficient in melting snow [1/m] 155 rn_kappa_sdry = 10.0 ! radiation attenuation coefficient in dry snow [1/m] 156 ln_zdf_chkcvg = .false. ! check convergence of heat diffusion scheme (outputs: tice_cvgerr, tice_cvgstp) 138 157 / 139 158 !------------------------------------------------------------------------------ … … 175 194 &namthd_pnd ! Melt ponds 176 195 !------------------------------------------------------------------------------ 177 ln_pnd = .false. ! activate melt ponds or not 178 ln_pnd_H12 = .false. ! activate evolutive melt ponds (from Holland et al 2012) 179 ln_pnd_CST = .false. ! activate constant melt ponds 180 rn_apnd = 0.2 ! prescribed pond fraction, at Tsu=0 degC 181 rn_hpnd = 0.05 ! prescribed pond depth, at Tsu=0 degC 182 ln_pnd_alb = .false. ! melt ponds affect albedo or not 196 ln_pnd = .true. ! activate melt ponds or not 197 ln_pnd_LEV = .true. ! level ice melt ponds (from Flocco et al 2007,2010 & Holland et al 2012) 198 rn_apnd_min = 0.15 ! minimum ice fraction that contributes to melt pond. range: 0.0 -- 0.15 ?? 199 rn_apnd_max = 0.85 ! maximum ice fraction that contributes to melt pond. range: 0.7 -- 0.85 ?? 200 ln_pnd_CST = .false. ! constant melt ponds 201 rn_apnd = 0.2 ! prescribed pond fraction, at Tsu=0 degC 202 rn_hpnd = 0.05 ! prescribed pond depth, at Tsu=0 degC 203 ln_pnd_lids = .true. ! frozen lids on top of the ponds (only for ln_pnd_LEV) 204 ln_pnd_alb = .true. ! effect of melt ponds on ice albedo 183 205 / 184 206 !------------------------------------------------------------------------------ … … 186 208 !------------------------------------------------------------------------------ 187 209 ln_iceini = .true. ! activate ice initialization (T) or not (F) 188 ln_iceini_file = .false. ! netcdf file provided for initialization (T) or not (F) 210 nn_iceini_file = 0 ! 0 = Initialise sea ice based on SSTs 211 ! 1 = Initialise sea ice from single category netcdf file 212 ! 2 = Initialise sea ice from multi category restart file 189 213 rn_thres_sst = 2.0 ! max temp. above Tfreeze with initial ice = (sst - tfreeze) 190 214 rn_hti_ini_n = 3.0 ! initial ice thickness (m), North … … 206 230 rn_hpd_ini_n = 0.05 ! initial pond depth (m), North 207 231 rn_hpd_ini_s = 0.05 ! " " South 208 ! -- for ln_iceini_file = T 209 sn_hti = 'Ice_initialization' , -12 ,'hti' , .false. , .true., 'yearly' , '' , '', '' 210 sn_hts = 'Ice_initialization' , -12 ,'hts' , .false. , .true., 'yearly' , '' , '', '' 211 sn_ati = 'Ice_initialization' , -12 ,'ati' , .false. , .true., 'yearly' , '' , '', '' 212 sn_smi = 'Ice_initialization' , -12 ,'smi' , .false. , .true., 'yearly' , '' , '', '' 213 sn_tmi = 'Ice_initialization' , -12 ,'tmi' , .false. , .true., 'yearly' , '' , '', '' 214 sn_tsu = 'Ice_initialization' , -12 ,'tsu' , .false. , .true., 'yearly' , '' , '', '' 215 sn_tms = 'NOT USED' , -12 ,'tms' , .false. , .true., 'yearly' , '' , '', '' 232 rn_hld_ini_n = 0.0 ! initial pond lid depth (m), North 233 rn_hld_ini_s = 0.0 ! " " South 234 ! -- for nn_iceini_file = 1 235 sn_hti = 'Ice_initialization' , -12. ,'hti' , .false. , .true., 'yearly' , '' , '', '' 236 sn_hts = 'Ice_initialization' , -12. ,'hts' , .false. , .true., 'yearly' , '' , '', '' 237 sn_ati = 'Ice_initialization' , -12. ,'ati' , .false. , .true., 'yearly' , '' , '', '' 238 sn_smi = 'Ice_initialization' , -12. ,'smi' , .false. , .true., 'yearly' , '' , '', '' 239 sn_tmi = 'Ice_initialization' , -12. ,'tmi' , .false. , .true., 'yearly' , '' , '', '' 240 sn_tsu = 'Ice_initialization' , -12. ,'tsu' , .false. , .true., 'yearly' , '' , '', '' 241 sn_tms = 'NOT USED' , -12. ,'tms' , .false. , .true., 'yearly' , '' , '', '' 216 242 ! melt ponds (be careful, sn_apd is the pond concentration (not fraction), so it differs from rn_apd) 217 sn_apd = 'NOT USED' , -12 ,'apd' , .false. , .true., 'yearly' , '' , '', '' 218 sn_hpd = 'NOT USED' , -12 ,'hpd' , .false. , .true., 'yearly' , '' , '', '' 243 sn_apd = 'NOT USED' , -12. ,'apd' , .false. , .true., 'yearly' , '' , '', '' 244 sn_hpd = 'NOT USED' , -12. ,'hpd' , .false. , .true., 'yearly' , '' , '', '' 245 sn_hld = 'NOT USED' , -12. ,'hld' , .false. , .true., 'yearly' , '' , '', '' 219 246 cn_dir='./' 220 247 / … … 238 265 ln_icediahsb = .false. ! output the heat, mass & salt budgets (T) or not (F) 239 266 ln_icectl = .false. ! ice points output for debug (T or F) 240 iiceprt = 10 !i-index for debug241 jiceprt = 10 !j-index for debug242 / 267 iiceprt = 10 ! i-index for debug 268 jiceprt = 10 ! j-index for debug 269 / -
NEMO/branches/2020/r12377_ticket2386/cfgs/SHARED/namelist_pisces_ref
r12377 r13540 352 352 ! 353 353 cn_dir = './' ! root directory for the location of the dynamical files 354 ln_ironsed = . true. ! boolean for Fe input from sediments355 ln_ironice = . true. ! boolean for Fe input from sea ice356 ln_hydrofe = . true. ! boolean for from hydrothermal vents354 ln_ironsed = .false. ! boolean for Fe input from sediments 355 ln_ironice = .false. ! boolean for Fe input from sea ice 356 ln_hydrofe = .false. ! boolean for from hydrothermal vents 357 357 sedfeinput = 2.e-9 ! Coastal release of Iron 358 358 distcoast = 5.e3 ! Distance off the coast for Iron from sediments -
NEMO/branches/2020/r12377_ticket2386/cfgs/SHARED/namelist_ref
r12511 r13540 72 72 ln_linssh = .false. ! =T linear free surface ==>> model level are fixed in time 73 73 ! 74 rn_Dt = 5400. ! time step for the dynamics and tracer74 rn_Dt = 5400. ! time step for the dynamics and tracer 75 75 rn_atfp = 0.1 ! asselin time filter parameter 76 76 ! … … 217 217 nn_ice = 0 ! =0 no ice boundary condition 218 218 ! ! =1 use observed ice-cover ( => fill namsbc_iif ) 219 ! ! =2 or 3 automatically for SI3 or CICE ("key_si3" or "key_cice") 220 ! ! except in AGRIF zoom where it has to be specified 219 ! ! =2 or 3 for SI3 and CICE, respectively 221 220 ln_ice_embd = .false. ! =T embedded sea-ice (pressure + mass and salt exchanges) 222 221 ! ! =F levitating ice (no pressure, mass and salt exchanges) … … 269 268 ln_Cd_L12 = .false. ! air-ice drags = F(ice conc.) (Lupkes et al. 2012) 270 269 ln_Cd_L15 = .false. ! air-ice drags = F(ice conc.) (Lupkes et al. 2015) 271 ! ! - module of the mean stress" data 270 ln_crt_fbk = .false. ! Add surface current feedback to the wind stress (Renault et al. 2020, doi: 10.1029/2019MS001715) 271 rn_stau_a = -2.9e-3 ! Alpha from eq. 10: Stau = Alpha * Wnd + Beta 272 rn_stau_b = 8.0e-3 ! Beta 272 273 rn_pfac = 1. ! multipl. factor for precipitation (total & snow) 273 274 rn_efac = 1. ! multipl. factor for evaporation (0. or 1.) 274 rn_vfac = 0. ! multipl. factor for ocean & ice velocity275 ! ! used to calculate the wind stress276 ! ! (0. => absolute or 1. => relative winds)277 275 ln_skin_cs = .false. ! use the cool-skin parameterization 278 276 ln_skin_wl = .false. ! use the warm-layer parameterization … … 281 279 ln_humi_dpt = .false. ! humidity "sn_humi" is dew-point temperature [K] 282 280 ln_humi_rlh = .false. ! humidity "sn_humi" is relative humidity [%] 281 ln_tpot = .true. !!GS: compute potential temperature or not 283 282 ! 284 283 cn_dir = './' ! root directory for the bulk data location … … 292 291 sn_tair = 't_10.15JUNE2009_fill' , 6. , 'T_10_MOD', .false. , .true. , 'yearly' , 'weights_core_orca2_bilinear_noc.nc' , '' , '' 293 292 sn_humi = 'q_10.15JUNE2009_fill' , 6. , 'Q_10_MOD', .false. , .true. , 'yearly' , 'weights_core_orca2_bilinear_noc.nc' , '' , '' 294 sn_hpgi = 'NONE' , 24. , 'uhpg' , .false. , .false., 'monthly' , 'weights_ERAI3D_F128_2_ORCA2_bicubic', 'UG' , ''295 sn_hpgj = 'NONE' , 24. , 'vhpg' , .false. , .false., 'monthly' , 'weights_ERAI3D_F128_2_ORCA2_bicubic', 'VG' , ''296 293 sn_prec = 'ncar_precip.15JUNE2009_fill', -1. , 'PRC_MOD1', .false. , .true. , 'yearly' , 'weights_core_orca2_bilinear_noc.nc' , '' , '' 297 294 sn_snow = 'ncar_precip.15JUNE2009_fill', -1. , 'SNOW' , .false. , .true. , 'yearly' , 'weights_core_orca2_bilinear_noc.nc' , '' , '' 298 295 sn_slp = 'slp.15JUNE2009_fill' , 6. , 'SLP' , .false. , .true. , 'yearly' , 'weights_core_orca2_bilinear_noc.nc' , '' , '' 296 sn_uoatm = 'NOT USED' , 6. , 'UOATM' , .false. , .true. , 'yearly' , 'weights_core_orca2_bilinear_noc.nc' , 'Uoceatm', '' 297 sn_voatm = 'NOT USED' , 6. , 'VOATM' , .false. , .true. , 'yearly' , 'weights_core_orca2_bilinear_noc.nc' , 'Voceatm', '' 298 sn_cc = 'NOT USED' , 24. , 'CC' , .false. , .true. , 'yearly' , 'weights_core_orca2_bilinear_noc.nc' , '' , '' 299 sn_hpgi = 'NOT USED' , 24. , 'uhpg' , .false. , .false., 'monthly' , 'weights_ERAI3D_F128_2_ORCA2_bicubic', 'UG' , '' 300 sn_hpgj = 'NOT USED' , 24. , 'vhpg' , .false. , .false., 'monthly' , 'weights_ERAI3D_F128_2_ORCA2_bicubic', 'VG' , '' 299 301 / 300 302 !----------------------------------------------------------------------- … … 309 311 cn_ablrst_outdir = "." ! directory to write output abl restarts 310 312 313 ln_rstart_abl = .false. 311 314 ln_hpgls_frc = .false. 312 315 ln_geos_winds = .false. 313 nn_dyn_restore = 2 ! restoring option for dynamical ABL variables: = 0 no restoring 316 ln_smth_pblh = .false. 317 nn_dyn_restore = 0 ! restoring option for dynamical ABL variables: = 0 no restoring 314 318 ! = 1 equatorial restoring 315 319 ! = 2 global restoring 316 rn_ldyn_min = 4.5 ! magnitude of the nudging on ABL dynamics at the bottom of the ABL [hour]317 rn_ldyn_max = 1.5 ! magnitude of the nudging on ABL dynamics at the top of the ABL [hour]318 rn_ltra_min = 4.5 ! magnitude of the nudging on ABL tracers at the bottom of the ABL [hour]319 rn_ltra_max = 1.5 ! magnitude of the nudging on ABL tracers at the top of the ABL [hour]320 rn_ldyn_min = 4.5 ! dynamics nudging magnitude inside the ABL [hour] (~3 rn_Dt) 321 rn_ldyn_max = 1.5 ! dynamics nudging magnitude above the ABL [hour] (~1 rn_Dt) 322 rn_ltra_min = 4.5 ! tracers nudging magnitude inside the ABL [hour] (~3 rn_Dt) 323 rn_ltra_max = 1.5 ! tracers nudging magnitude above the ABL [hour] (~1 rn_Dt) 320 324 nn_amxl = 0 ! mixing length: = 0 Deardorff 80 length-scale 321 325 ! = 1 length-scale based on the distance to the PBL height 322 326 ! = 2 Bougeault & Lacarrere 89 length-scale 323 rn_Cm = 0.0667 ! 0.126 in MesoNH 324 rn_Ct = 0.1667 ! 0.143 in MesoNH 325 rn_Ce = 0.4 ! 0.4 in MesoNH 326 rn_Ceps = 0.7 ! 0.85 in MesoNH 327 rn_Rod = 0.15 ! c0 in RMCA17 mixing length formulation (not yet implemented) 328 rn_Ric = 0.139 ! Critical Richardson number (to compute PBL height and diffusivities) 327 ! CBR00 ! CCH02 ! MesoNH ! 328 rn_Cm = 0.0667 ! 0.0667 ! 0.1260 ! 0.1260 ! 329 rn_Ct = 0.1667 ! 0.1667 ! 0.1430 ! 0.1430 ! 330 rn_Ce = 0.40 ! 0.40 ! 0.34 ! 0.40 ! 331 rn_Ceps = 0.700 ! 0.700 ! 0.845 ! 0.850 ! 332 rn_Ric = 0.139 ! 0.139 ! 0.143 ! ? ! Critical Richardson number (to compute PBL height and diffusivities) 333 rn_Rod = 0.15 ! c0 in RMCA17 mixing length formulation (not yet implemented) 329 334 / 330 335 !----------------------------------------------------------------------- 331 336 &namsbc_cpl ! coupled ocean/atmosphere model ("key_oasis3") 332 337 !----------------------------------------------------------------------- 333 nn_cplmodel = 1 ! Maximum number of models to/from which NEMO is potentially sending/receiving data 334 ln_usecplmask = .false. ! use a coupling mask file to merge data received from several models 335 ! ! -> file cplmask.nc with the float variable called cplmask (jpi,jpj,nn_cplmodel) 336 nn_cats_cpl = 5 ! Number of sea ice categories over which coupling is to be carried out (if not 1) 338 nn_cplmodel = 1 ! Maximum number of models to/from which NEMO is potentially sending/receiving data 339 ln_usecplmask = .false. ! use a coupling mask file to merge data received from several models 340 ! ! -> file cplmask.nc with the float variable called cplmask (jpi,jpj,nn_cplmodel) 341 ln_scale_ice_flux = .false. ! use ice fluxes that are already "ice weighted" ( i.e. multiplied ice concentration) 342 nn_cats_cpl = 5 ! Number of sea ice categories over which coupling is to be carried out (if not 1) 337 343 !_____________!__________________________!____________!_____________!______________________!________! 338 344 ! ! description ! multiple ! vector ! vector ! vector ! … … 540 546 ! ! file name ! frequency (hours) ! variable ! time interp.! clim ! 'yearly'/ ! weights ! rotation ! land/sea mask ! 541 547 ! ! ! (if <0 months) ! name ! (logical) ! (T/F) ! 'monthly' ! filename ! pairing ! filename ! 542 sn_isfpar_zmax = 'isfmlt_par', 0 543 sn_isfpar_zmin = 'isfmlt_par', 0 548 sn_isfpar_zmax = 'isfmlt_par', 0. ,'sozisfmax', .false. , .true. , 'yearly' , '' , '' , '' 549 sn_isfpar_zmin = 'isfmlt_par', 0. ,'sozisfmin', .false. , .true. , 'yearly' , '' , '' , '' 544 550 !* 'spe' and 'oasis' case 545 sn_isfpar_fwf = 'isfmlt_par' , -12. ,'sofwfisf' , .false. , .true. , 'yearly' 551 sn_isfpar_fwf = 'isfmlt_par' , -12. ,'sofwfisf' , .false. , .true. , 'yearly' , '' , '' , '' 546 552 !* 'bg03' case 547 sn_isfpar_Leff = 'isfmlt_par', 0. ,'Leff' , .false. , .true. , 'yearly' 553 sn_isfpar_Leff = 'isfmlt_par', 0. ,'Leff' , .false. , .true. , 'yearly' , '' , '' , '' 548 554 ! 549 555 ! ---------------- ice sheet coupling ------------------------------- … … 639 645 &namagrif ! AGRIF zoom ("key_agrif") 640 646 !----------------------------------------------------------------------- 641 ln_agrif_2way = .true. ! activate two way nesting 642 ln_spc_dyn = .true. ! use 0 as special value for dynamics 643 rn_sponge_tra = 2880. ! coefficient for tracer sponge layer [m2/s] 644 rn_sponge_dyn = 2880. ! coefficient for dynamics sponge layer [m2/s] 645 rn_trelax_tra = 0.01 ! inverse of relaxation time (in steps) for tracers [] 646 rn_trelax_dyn = 0.01 ! inverse of relaxation time (in steps) for dynamics [] 647 ln_chk_bathy = .false. ! =T check the parent bathymetry 647 ln_agrif_2way = .true. ! activate two way nesting 648 ln_init_chfrpar = .false. ! initialize child grids from parent 649 ln_spc_dyn = .true. ! use 0 as special value for dynamics 650 rn_sponge_tra = 0.002 ! coefficient for tracer sponge layer [] 651 rn_sponge_dyn = 0.002 ! coefficient for dynamics sponge layer [] 652 rn_trelax_tra = 0.01 ! inverse of relaxation time (in steps) for tracers [] 653 rn_trelax_dyn = 0.01 ! inverse of relaxation time (in steps) for dynamics [] 654 ln_chk_bathy = .false. ! =T check the parent bathymetry 648 655 / 649 656 !----------------------------------------------------------------------- … … 727 734 bn_aip = 'NOT USED' , 24. , 'siapnd' , .true. , .false., 'daily' , '' , '' , '' 728 735 bn_hip = 'NOT USED' , 24. , 'sihpnd' , .true. , .false., 'daily' , '' , '' , '' 736 bn_hil = 'NOT USED' , 24. , 'sihlid' , .true. , .false., 'daily' , '' , '' , '' 729 737 ! if bn_t_i etc are "not used", then define arbitrary temperatures and salinity and ponds 730 738 rn_ice_tem = 270. ! arbitrary temperature of incoming sea ice … … 733 741 rn_ice_apnd = 0.2 ! -- pond fraction = a_ip/a_i -- 734 742 rn_ice_hpnd = 0.05 ! -- pond depth -- 743 rn_ice_hlid = 0.0 ! -- pond lid depth -- 735 744 / 736 745 !----------------------------------------------------------------------- … … 745 754 !! !! 746 755 !! namdrg top/bottom drag coefficient (default: NO selection) 747 !! namdrg_top top friction (ln_ OFF=F & ln_isfcav=T)748 !! namdrg_bot bottom friction (ln_ OFF=F)756 !! namdrg_top top friction (ln_drg_OFF=F & ln_isfcav=T) 757 !! namdrg_bot bottom friction (ln_drg_OFF=F) 749 758 !! nambbc bottom temperature boundary condition (default: OFF) 750 759 !! nambbl bottom boundary layer scheme (default: OFF) … … 754 763 &namdrg ! top/bottom drag coefficient (default: NO selection) 755 764 !----------------------------------------------------------------------- 756 ln_ OFF= .false. ! free-slip : Cd = 0 (F => fill namdrg_bot765 ln_drg_OFF = .false. ! free-slip : Cd = 0 (F => fill namdrg_bot 757 766 ln_lin = .false. ! linear drag: Cd = Cd0 Uc0 & namdrg_top) 758 767 ln_non_lin = .false. ! non-linear drag: Cd = Cd0 |U| … … 760 769 ! 761 770 ln_drgimp = .true. ! implicit top/bottom friction flag 762 / 763 !----------------------------------------------------------------------- 764 &namdrg_top ! TOP friction (ln_OFF =F & ln_isfcav=T) 771 ln_drgice_imp = .true. ! implicit ice-ocean drag 772 / 773 !----------------------------------------------------------------------- 774 &namdrg_top ! TOP friction (ln_drg_OFF =F & ln_isfcav=T) 765 775 !----------------------------------------------------------------------- 766 776 rn_Cd0 = 1.e-3 ! drag coefficient [-] … … 773 783 / 774 784 !----------------------------------------------------------------------- 775 &namdrg_bot ! BOTTOM friction (ln_ OFF =F)785 &namdrg_bot ! BOTTOM friction (ln_drg_OFF =F) 776 786 !----------------------------------------------------------------------- 777 787 rn_Cd0 = 1.e-3 ! drag coefficient [-] … … 826 836 ! 827 837 ! ! S-EOS coefficients (ln_seos=T): 828 ! ! rd(T,S,Z)*r au0 = -a0*(1+.5*lambda*dT+mu*Z+nu*dS)*dT+b0*dS838 ! ! rd(T,S,Z)*rho0 = -a0*(1+.5*lambda*dT+mu*Z+nu*dS)*dT+b0*dS 829 839 rn_a0 = 1.6550e-1 ! thermal expension coefficient 830 840 rn_b0 = 7.6554e-1 ! saline expension coefficient … … 999 1009 ln_bt_auto = .true. ! Number of sub-step defined from: 1000 1010 rn_bt_cmax = 0.8 ! =T : the Maximum Courant Number allowed 1001 nn_e = 30 ! =F : the number of sub-step in rn_Dt seconds1011 nn_e = 30 ! =F : the number of sub-step in rn_Dt seconds 1002 1012 rn_bt_alpha = 0. ! Temporal diffusion parameter (if ln_bt_av=F) 1003 1013 / … … 1130 1140 rn_bshear = 1.e-20 ! background shear (>0) currently a numerical threshold (do not change it) 1131 1141 nn_pdl = 1 ! Prandtl number function of richarson number (=1, avt=pdl(Ri)*avm) or not (=0, avt=avm) 1132 nn_mxl = 2! mixing length: = 0 bounded by the distance to surface and bottom1142 nn_mxl = 3 ! mixing length: = 0 bounded by the distance to surface and bottom 1133 1143 ! ! = 1 bounded by the local vertical scale factor 1134 1144 ! ! = 2 first vertical derivative of mixing length bounded by 1 1135 1145 ! ! = 3 as =2 with distinct dissipative an mixing length scale 1136 1146 ln_mxl0 = .true. ! surface mixing length scale = F(wind stress) (T) or not (F) 1147 nn_mxlice = 2 ! type of scaling under sea-ice 1148 ! = 0 no scaling under sea-ice 1149 ! = 1 scaling with constant sea-ice thickness 1150 ! = 2 scaling with mean sea-ice thickness ( only with SI3 sea-ice model ) 1151 ! = 3 scaling with maximum sea-ice thickness 1152 rn_mxlice = 10. ! max constant ice thickness value when scaling under sea-ice ( nn_mxlice=1) 1137 1153 rn_mxl0 = 0.04 ! surface buoyancy lenght scale minimum value 1138 ln_drg = .false. ! top/bottom friction added as boundary condition of TKE1139 1154 ln_lc = .true. ! Langmuir cell parameterisation (Axell 2002) 1140 1155 rn_lc = 0.15 ! coef. associated to Langmuir cells … … 1147 1162 ! = 0 constant 10 m length scale 1148 1163 ! = 1 0.5m at the equator to 30m poleward of 40 degrees 1149 rn_eice = 4 ! below sea ice: =0 ON ; =4 OFF when ice fraction > 1/4 1164 nn_eice = 1 ! attenutaion of langmuir & surface wave breaking under ice 1165 ! ! = 0 no impact of ice cover on langmuir & surface wave breaking 1166 ! ! = 1 weigthed by 1-TANH(10*fr_i) 1167 ! ! = 2 weighted by 1-fr_i 1168 ! ! = 3 weighted by 1-MIN(1,4*fr_i) 1150 1169 / 1151 1170 !----------------------------------------------------------------------- … … 1160 1179 rn_charn = 70000. ! Charnock constant for wb induced roughness length 1161 1180 rn_hsro = 0.02 ! Minimum surface roughness 1181 rn_hsri = 0.03 ! Ice-ocean roughness 1162 1182 rn_frac_hs = 1.3 ! Fraction of wave height as roughness (if nn_z0_met>1) 1163 1183 nn_z0_met = 2 ! Method for surface roughness computation (0/1/2/3) 1164 ! ! =3 requires ln_wave=T 1184 ! ! = 3 requires ln_wave=T 1185 nn_z0_ice = 1 ! attenutaion of surface wave breaking under ice 1186 ! ! = 0 no impact of ice cover 1187 ! ! = 1 roughness uses rn_hsri and is weigthed by 1-TANH(10*fr_i) 1188 ! ! = 2 roughness uses rn_hsri and is weighted by 1-fr_i 1189 ! ! = 3 roughness uses rn_hsri and is weighted by 1-MIN(1,4*fr_i) 1165 1190 nn_bc_surf = 1 ! surface condition (0/1=Dir/Neum) 1166 1191 nn_bc_bot = 1 ! bottom condition (0/1=Dir/Neum) … … 1193 1218 ln_mevar = .true. ! variable (T) or constant (F) mixing efficiency 1194 1219 ln_tsdiff = .true. ! account for differential T/S mixing (T) or not (F) 1195 / 1196 1220 1221 cn_dir = './' ! root directory for the iwm data location 1222 !___________!_________________________!___________________!___________!_____________!________!___________!__________________!__________!_______________! 1223 ! ! file name ! frequency (hours) ! variable ! time interp.! clim ! 'yearly'/ ! weights filename ! rotation ! land/sea mask ! 1224 ! ! ! (if <0 months) ! name ! (logical) ! (T/F) ! 'monthly' ! ! pairing ! filename ! 1225 sn_mpb = 'NOT USED' , -12. , 'mixing_power_bot' , .false. , .true. , 'yearly' , '' , '' , '' 1226 sn_mpp = 'NOT USED' , -12. , 'mixing_power_pyc' , .false. , .true. , 'yearly' , '' , '' , '' 1227 sn_mpc = 'NOT USED' , -12. , 'mixing_power_cri' , .false. , .true. , 'yearly' , '' , '' , '' 1228 sn_dsb = 'NOT USED' , -12. , 'decay_scale_bot' , .false. , .true. , 'yearly' , '' , '' , '' 1229 sn_dsc = 'NOT USED' , -12. , 'decay_scale_cri' , .false. , .true. , 'yearly' , '' , '' , '' 1230 / 1197 1231 !!====================================================================== 1198 1232 !! *** Diagnostics namelists *** !! … … 1382 1416 jpni = 0 ! number of processors following i (set automatically if < 1), see also ln_listonly = T 1383 1417 jpnj = 0 ! number of processors following j (set automatically if < 1), see also ln_listonly = T 1418 nn_hls = 1 ! halo width (applies to both rows and columns) 1384 1419 / 1385 1420 !----------------------------------------------------------------------- 1386 1421 &namctl ! Control prints (default: OFF) 1387 1422 !----------------------------------------------------------------------- 1388 sn_cfctl%l_glochk = .FALSE. ! Range sanity checks are local (F) or global (T). Set T for debugging only 1389 sn_cfctl%l_allon = .FALSE. ! IF T activate all options. If F deactivate all unless l_config is T 1390 sn_cfctl%l_config = .TRUE. ! IF .true. then control which reports are written with the following 1391 sn_cfctl%l_runstat = .TRUE. ! switches and which areas produce reports with the proc integer settings. 1392 sn_cfctl%l_trcstat = .FALSE. ! The default settings for the proc integers should ensure 1393 sn_cfctl%l_oceout = .FALSE. ! that all areas report. 1394 sn_cfctl%l_layout = .FALSE. ! 1395 sn_cfctl%l_prtctl = .FALSE. ! 1396 sn_cfctl%l_prttrc = .FALSE. ! 1397 sn_cfctl%l_oasout = .FALSE. ! 1398 sn_cfctl%procmin = 0 ! Minimum area number for reporting [default:0] 1399 sn_cfctl%procmax = 1000000 ! Maximum area number for reporting [default:1000000] 1400 sn_cfctl%procincr = 1 ! Increment for optional subsetting of areas [default:1] 1401 sn_cfctl%ptimincr = 1 ! Timestep increment for writing time step progress info 1402 nn_print = 0 ! level of print (0 no extra print) 1403 nn_ictls = 0 ! start i indice of control sum (use to compare mono versus 1404 nn_ictle = 0 ! end i indice of control sum multi processor runs 1405 nn_jctls = 0 ! start j indice of control over a subdomain) 1406 nn_jctle = 0 ! end j indice of control 1407 nn_isplt = 1 ! number of processors in i-direction 1408 nn_jsplt = 1 ! number of processors in j-direction 1409 ln_timing = .false. ! timing by routine write out in timing.output file 1410 ln_diacfl = .false. ! CFL diagnostics write out in cfl_diagnostics.ascii 1423 sn_cfctl%l_runstat = .TRUE. ! switches and which areas produce reports with the proc integer settings. 1424 sn_cfctl%l_trcstat = .FALSE. ! The default settings for the proc integers should ensure 1425 sn_cfctl%l_oceout = .FALSE. ! that all areas report. 1426 sn_cfctl%l_layout = .FALSE. ! 1427 sn_cfctl%l_prtctl = .FALSE. ! 1428 sn_cfctl%l_prttrc = .FALSE. ! 1429 sn_cfctl%l_oasout = .FALSE. ! 1430 sn_cfctl%procmin = 0 ! Minimum area number for reporting [default:0] 1431 sn_cfctl%procmax = 1000000 ! Maximum area number for reporting [default:1000000] 1432 sn_cfctl%procincr = 1 ! Increment for optional subsetting of areas [default:1] 1433 sn_cfctl%ptimincr = 1 ! Timestep increment for writing time step progress info 1434 nn_ictls = 0 ! start i indice of control sum (use to compare mono versus 1435 nn_ictle = 0 ! end i indice of control sum multi processor runs 1436 nn_jctls = 0 ! start j indice of control over a subdomain) 1437 nn_jctle = 0 ! end j indice of control 1438 nn_isplt = 1 ! number of processors in i-direction 1439 nn_jsplt = 1 ! number of processors in j-direction 1440 ln_timing = .false. ! timing by routine write out in timing.output file 1441 ln_diacfl = .false. ! CFL diagnostics write out in cfl_diagnostics.ascii 1411 1442 / 1412 1443 !-----------------------------------------------------------------------
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