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namelist_ref in trunk/NEMOGCM/CONFIG/SHARED – NEMO

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source: trunk/NEMOGCM/CONFIG/SHARED/namelist_ref @ 5072

Last change on this file since 5072 was 5029, checked in by davestorkey, 10 years ago
Reinstate old formulation of EEN vorticity scheme as an option in NEMO 3.6. See ticket #1375
File size: 91.4 KB

Line
1	!!>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>
2	!! NEMO/OPA : 1 - run manager (namrun)
3	!! namelists 2 - Domain (namcfg, namzgr, namzgr_sco, namdom, namtsd)
4	!! 3 - Surface boundary (namsbc, namsbc_ana, namsbc_flx, namsbc_clio, namsbc_core, namsbc_sas
5	!! namsbc_cpl, namtra_qsr, namsbc_rnf,
6	!! namsbc_apr, namsbc_ssr, namsbc_alb)
7	!! 4 - lateral boundary (namlbc, namcla, namobc, namagrif, nambdy, nambdy_tide)
8	!! 5 - bottom boundary (nambfr, nambbc, nambbl)
9	!! 6 - Tracer (nameos, namtra_adv, namtra_ldf, namtra_dmp)
10	!! 7 - dynamics (namdyn_adv, namdyn_vor, namdyn_hpg, namdyn_spg, namdyn_ldf)
11	!! 8 - Verical physics (namzdf, namzdf_ric, namzdf_tke, namzdf_kpp, namzdf_ddm, namzdf_tmx)
12	!! 9 - diagnostics (namnc4, namtrd, namspr, namflo, namptr, namhsb)
13	!! 10 - miscellaneous (namsol, nammpp, namctl)
14	!! 11 - Obs & Assim (namobs, nam_asminc)
15	!!>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>
16
17	!!======================================================================
18	!! * Run management namelists *
19	!!======================================================================
20	!! namrun parameters of the run
21	!!======================================================================
22	!
23	!-----------------------------------------------------------------------
24	&namrun ! parameters of the run
25	!-----------------------------------------------------------------------
26	nn_no = 0 ! job number (no more used...)
27	cn_exp = "ORCA2" ! experience name
28	nn_it000 = 1 ! first time step
29	nn_itend = 5475 ! last time step (std 5475)
30	nn_date0 = 010101 ! date at nit_0000 (format yyyymmdd) used if ln_rstart=F or (ln_rstart=T and nn_rstctl=0 or 1)
31	nn_leapy = 0 ! Leap year calendar (1) or not (0)
32	ln_rstart = .false. ! start from rest (F) or from a restart file (T)
33	nn_euler = 1 ! = 0 : start with forward time step if ln_rstart=T
34	nn_rstctl = 0 ! restart control ==> activated only if ln_rstart=T
35	! = 0 nn_date0 read in namelist ; nn_it000 : read in namelist
36	! = 1 nn_date0 read in namelist ; nn_it000 : check consistancy between namelist and restart
37	! = 2 nn_date0 read in restart ; nn_it000 : check consistancy between namelist and restart
38	cn_ocerst_in = "restart" ! suffix of ocean restart name (input)
39	cn_ocerst_out = "restart" ! suffix of ocean restart name (output)
40	nn_istate = 0 ! output the initial state (1) or not (0)
41	nn_stock = 5475 ! frequency of creation of a restart file (modulo referenced to 1)
42	nn_write = 5475 ! frequency of write in the output file (modulo referenced to nn_it000)
43	ln_dimgnnn = .false. ! DIMG file format: 1 file for all processors (F) or by processor (T)
44	ln_mskland = .false. ! mask land points in NetCDF outputs (costly: + ~15%)
45	ln_clobber = .false. ! clobber (overwrite) an existing file
46	nn_chunksz = 0 ! chunksize (bytes) for NetCDF file (works only with iom_nf90 routines)
47	/
48	!
49	!!======================================================================
50	!! * Domain namelists *
51	!!======================================================================
52	!! namcfg parameters of the configuration
53	!! namzgr vertical coordinate
54	!! namzgr_sco s-coordinate or hybrid z-s-coordinate
55	!! namdom space and time domain (bathymetry, mesh, timestep)
56	!! namtsd data: temperature & salinity
57	!!======================================================================
58	!
59	!-----------------------------------------------------------------------
60	&namcfg ! parameters of the configuration
61	!-----------------------------------------------------------------------
62	cp_cfg = "default" ! name of the configuration
63	cp_cfz = "no zoom" ! name of the zoom of configuration
64	jp_cfg = 0 ! resolution of the configuration
65	jpidta = 10 ! 1st lateral dimension ( >= jpi )
66	jpjdta = 12 ! 2nd " " ( >= jpj )
67	jpkdta = 31 ! number of levels ( >= jpk )
68	jpiglo = 10 ! 1st dimension of global domain --> i =jpidta
69	jpjglo = 12 ! 2nd - - --> j =jpjdta
70	jpizoom = 1 ! left bottom (i,j) indices of the zoom
71	jpjzoom = 1 ! in data domain indices
72	jperio = 0 ! lateral cond. type (between 0 and 6)
73	! = 0 closed ; = 1 cyclic East-West
74	! = 2 equatorial symmetric ; = 3 North fold T-point pivot
75	! = 4 cyclic East-West AND North fold T-point pivot
76	! = 5 North fold F-point pivot
77	! = 6 cyclic East-West AND North fold F-point pivot
78	/
79	!-----------------------------------------------------------------------
80	&namzgr ! vertical coordinate
81	!-----------------------------------------------------------------------
82	ln_zco = .false. ! z-coordinate - full steps (T/F) ("key_zco" may also be defined)
83	ln_zps = .true. ! z-coordinate - partial steps (T/F)
84	ln_sco = .false. ! s- or hybrid z-s-coordinate (T/F)
85	ln_isfcav = .false. ! ice shelf cavity
86	/
87	!-----------------------------------------------------------------------
88	&namzgr_sco ! s-coordinate or hybrid z-s-coordinate
89	!-----------------------------------------------------------------------
90	ln_s_sh94 = .true. ! Song & Haidvogel 1994 hybrid S-sigma (T)\|
91	ln_s_sf12 = .false. ! Siddorn & Furner 2012 hybrid S-z-sigma (T)\| if both are false the NEMO tanh stretching is applied
92	ln_sigcrit = .false. ! use sigma coordinates below critical depth (T) or Z coordinates (F) for Siddorn & Furner stretch
93	! stretching coefficients for all functions
94	rn_sbot_min = 10.0 ! minimum depth of s-bottom surface (>0) (m)
95	rn_sbot_max = 7000.0 ! maximum depth of s-bottom surface (= ocean depth) (>0) (m)
96	rn_hc = 150.0 ! critical depth for transition to stretched coordinates
97	!!!!!!! Envelop bathymetry
98	rn_rmax = 0.3 ! maximum cut-off r-value allowed (0<r_max<1)
99	!!!!!!! SH94 stretching coefficients (ln_s_sh94 = .true.)
100	rn_theta = 6.0 ! surface control parameter (0<=theta<=20)
101	rn_bb = 0.8 ! stretching with SH94 s-sigma
102	!!!!!!! SF12 stretching coefficient (ln_s_sf12 = .true.)
103	rn_alpha = 4.4 ! stretching with SF12 s-sigma
104	rn_efold = 0.0 ! efold length scale for transition to stretched coord
105	rn_zs = 1.0 ! depth of surface grid box
106	! bottom cell depth (Zb) is a linear function of water depth Zb = H*a + b
107	rn_zb_a = 0.024 ! bathymetry scaling factor for calculating Zb
108	rn_zb_b = -0.2 ! offset for calculating Zb
109	!!!!!!!! Other stretching (not SH94 or SF12) [also uses rn_theta above]
110	rn_thetb = 1.0 ! bottom control parameter (0<=thetb<= 1)
111	/
112	!-----------------------------------------------------------------------
113	&namdom ! space and time domain (bathymetry, mesh, timestep)
114	!-----------------------------------------------------------------------
115	nn_bathy = 1 ! compute (=0) or read (=1) the bathymetry file
116	rn_bathy = 0. ! value of the bathymetry. if (=0) bottom flat at jpkm1
117	nn_closea = 0 ! remove (=0) or keep (=1) closed seas and lakes (ORCA)
118	nn_msh = 0 ! create (=1) a mesh file or not (=0)
119	rn_hmin = -3. ! min depth of the ocean (>0) or min number of ocean level (<0)
120	rn_e3zps_min= 20. ! partial step thickness is set larger than the minimum of
121	rn_e3zps_rat= 0.1 ! rn_e3zps_min and rn_e3zps_rat*e3t, with 0<rn_e3zps_rat<1
122	!
123	rn_rdt = 5760. ! time step for the dynamics (and tracer if nn_acc=0)
124	rn_atfp = 0.1 ! asselin time filter parameter
125	nn_acc = 0 ! acceleration of convergence : =1 used, rdt < rdttra(k)
126	! =0, not used, rdt = rdttra
127	rn_rdtmin = 28800. ! minimum time step on tracers (used if nn_acc=1)
128	rn_rdtmax = 28800. ! maximum time step on tracers (used if nn_acc=1)
129	rn_rdth = 800. ! depth variation of tracer time step (used if nn_acc=1)
130	ln_crs = .false. ! Logical switch for coarsening module
131	jphgr_msh = 0 ! type of horizontal mesh
132	! = 0 curvilinear coordinate on the sphere read in coordinate.nc
133	! = 1 geographical mesh on the sphere with regular grid-spacing
134	! = 2 f-plane with regular grid-spacing
135	! = 3 beta-plane with regular grid-spacing
136	! = 4 Mercator grid with T/U point at the equator
137	ppglam0 = 0.0 ! longitude of first raw and column T-point (jphgr_msh = 1)
138	ppgphi0 = -35.0 ! latitude of first raw and column T-point (jphgr_msh = 1)
139	ppe1_deg = 1.0 ! zonal grid-spacing (degrees)
140	ppe2_deg = 0.5 ! meridional grid-spacing (degrees)
141	ppe1_m = 5000.0 ! zonal grid-spacing (degrees)
142	ppe2_m = 5000.0 ! meridional grid-spacing (degrees)
143	ppsur = -4762.96143546300 ! ORCA r4, r2 and r05 coefficients
144	ppa0 = 255.58049070440 ! (default coefficients)
145	ppa1 = 245.58132232490 !
146	ppkth = 21.43336197938 !
147	ppacr = 3.0 !
148	ppdzmin = 10. ! Minimum vertical spacing
149	pphmax = 5000. ! Maximum depth
150	ldbletanh = .TRUE. ! Use/do not use double tanf function for vertical coordinates
151	ppa2 = 100.760928500000 ! Double tanh function parameters
152	ppkth2 = 48.029893720000 !
153	ppacr2 = 13.000000000000 !
154	/
155	!-----------------------------------------------------------------------
156	&namsplit ! time splitting parameters ("key_dynspg_ts")
157	!-----------------------------------------------------------------------
158	ln_bt_fw = .TRUE. ! Forward integration of barotropic equations
159	ln_bt_av = .TRUE. ! Time filtering of barotropic variables
160	ln_bt_nn_auto = .TRUE. ! Set nn_baro automatically to be just below
161	! a user defined maximum courant number (rn_bt_cmax)
162	nn_baro = 30 ! Number of iterations of barotropic mode
163	! during rn_rdt seconds. Only used if ln_bt_nn_auto=F
164	rn_bt_cmax = 0.8 ! Maximum courant number allowed if ln_bt_nn_auto=T
165	nn_bt_flt = 1 ! Time filter choice
166	! = 0 None
167	! = 1 Boxcar over nn_baro barotropic steps
168	! = 2 Boxcar over 2*nn_baro " "
169	/
170	!-----------------------------------------------------------------------
171	&namcrs ! Grid coarsening for dynamics output and/or
172	! passive tracer coarsened online simulations
173	!-----------------------------------------------------------------------
174	nn_factx = 3 ! Reduction factor of x-direction
175	nn_facty = 3 ! Reduction factor of y-direction
176	nn_binref = 0 ! Bin centering preference: NORTH or EQUAT
177	! 0, coarse grid is binned with preferential treatment of the north fold
178	! 1, coarse grid is binned with centering at the equator
179	! Symmetry with nn_facty being odd-numbered. Asymmetry with even-numbered nn_facty.
180	nn_msh_crs = 1 ! create (=1) a mesh file or not (=0)
181	nn_crs_kz = 0 ! 0, MEAN of volume boxes
182	! 1, MAX of boxes
183	! 2, MIN of boxes
184	ln_crs_wn = .true. ! wn coarsened (T) or computed using horizontal divergence ( F )
185	/
186	!-----------------------------------------------------------------------
187	&namc1d ! 1D configuration options ("key_c1d")
188	!-----------------------------------------------------------------------
189	rn_lat1d = 50 ! Column latitude (default at PAPA station)
190	rn_lon1d = -145 ! Column longitude (default at PAPA station)
191	ln_c1d_locpt= .true. ! Localization of 1D config in a grid (T) or independant point (F)
192	/
193	!-----------------------------------------------------------------------
194	&namtsd ! data : Temperature & Salinity
195	!-----------------------------------------------------------------------
196	!-----------------------------------------------------------------------
197	! ! file name ! frequency (hours) ! variable ! time interp. ! clim ! 'yearly'/ ! weights ! rotation ! land/sea mask !
198	! ! ! (if <0 months) ! name ! (logical) ! (T/F) ! 'monthly' ! filename ! pairing ! filename !
199	sn_tem = 'data_1m_potential_temperature_nomask', -1 ,'votemper' , .true. , .true. , 'yearly' , '' , '' , ''
200	sn_sal = 'data_1m_salinity_nomask' , -1 ,'vosaline' , .true. , .true. , 'yearly' , '' , '' , ''
201	!
202	cn_dir = './' ! root directory for the location of the runoff files
203	ln_tsd_init = .true. ! Initialisation of ocean T & S with T &S input data (T) or not (F)
204	ln_tsd_tradmp = .true. ! damping of ocean T & S toward T &S input data (T) or not (F)
205	/
206	!!======================================================================
207	!! * Surface Boundary Condition namelists *
208	!!======================================================================
209	!! namsbc surface boundary condition
210	!! namsbc_ana analytical formulation
211	!! namsbc_flx flux formulation
212	!! namsbc_clio CLIO bulk formulae formulation
213	!! namsbc_core CORE bulk formulae formulation
214	!! namsbc_mfs MFS bulk formulae formulation
215	!! namsbc_cpl CouPLed formulation ("key_coupled")
216	!! namsbc_sas StAndalone Surface module
217	!! namtra_qsr penetrative solar radiation
218	!! namsbc_rnf river runoffs
219	!! namsbc_isf ice shelf melting/freezing
220	!! namsbc_apr Atmospheric Pressure
221	!! namsbc_ssr sea surface restoring term (for T and/or S)
222	!! namsbc_alb albedo parameters
223	!!======================================================================
224	!
225	!-----------------------------------------------------------------------
226	&namsbc ! Surface Boundary Condition (surface module)
227	!-----------------------------------------------------------------------
228	nn_fsbc = 5 ! frequency of surface boundary condition computation
229	! (also = the frequency of sea-ice model call)
230	ln_ana = .false. ! analytical formulation (T => fill namsbc_ana )
231	ln_flx = .false. ! flux formulation (T => fill namsbc_flx )
232	ln_blk_clio = .false. ! CLIO bulk formulation (T => fill namsbc_clio)
233	ln_blk_core = .true. ! CORE bulk formulation (T => fill namsbc_core)
234	ln_blk_mfs = .false. ! MFS bulk formulation (T => fill namsbc_mfs )
235	ln_apr_dyn = .false. ! Patm gradient added in ocean & ice Eqs. (T => fill namsbc_apr )
236	nn_ice = 2 ! =0 no ice boundary condition ,
237	! =1 use observed ice-cover ,
238	! =2 ice-model used ("key_lim3" or "key_lim2")
239	nn_ice_embd = 1 ! =0 levitating ice (no mass exchange, concentration/dilution effect)
240	! =1 levitating ice with mass and salt exchange but no presure effect
241	! =2 embedded sea-ice (full salt and mass exchanges and pressure)
242	ln_dm2dc = .false. ! daily mean to diurnal cycle on short wave
243	ln_rnf = .true. ! runoffs (T => fill namsbc_rnf)
244	nn_isf = 0 ! ice shelf melting/freezing (/=0 => fill namsbc_isf)
245	! 0 =no isf 1 = presence of ISF
246	! 2 = bg03 parametrisation 3 = rnf file for isf
247	! 4 = ISF fwf specified
248	! option 1 and 4 need ln_isfcav = .true. (domzgr)
249	ln_ssr = .true. ! Sea Surface Restoring on T and/or S (T => fill namsbc_ssr)
250	nn_fwb = 2 ! FreshWater Budget: =0 unchecked
251	! =1 global mean of e-p-r set to zero at each time step
252	! =2 annual global mean of e-p-r set to zero
253	ln_wave = .false. ! Activate coupling with wave (either Stokes Drift or Drag coefficient, or both) (T => fill namsbc_wave)
254	ln_cdgw = .false. ! Neutral drag coefficient read from wave model (T => fill namsbc_wave)
255	ln_sdw = .false. ! Computation of 3D stokes drift (T => fill namsbc_wave)
256	nn_lsm = 0 ! =0 land/sea mask for input fields is not applied (keep empty land/sea mask filename field) ,
257	! =1:n number of iterations of land/sea mask application for input fields (fill land/sea mask filename field)
258	nn_limflx = -1 ! LIM3 Multi-category heat flux formulation (use -1 if LIM3 is not used)
259	! =-1 Use per-category fluxes, bypass redistributor, forced mode only, not yet implemented coupled
260	! = 0 Average per-category fluxes (forced and coupled mode)
261	! = 1 Average and redistribute per-category fluxes, forced mode only, not yet implemented coupled
262	! = 2 Redistribute a single flux over categories (coupled mode only)
263	/
264	!-----------------------------------------------------------------------
265	&namsbc_ana ! analytical surface boundary condition
266	!-----------------------------------------------------------------------
267	nn_tau000 = 0 ! gently increase the stress over the first ntau_rst time-steps
268	rn_utau0 = 0.5 ! uniform value for the i-stress
269	rn_vtau0 = 0.e0 ! uniform value for the j-stress
270	rn_qns0 = 0.e0 ! uniform value for the total heat flux
271	rn_qsr0 = 0.e0 ! uniform value for the solar radiation
272	rn_emp0 = 0.e0 ! uniform value for the freswater budget (E-P)
273	/
274	!-----------------------------------------------------------------------
275	&namsbc_flx ! surface boundary condition : flux formulation
276	!-----------------------------------------------------------------------
277	! ! file name ! frequency (hours) ! variable ! time interp. ! clim ! 'yearly'/ ! weights ! rotation ! land/sea mask !
278	! ! ! (if <0 months) ! name ! (logical) ! (T/F) ! 'monthly' ! filename ! pairing ! filename !
279	sn_utau = 'utau' , 24 , 'utau' , .false. , .false., 'yearly' , '' , '' , ''
280	sn_vtau = 'vtau' , 24 , 'vtau' , .false. , .false., 'yearly' , '' , '' , ''
281	sn_qtot = 'qtot' , 24 , 'qtot' , .false. , .false., 'yearly' , '' , '' , ''
282	sn_qsr = 'qsr' , 24 , 'qsr' , .false. , .false., 'yearly' , '' , '' , ''
283	sn_emp = 'emp' , 24 , 'emp' , .false. , .false., 'yearly' , '' , '' , ''
284
285	cn_dir = './' ! root directory for the location of the flux files
286	/
287	!-----------------------------------------------------------------------
288	&namsbc_clio ! namsbc_clio CLIO bulk formulae
289	!-----------------------------------------------------------------------
290	! ! file name ! frequency (hours) ! variable ! time interp. ! clim ! 'yearly'/ ! weights ! rotation ! land/sea mask !
291	! ! ! (if <0 months) ! name ! (logical) ! (T/F) ! 'monthly' ! filename ! pairing ! filename !
292	sn_utau = 'taux_1m' , -1 , 'sozotaux', .true. , .true. , 'yearly' , '' , '' , ''
293	sn_vtau = 'tauy_1m' , -1 , 'sometauy', .true. , .true. , 'yearly' , '' , '' , ''
294	sn_wndm = 'flx' , -1 , 'socliowi', .true. , .true. , 'yearly' , '' , '' , ''
295	sn_tair = 'flx' , -1 , 'socliot2', .true. , .true. , 'yearly' , '' , '' , ''
296	sn_humi = 'flx' , -1 , 'socliohu', .true. , .true. , 'yearly' , '' , '' , ''
297	sn_ccov = 'flx' , -1 , 'socliocl', .false. , .true. , 'yearly' , '' , '' , ''
298	sn_prec = 'flx' , -1 , 'socliopl', .false. , .true. , 'yearly' , '' , '' , ''
299
300	cn_dir = './' ! root directory for the location of the bulk files are
301	/
302	!-----------------------------------------------------------------------
303	&namsbc_core ! namsbc_core CORE bulk formulae
304	!-----------------------------------------------------------------------
305	! ! file name ! frequency (hours) ! variable ! time interp. ! clim ! 'yearly'/ ! weights ! rotation ! land/sea mask !
306	! ! ! (if <0 months) ! name ! (logical) ! (T/F) ! 'monthly' ! filename ! pairing ! filename !
307	sn_wndi = 'u_10.15JUNE2009_fill' , 6 , 'U_10_MOD', .false. , .true. , 'yearly' , 'weights_core_orca2_bicubic_noc.nc' , 'Uwnd' , ''
308	sn_wndj = 'v_10.15JUNE2009_fill' , 6 , 'V_10_MOD', .false. , .true. , 'yearly' , 'weights_core_orca2_bicubic_noc.nc' , 'Vwnd' , ''
309	sn_qsr = 'ncar_rad.15JUNE2009_fill' , 24 , 'SWDN_MOD', .false. , .true. , 'yearly' , 'weights_core_orca2_bilinear_noc.nc' , '' , ''
310	sn_qlw = 'ncar_rad.15JUNE2009_fill' , 24 , 'LWDN_MOD', .false. , .true. , 'yearly' , 'weights_core_orca2_bilinear_noc.nc' , '' , ''
311	sn_tair = 't_10.15JUNE2009_fill' , 6 , 'T_10_MOD', .false. , .true. , 'yearly' , 'weights_core_orca2_bilinear_noc.nc' , '' , ''
312	sn_humi = 'q_10.15JUNE2009_fill' , 6 , 'Q_10_MOD', .false. , .true. , 'yearly' , 'weights_core_orca2_bilinear_noc.nc' , '' , ''
313	sn_prec = 'ncar_precip.15JUNE2009_fill' , -1 , 'PRC_MOD1', .false. , .true. , 'yearly' , 'weights_core_orca2_bilinear_noc.nc' , '' , ''
314	sn_snow = 'ncar_precip.15JUNE2009_fill' , -1 , 'SNOW' , .false. , .true. , 'yearly' , 'weights_core_orca2_bilinear_noc.nc' , '' , ''
315	sn_tdif = 'taudif_core' , 24 , 'taudif' , .false. , .true. , 'yearly' , 'weights_core_orca2_bilinear_noc.nc' , '' , ''
316
317	cn_dir = './' ! root directory for the location of the bulk files
318	ln_taudif = .false. ! HF tau contribution: use "mean of stress module - module of the mean stress" data
319	rn_zqt = 10. ! Air temperature and humidity reference height (m)
320	rn_zu = 10. ! Wind vector reference height (m)
321	rn_pfac = 1. ! multiplicative factor for precipitation (total & snow)
322	rn_efac = 1. ! multiplicative factor for evaporation (0. or 1.)
323	rn_vfac = 0. ! multiplicative factor for ocean/ice velocity
324	! in the calculation of the wind stress (0.=absolute winds or 1.=relative winds)
325	/
326	!-----------------------------------------------------------------------
327	&namsbc_mfs ! namsbc_mfs MFS bulk formulae
328	!-----------------------------------------------------------------------
329	! ! file name ! frequency (hours) ! variable ! time interp. ! clim ! 'yearly'/ ! weights ! rotation ! land/sea mask !
330	! ! ! (if <0 months) ! name ! (logical) ! (T/F) ! 'monthly' ! filename ! pairing ! filename !
331	sn_wndi = 'ecmwf' , 6 , 'u10' , .true. , .false. , 'daily' ,'bicubic.nc' , '' , ''
332	sn_wndj = 'ecmwf' , 6 , 'v10' , .true. , .false. , 'daily' ,'bicubic.nc' , '' , ''
333	sn_clc = 'ecmwf' , 6 , 'clc' , .true. , .false. , 'daily' ,'bilinear.nc', '' , ''
334	sn_msl = 'ecmwf' , 6 , 'msl' , .true. , .false. , 'daily' ,'bicubic.nc' , '' , ''
335	sn_tair = 'ecmwf' , 6 , 't2' , .true. , .false. , 'daily' ,'bicubic.nc' , '' , ''
336	sn_rhm = 'ecmwf' , 6 , 'rh' , .true. , .false. , 'daily' ,'bilinear.nc', '' , ''
337	sn_prec = 'ecmwf' , 6 , 'precip' , .true. , .true. , 'daily' ,'bicubic.nc' , '' , ''
338
339	cn_dir = './ECMWF/' ! root directory for the location of the bulk files
340	/
341	!-----------------------------------------------------------------------
342	&namsbc_cpl ! coupled ocean/atmosphere model ("key_coupled")
343	!-----------------------------------------------------------------------
344	! ! description ! multiple ! vector ! vector ! vector !
345	! ! ! categories ! reference ! orientation ! grids !
346	! send
347	sn_snd_temp = 'weighted oce and ice' , 'no' , '' , '' , ''
348	sn_snd_alb = 'weighted ice' , 'no' , '' , '' , ''
349	sn_snd_thick = 'none' , 'no' , '' , '' , ''
350	sn_snd_crt = 'none' , 'no' , 'spherical' , 'eastward-northward' , 'T'
351	sn_snd_co2 = 'coupled' , 'no' , '' , '' , ''
352	! receive
353	sn_rcv_w10m = 'none' , 'no' , '' , '' , ''
354	sn_rcv_taumod = 'coupled' , 'no' , '' , '' , ''
355	sn_rcv_tau = 'oce only' , 'no' , 'cartesian' , 'eastward-northward', 'U,V'
356	sn_rcv_dqnsdt = 'coupled' , 'no' , '' , '' , ''
357	sn_rcv_qsr = 'oce and ice' , 'no' , '' , '' , ''
358	sn_rcv_qns = 'oce and ice' , 'no' , '' , '' , ''
359	sn_rcv_emp = 'conservative' , 'no' , '' , '' , ''
360	sn_rcv_rnf = 'coupled' , 'no' , '' , '' , ''
361	sn_rcv_cal = 'coupled' , 'no' , '' , '' , ''
362	sn_rcv_co2 = 'coupled' , 'no' , '' , '' , ''
363	!
364	nn_cplmodel = 1 ! Maximum number of models to/from which NEMO is potentialy sending/receiving data
365	ln_usecplmask = .false. ! use a coupling mask file to merge data received from several models
366	! -> file cplmask.nc with the float variable called cplmask (jpi,jpj,nn_cplmodel)
367	/
368	!-----------------------------------------------------------------------
369	&namsbc_sas ! analytical surface boundary condition
370	!-----------------------------------------------------------------------
371	! ! file name ! frequency (hours) ! variable ! time interp. ! clim ! 'yearly'/ ! weights ! rotation ! land/sea mask !
372	! ! ! (if <0 months) ! name ! (logical) ! (T/F) ! 'monthly' ! filename ! pairing ! filename !
373	sn_usp = 'sas_grid_U' , 120 , 'vozocrtx' , .true. , .true. , 'yearly' , '' , '' , ''
374	sn_vsp = 'sas_grid_V' , 120 , 'vomecrty' , .true. , .true. , 'yearly' , '' , '' , ''
375	sn_tem = 'sas_grid_T' , 120 , 'sosstsst' , .true. , .true. , 'yearly' , '' , '' , ''
376	sn_sal = 'sas_grid_T' , 120 , 'sosaline' , .true. , .true. , 'yearly' , '' , '' , ''
377	sn_ssh = 'sas_grid_T' , 120 , 'sossheig' , .true. , .true. , 'yearly' , '' , '' , ''
378
379	ln_3d_uv = .true. ! specify whether we are supplying a 3D u,v field
380	cn_dir = './' ! root directory for the location of the bulk files are
381	/
382	!-----------------------------------------------------------------------
383	&namtra_qsr ! penetrative solar radiation
384	!-----------------------------------------------------------------------
385	! ! file name ! frequency (hours) ! variable ! time interp. ! clim ! 'yearly'/ ! weights ! rotation ! land/sea mask !
386	! ! ! (if <0 months) ! name ! (logical) ! (T/F) ! 'monthly' ! filename ! pairing ! filename !
387	sn_chl ='chlorophyll', -1 , 'CHLA' , .true. , .true. , 'yearly' , '' , '' , ''
388
389	cn_dir = './' ! root directory for the location of the runoff files
390	ln_traqsr = .true. ! Light penetration (T) or not (F)
391	ln_qsr_rgb = .true. ! RGB (Red-Green-Blue) light penetration
392	ln_qsr_2bd = .false. ! 2 bands light penetration
393	ln_qsr_bio = .false. ! bio-model light penetration
394	nn_chldta = 1 ! RGB : Chl data (=1) or cst value (=0)
395	rn_abs = 0.58 ! RGB & 2 bands: fraction of light (rn_si1)
396	rn_si0 = 0.35 ! RGB & 2 bands: shortess depth of extinction
397	rn_si1 = 23.0 ! 2 bands: longest depth of extinction
398	ln_qsr_ice = .true. ! light penetration for ice-model LIM3
399	/
400	!-----------------------------------------------------------------------
401	&namsbc_rnf ! runoffs namelist surface boundary condition
402	!-----------------------------------------------------------------------
403	! ! file name ! frequency (hours) ! variable ! time interp. ! clim ! 'yearly'/ ! weights ! rotation ! land/sea mask !
404	! ! ! (if <0 months) ! name ! (logical) ! (T/F) ! 'monthly' ! filename ! pairing ! filename !
405	sn_rnf = 'runoff_core_monthly', -1 , 'sorunoff', .true. , .true. , 'yearly' , '' , '' , ''
406	sn_cnf = 'runoff_core_monthly', 0 , 'socoefr0', .false. , .true. , 'yearly' , '' , '' , ''
407	sn_s_rnf = 'runoffs' , 24 , 'rosaline', .true. , .true. , 'yearly' , '' , '' , ''
408	sn_t_rnf = 'runoffs' , 24 , 'rotemper', .true. , .true. , 'yearly' , '' , '' , ''
409	sn_dep_rnf = 'runoffs' , 0 , 'rodepth' , .false. , .true. , 'yearly' , '' , '' , ''
410
411	cn_dir = './' ! root directory for the location of the runoff files
412	ln_rnf_emp = .false. ! runoffs included into precipitation field (T) or into a file (F)
413	ln_rnf_mouth = .true. ! specific treatment at rivers mouths
414	rn_hrnf = 15.e0 ! depth over which enhanced vertical mixing is used
415	rn_avt_rnf = 1.e-3 ! value of the additional vertical mixing coef. [m2/s]
416	rn_rfact = 1.e0 ! multiplicative factor for runoff
417	ln_rnf_depth = .false. ! read in depth information for runoff
418	ln_rnf_tem = .false. ! read in temperature information for runoff
419	ln_rnf_sal = .false. ! read in salinity information for runoff
420	/
421	!-----------------------------------------------------------------------
422	&namsbc_isf ! Top boundary layer (ISF)
423	!-----------------------------------------------------------------------
424	! ! file name ! frequency (hours) ! variable ! time interpol. ! clim ! 'yearly'/ ! weights ! rotation !
425	! ! ! (if <0 months) ! name ! (logical) ! (T/F) ! 'monthly' ! filename ! pairing !
426	! nn_isf == 4
427	sn_qisf = 'rnfisf' , -12 ,'sohflisf', .false. , .true. , 'yearly' , '' , ''
428	sn_fwfisf = 'rnfisf' , -12 ,'sowflisf', .false. , .true. , 'yearly' , '' , ''
429	! nn_isf == 3
430	sn_rnfisf = 'runoffs' , -12 ,'sofwfisf', .false. , .true. , 'yearly' , '' , ''
431	! nn_isf == 2 and 3
432	sn_depmax_isf = 'runoffs' , -12 ,'sozisfmax' , .false. , .true. , 'yearly' , '' , ''
433	sn_depmin_isf = 'runoffs' , -12 ,'sozisfmin' , .false. , .true. , 'yearly' , '' , ''
434	! nn_isf == 2
435	sn_Leff_isf = 'rnfisf' , 0 ,'Leff' , .false. , .true. , 'yearly' , '' , ''
436	! for all case
437	ln_divisf = .true. ! apply isf melting as a mass flux or in the salinity trend. (maybe I should remove this option as for runoff?)
438	! only for nn_isf = 1 or 2
439	rn_gammat0 = 1.0e-4 ! gammat coefficient used in blk formula
440	rn_gammas0 = 1.0e-4 ! gammas coefficient used in blk formula
441	! only for nn_isf = 1
442	nn_isfblk = 1 ! 1 ISOMIP ; 2 conservative (3 equation formulation, Jenkins et al. 1991 ??)
443	rn_hisf_tbl = 30. ! thickness of the top boundary layer (Losh et al. 2008)
444	! 0 => thickness of the tbl = thickness of the first wet cell
445	ln_conserve = .true. ! conservative case (take into account meltwater advection)
446	nn_gammablk = 1 ! 0 = cst Gammat (= gammat/s)
447	! 1 = velocity dependend Gamma (u* * gammat/s) (Jenkins et al. 2010)
448	! if you want to keep the cd as in global config, adjust rn_gammat0 to compensate
449	! 2 = velocity and stability dependent Gamma Holland et al. 1999
450	/
451	!-----------------------------------------------------------------------
452	&namsbc_apr ! Atmospheric pressure used as ocean forcing or in bulk
453	!-----------------------------------------------------------------------
454	! ! file name ! frequency (hours) ! variable ! time interp. ! clim ! 'yearly'/ ! weights ! rotation ! land/sea mask !
455	! ! ! (if <0 months) ! name ! (logical) ! (T/F) ! 'monthly' ! filename ! pairing ! filename !
456	sn_apr = 'patm' , -1 ,'somslpre', .true. , .true. , 'yearly' , '' , '' , ''
457
458	cn_dir = './' ! root directory for the location of the bulk files
459	rn_pref = 101000._wp ! reference atmospheric pressure [N/m2]/
460	ln_ref_apr = .false. ! ref. pressure: global mean Patm (T) or a constant (F)
461	ln_apr_obc = .false. ! inverse barometer added to OBC ssh data
462	/
463	!-----------------------------------------------------------------------
464	&namsbc_ssr ! surface boundary condition : sea surface restoring
465	!-----------------------------------------------------------------------
466	! ! file name ! frequency (hours) ! variable ! time interp. ! clim ! 'yearly'/ ! weights ! rotation ! land/sea mask !
467	! ! ! (if <0 months) ! name ! (logical) ! (T/F) ! 'monthly' ! filename ! pairing ! filename !
468	sn_sst = 'sst_data' , 24 , 'sst' , .false. , .false., 'yearly' , '' , '' , ''
469	sn_sss = 'sss_data' , -1 , 'sss' , .true. , .true. , 'yearly' , '' , '' , ''
470
471	cn_dir = './' ! root directory for the location of the runoff files
472	nn_sstr = 0 ! add a retroaction term in the surface heat flux (=1) or not (=0)
473	nn_sssr = 2 ! add a damping term in the surface freshwater flux (=2)
474	! or to SSS only (=1) or no damping term (=0)
475	rn_dqdt = -40. ! magnitude of the retroaction on temperature [W/m2/K]
476	rn_deds = -166.67 ! magnitude of the damping on salinity [mm/day]
477	ln_sssr_bnd = .true. ! flag to bound erp term (associated with nn_sssr=2)
478	rn_sssr_bnd = 4.e0 ! ABS(Max/Min) value of the damping erp term [mm/day]
479	/
480	!-----------------------------------------------------------------------
481	&namsbc_alb ! albedo parameters
482	!-----------------------------------------------------------------------
483	rn_cloud = 0.06 ! cloud correction to snow and ice albedo
484	rn_albice = 0.53 ! albedo of melting ice in the arctic and antarctic
485	rn_alphd = 0.80 ! coefficients for linear interpolation used to
486	rn_alphc = 0.65 ! compute albedo between two extremes values
487	rn_alphdi = 0.72 ! (Pyane, 1972)
488	/
489	!-----------------------------------------------------------------------
490	&namberg ! iceberg parameters
491	!-----------------------------------------------------------------------
492	ln_icebergs = .false.
493	ln_bergdia = .true. ! Calculate budgets
494	nn_verbose_level = 1 ! Turn on more verbose output if level > 0
495	nn_verbose_write = 15 ! Timesteps between verbose messages
496	nn_sample_rate = 1 ! Timesteps between sampling for trajectory storage
497	! Initial mass required for an iceberg of each class
498	rn_initial_mass = 8.8e7, 4.1e8, 3.3e9, 1.8e10, 3.8e10, 7.5e10, 1.2e11, 2.2e11, 3.9e11, 7.4e11
499	! Proportion of calving mass to apportion to each class
500	rn_distribution = 0.24, 0.12, 0.15, 0.18, 0.12, 0.07, 0.03, 0.03, 0.03, 0.02
501	! Ratio between effective and real iceberg mass (non-dim)
502	! i.e. number of icebergs represented at a point
503	rn_mass_scaling = 2000, 200, 50, 20, 10, 5, 2, 1, 1, 1
504	! thickness of newly calved bergs (m)
505	rn_initial_thickness = 40., 67., 133., 175., 250., 250., 250., 250., 250., 250.
506	rn_rho_bergs = 850. ! Density of icebergs
507	rn_LoW_ratio = 1.5 ! Initial ratio L/W for newly calved icebergs
508	ln_operator_splitting = .true. ! Use first order operator splitting for thermodynamics
509	rn_bits_erosion_fraction = 0. ! Fraction of erosion melt flux to divert to bergy bits
510	rn_sicn_shift = 0. ! Shift of sea-ice concn in erosion flux (0<sicn_shift<1)
511	ln_passive_mode = .false. ! iceberg - ocean decoupling
512	nn_test_icebergs = 10 ! Create test icebergs of this class (-1 = no)
513	! Put a test iceberg at each gridpoint in box (lon1,lon2,lat1,lat2)
514	rn_test_box = 108.0, 116.0, -66.0, -58.0
515	rn_speed_limit = 0. ! CFL speed limit for a berg
516
517	! ! file name ! frequency (hours) ! variable ! time interp. ! clim ! 'yearly'/ ! weights ! rotation ! land/sea mask !
518	! ! ! (if <0 months) ! name ! (logical) ! (T/F ) ! 'monthly' ! filename ! pairing ! filename !
519	sn_icb = 'calving' , -1 , 'calvingmask', .true. , .true. , 'yearly' , '' , '' , ''
520
521	cn_dir = './'
522	/
523
524	!!======================================================================
525	!! * Lateral boundary condition *
526	!!======================================================================
527	!! namlbc lateral momentum boundary condition
528	!! namcla cross land advection
529	!! namobc open boundaries parameters ("key_obc")
530	!! namagrif agrif nested grid ( read by child model only ) ("key_agrif")
531	!! nambdy Unstructured open boundaries ("key_bdy")
532	!! namtide Tidal forcing at open boundaries ("key_bdy_tides")
533	!!======================================================================
534	!
535	!-----------------------------------------------------------------------
536	&namlbc ! lateral momentum boundary condition
537	!-----------------------------------------------------------------------
538	rn_shlat = 2. ! shlat = 0 ! 0 < shlat < 2 ! shlat = 2 ! 2 < shlat
539	! free slip ! partial slip ! no slip ! strong slip
540	ln_vorlat = .false. ! consistency of vorticity boundary condition with analytical eqs.
541	/
542	!-----------------------------------------------------------------------
543	&namcla ! cross land advection
544	!-----------------------------------------------------------------------
545	nn_cla = 0 ! advection between 2 ocean pts separates by land
546	/
547	!-----------------------------------------------------------------------
548	&namobc ! open boundaries parameters ("key_obc")
549	!-----------------------------------------------------------------------
550	ln_obc_clim = .false. ! climatological obc data files (T) or not (F)
551	ln_vol_cst = .true. ! impose the total volume conservation (T) or not (F)
552	ln_obc_fla = .false. ! Flather open boundary condition
553	nn_obcdta = 1 ! = 0 the obc data are equal to the initial state
554	! = 1 the obc data are read in 'obc.dta' files
555	cn_obcdta = 'annual' ! set to annual if obc datafile hold 1 year of data
556	! set to monthly if obc datafile hold 1 month of data
557	rn_dpein = 1. ! damping time scale for inflow at east open boundary
558	rn_dpwin = 1. ! - - - west - -
559	rn_dpnin = 1. ! - - - north - -
560	rn_dpsin = 1. ! - - - south - -
561	rn_dpeob = 3000. ! time relaxation (days) for the east open boundary
562	rn_dpwob = 15. ! - - - west - -
563	rn_dpnob = 3000. ! - - - north - -
564	rn_dpsob = 15. ! - - - south - -
565	rn_volemp = 1. ! = 0 the total volume change with the surface flux (E-P-R)
566	! = 1 the total volume remains constant
567	/
568	!-----------------------------------------------------------------------
569	&namagrif ! AGRIF zoom ("key_agrif")
570	!-----------------------------------------------------------------------
571	nn_cln_update = 3 ! baroclinic update frequency
572	ln_spc_dyn = .true. ! use 0 as special value for dynamics
573	rn_sponge_tra = 2880. ! coefficient for tracer sponge layer [m2/s]
574	rn_sponge_dyn = 2880. ! coefficient for dynamics sponge layer [m2/s]
575	/
576	!-----------------------------------------------------------------------
577	&nam_tide ! tide parameters (#ifdef key_tide)
578	!-----------------------------------------------------------------------
579	ln_tide_pot = .true. ! use tidal potential forcing
580	ln_tide_ramp = .false. !
581	rdttideramp = 0. !
582	clname(1) = 'M2' ! name of constituent
583	clname(2) = 'S2'
584	clname(3) = 'N2'
585	clname(4) = 'K1'
586	clname(5) = 'O1'
587	clname(6) = 'Q1'
588	clname(7) = 'M4'
589	clname(8) = 'K2'
590	clname(9) = 'P1'
591	clname(10) = 'Mf'
592	clname(11) = 'Mm'
593	/
594	!-----------------------------------------------------------------------
595	&nambdy ! unstructured open boundaries ("key_bdy")
596	!-----------------------------------------------------------------------
597	nb_bdy = 0 ! number of open boundary sets
598	ln_coords_file = .true. ! =T : read bdy coordinates from file
599	cn_coords_file = 'coordinates.bdy.nc' ! bdy coordinates files
600	ln_mask_file = .false. ! =T : read mask from file
601	cn_mask_file = '' ! name of mask file (if ln_mask_file=.TRUE.)
602	cn_dyn2d = 'none' !
603	nn_dyn2d_dta = 0 ! = 0, bdy data are equal to the initial state
604	! = 1, bdy data are read in 'bdydata .nc' files
605	! = 2, use tidal harmonic forcing data from files
606	! = 3, use external data AND tidal harmonic forcing
607	cn_dyn3d = 'none' !
608	nn_dyn3d_dta = 0 ! = 0, bdy data are equal to the initial state
609	! = 1, bdy data are read in 'bdydata .nc' files
610	cn_tra = 'none' !
611	nn_tra_dta = 0 ! = 0, bdy data are equal to the initial state
612	! = 1, bdy data are read in 'bdydata .nc' files
613	cn_ice_lim = 'none' !
614	nn_ice_lim_dta = 0 ! = 0, bdy data are equal to the initial state
615	! = 1, bdy data are read in 'bdydata .nc' files
616	rn_ice_tem = 270. ! lim3 only: arbitrary temperature of incoming sea ice
617	rn_ice_sal = 10. ! lim3 only: -- salinity --
618	rn_ice_age = 30. ! lim3 only: -- age --
619
620	ln_tra_dmp =.false. ! open boudaries conditions for tracers
621	ln_dyn3d_dmp =.false. ! open boundary condition for baroclinic velocities
622	rn_time_dmp = 1. ! Damping time scale in days
623	rn_time_dmp_out = 1. ! Outflow damping time scale
624	nn_rimwidth = 10 ! width of the relaxation zone
625	ln_vol = .false. ! total volume correction (see nn_volctl parameter)
626	nn_volctl = 1 ! = 0, the total water flux across open boundaries is zero
627	/
628	!-----------------------------------------------------------------------
629	&nambdy_dta ! open boundaries - external data ("key_bdy")
630	!-----------------------------------------------------------------------
631	! ! file name ! frequency (hours) ! variable ! time interp. ! clim ! 'yearly'/ ! weights ! rotation ! land/sea mask !
632	! ! ! (if <0 months) ! name ! (logical) ! (T/F ) ! 'monthly' ! filename ! pairing ! filename !
633	bn_ssh = 'amm12_bdyT_u2d' , 24 , 'sossheig' , .true. , .false. , 'daily' , '' , '' , ''
634	bn_u2d = 'amm12_bdyU_u2d' , 24 , 'vobtcrtx' , .true. , .false. , 'daily' , '' , '' , ''
635	bn_v2d = 'amm12_bdyV_u2d' , 24 , 'vobtcrty' , .true. , .false. , 'daily' , '' , '' , ''
636	bn_u3d = 'amm12_bdyU_u3d' , 24 , 'vozocrtx' , .true. , .false. , 'daily' , '' , '' , ''
637	bn_v3d = 'amm12_bdyV_u3d' , 24 , 'vomecrty' , .true. , .false. , 'daily' , '' , '' , ''
638	bn_tem = 'amm12_bdyT_tra' , 24 , 'votemper' , .true. , .false. , 'daily' , '' , '' , ''
639	bn_sal = 'amm12_bdyT_tra' , 24 , 'vosaline' , .true. , .false. , 'daily' , '' , '' , ''
640	! for lim2
641	! bn_frld = 'amm12_bdyT_ice' , 24 , 'ileadfra' , .true. , .false. , 'daily' , '' , '' , ''
642	! bn_hicif = 'amm12_bdyT_ice' , 24 , 'iicethic' , .true. , .false. , 'daily' , '' , '' , ''
643	! bn_hsnif = 'amm12_bdyT_ice' , 24 , 'isnowthi' , .true. , .false. , 'daily' , '' , '' , ''
644	! for lim3
645	! bn_a_i = 'amm12_bdyT_ice' , 24 , 'ileadfra' , .true. , .false. , 'daily' , '' , '' , ''
646	! bn_ht_i = 'amm12_bdyT_ice' , 24 , 'iicethic' , .true. , .false. , 'daily' , '' , '' , ''
647	! bn_ht_s = 'amm12_bdyT_ice' , 24 , 'isnowthi' , .true. , .false. , 'daily' , '' , '' , ''
648	cn_dir = 'bdydta/'
649	ln_full_vel = .false.
650	/
651	!-----------------------------------------------------------------------
652	&nambdy_tide ! tidal forcing at open boundaries
653	!-----------------------------------------------------------------------
654	filtide = 'bdydta/amm12_bdytide_' ! file name root of tidal forcing files
655	ln_bdytide_2ddta = .false.
656	ln_bdytide_conj = .false.
657	/
658	!!======================================================================
659	!! * Bottom boundary condition *
660	!!======================================================================
661	!! nambfr bottom friction
662	!! nambbc bottom temperature boundary condition
663	!! nambbl bottom boundary layer scheme ("key_trabbl")
664	!!======================================================================
665	!
666	!-----------------------------------------------------------------------
667	&nambfr ! bottom friction
668	!-----------------------------------------------------------------------
669	nn_bfr = 1 ! type of bottom friction : = 0 : free slip, = 1 : linear friction
670	! = 2 : nonlinear friction
671	rn_bfri1 = 4.e-4 ! bottom drag coefficient (linear case)
672	rn_bfri2 = 1.e-3 ! bottom drag coefficient (non linear case). Minimum coeft if ln_loglayer=T
673	rn_bfri2_max = 1.e-1 ! max. bottom drag coefficient (non linear case and ln_loglayer=T)
674	rn_bfeb2 = 2.5e-3 ! bottom turbulent kinetic energy background (m2/s2)
675	rn_bfrz0 = 3.e-3 ! bottom roughness [m] if ln_loglayer=T
676	ln_bfr2d = .false. ! horizontal variation of the bottom friction coef (read a 2D mask file )
677	rn_bfrien = 50. ! local multiplying factor of bfr (ln_bfr2d=T)
678	rn_tfri1 = 4.e-4 ! top drag coefficient (linear case)
679	rn_tfri2 = 2.5e-3 ! top drag coefficient (non linear case). Minimum coeft if ln_loglayer=T
680	rn_tfri2_max = 1.e-1 ! max. top drag coefficient (non linear case and ln_loglayer=T)
681	rn_tfeb2 = 0.0 ! top turbulent kinetic energy background (m2/s2)
682	rn_tfrz0 = 3.e-3 ! top roughness [m] if ln_loglayer=T
683	ln_tfr2d = .false. ! horizontal variation of the top friction coef (read a 2D mask file )
684	rn_tfrien = 50. ! local multiplying factor of tfr (ln_tfr2d=T)
685
686	ln_bfrimp = .true. ! implicit bottom friction (requires ln_zdfexp = .false. if true)
687	ln_loglayer = .false. ! logarithmic formulation (non linear case)
688	/
689	!-----------------------------------------------------------------------
690	&nambbc ! bottom temperature boundary condition
691	!-----------------------------------------------------------------------
692	ln_trabbc = .true. ! Apply a geothermal heating at the ocean bottom
693	nn_geoflx = 2 ! geothermal heat flux: = 0 no flux
694	! = 1 constant flux
695	! = 2 variable flux (read in geothermal_heating.nc in mW/m2)
696	rn_geoflx_cst = 86.4e-3 ! Constant value of geothermal heat flux [W/m2]
697	/
698	!-----------------------------------------------------------------------
699	&nambbl ! bottom boundary layer scheme
700	!-----------------------------------------------------------------------
701	nn_bbl_ldf = 1 ! diffusive bbl (=1) or not (=0)
702	nn_bbl_adv = 0 ! advective bbl (=1/2) or not (=0)
703	rn_ahtbbl = 1000. ! lateral mixing coefficient in the bbl [m2/s]
704	rn_gambbl = 10. ! advective bbl coefficient [s]
705	/
706
707	!!======================================================================
708	!! Tracer (T & S ) namelists
709	!!======================================================================
710	!! nameos equation of state
711	!! namtra_adv advection scheme
712	!! namtra_adv_mle mixed layer eddy param. (Fox-Kemper param.)
713	!! namtra_ldf lateral diffusion scheme
714	!! namtra_dmp T & S newtonian damping
715	!!======================================================================
716	!
717	!-----------------------------------------------------------------------
718	&nameos ! ocean physical parameters
719	!-----------------------------------------------------------------------
720	nn_eos = -1 ! type of equation of state and Brunt-Vaisala frequency
721	! =-1, TEOS-10
722	! = 0, EOS-80
723	! = 1, S-EOS (simplified eos)
724	ln_useCT = .true. ! use of Conservative Temp. ==> surface CT converted in Pot. Temp. in sbcssm
725	! !
726	! ! S-EOS coefficients :
727	! ! rd(T,S,Z)rau0 = -a0(1+.5lambdadT+muZ+nudS)dT+b0dS
728	rn_a0 = 1.6550e-1 ! thermal expension coefficient (nn_eos= 1)
729	rn_b0 = 7.6554e-1 ! saline expension coefficient (nn_eos= 1)
730	rn_lambda1 = 5.9520e-2 ! cabbeling coeff in T^2 (=0 for linear eos)
731	rn_lambda2 = 7.4914e-4 ! cabbeling coeff in S^2 (=0 for linear eos)
732	rn_mu1 = 1.4970e-4 ! thermobaric coeff. in T (=0 for linear eos)
733	rn_mu2 = 1.1090e-5 ! thermobaric coeff. in S (=0 for linear eos)
734	rn_nu = 2.4341e-3 ! cabbeling coeff in T*S (=0 for linear eos)
735	/
736	!-----------------------------------------------------------------------
737	&namtra_adv ! advection scheme for tracer
738	!-----------------------------------------------------------------------
739	ln_traadv_cen2 = .false. ! 2nd order centered scheme
740	ln_traadv_tvd = .true. ! TVD scheme
741	ln_traadv_muscl = .false. ! MUSCL scheme
742	ln_traadv_muscl2 = .false. ! MUSCL2 scheme + cen2 at boundaries
743	ln_traadv_ubs = .false. ! UBS scheme
744	ln_traadv_qck = .false. ! QUICKEST scheme
745	ln_traadv_msc_ups= .false. ! use upstream scheme within muscl
746	ln_traadv_tvd_zts= .false. ! TVD scheme with sub-timestepping of vertical tracer advection
747	/
748	!-----------------------------------------------------------------------
749	&namtra_adv_mle ! mixed layer eddy parametrisation (Fox-Kemper param)
750	!-----------------------------------------------------------------------
751	ln_mle = .true. ! (T) use the Mixed Layer Eddy (MLE) parameterisation
752	rn_ce = 0.06 ! magnitude of the MLE (typical value: 0.06 to 0.08)
753	nn_mle = 1 ! MLE type: =0 standard Fox-Kemper ; =1 new formulation
754	rn_lf = 5.e+3 ! typical scale of mixed layer front (meters) (case rn_mle=0)
755	rn_time = 172800. ! time scale for mixing momentum across the mixed layer (seconds) (case rn_mle=0)
756	rn_lat = 20. ! reference latitude (degrees) of MLE coef. (case rn_mle=1)
757	nn_mld_uv = 0 ! space interpolation of MLD at u- & v-pts (0=min,1=averaged,2=max)
758	nn_conv = 0 ! =1 no MLE in case of convection ; =0 always MLE
759	rn_rho_c_mle = 0.01 ! delta rho criterion used to calculate MLD for FK
760	/
761	!----------------------------------------------------------------------------------
762	&namtra_ldf ! lateral diffusion scheme for tracers
763	!----------------------------------------------------------------------------------
764	! ! Operator type:
765	ln_traldf_lap = .true. ! laplacian operator
766	ln_traldf_bilap = .false. ! bilaplacian operator
767	! ! Direction of action:
768	ln_traldf_level = .false. ! iso-level
769	ln_traldf_hor = .false. ! horizontal (geopotential) (needs "key_ldfslp" when ln_sco=T)
770	ln_traldf_iso = .true. ! iso-neutral (needs "key_ldfslp")
771	! ! Griffies parameters (all need "key_ldfslp")
772	ln_traldf_grif = .false. ! use griffies triads
773	ln_traldf_gdia = .false. ! output griffies eddy velocities
774	ln_triad_iso = .false. ! pure lateral mixing in ML
775	ln_botmix_grif = .false. ! lateral mixing on bottom
776	! ! Coefficients
777	! Eddy-induced (GM) advection always used with Griffies; otherwise needs "key_traldf_eiv"
778	! Value rn_aeiv_0 is ignored unless = 0 with Held-Larichev spatially varying aeiv
779	! (key_traldf_c2d & key_traldf_eiv & key_orca_r2, _r1 or _r05)
780	rn_aeiv_0 = 2000. ! eddy induced velocity coefficient [m2/s]
781	rn_aht_0 = 2000. ! horizontal eddy diffusivity for tracers [m2/s]
782	rn_ahtb_0 = 0. ! background eddy diffusivity for ldf_iso [m2/s]
783	! (normally=0; not used with Griffies)
784	rn_slpmax = 0.01 ! slope limit
785	rn_chsmag = 1. ! multiplicative factor in Smagorinsky diffusivity
786	rn_smsh = 1. ! Smagorinsky diffusivity: = 0 - use only sheer
787	rn_aht_m = 2000. ! upper limit or stability criteria for lateral eddy diffusivity (m2/s)
788	/
789	!-----------------------------------------------------------------------
790	&namtra_dmp ! tracer: T & S newtonian damping
791	!-----------------------------------------------------------------------
792	ln_tradmp = .true. ! add a damping termn (T) or not (F)
793	nn_hdmp = -1 ! horizontal shape =-1, damping in Med and Red Seas only
794	! =XX, damping poleward of XX degrees (XX>0)
795	! + F(distance-to-coast) + Red and Med Seas
796	nn_zdmp = 0 ! vertical shape =0 damping throughout the water column
797	! =1 no damping in the mixing layer (kz criteria)
798	! =2 no damping in the mixed layer (rho crieria)
799	rn_surf = 50. ! surface time scale of damping [days]
800	rn_bot = 360. ! bottom time scale of damping [days]
801	rn_dep = 800. ! depth of transition between rn_surf and rn_bot [meters]
802	nn_file = 0 ! create a damping.coeff NetCDF file (=1) or not (=0)
803	/
804
805	!!======================================================================
806	!! * Dynamics namelists *
807	!!======================================================================
808	!! namdyn_adv formulation of the momentum advection
809	!! namdyn_vor advection scheme
810	!! namdyn_hpg hydrostatic pressure gradient
811	!! namdyn_spg surface pressure gradient (CPP key only)
812	!! namdyn_ldf lateral diffusion scheme
813	!!======================================================================
814	!
815	!-----------------------------------------------------------------------
816	&namdyn_adv ! formulation of the momentum advection
817	!-----------------------------------------------------------------------
818	ln_dynadv_vec = .true. ! vector form (T) or flux form (F)
819	ln_dynadv_cen2= .false. ! flux form - 2nd order centered scheme
820	ln_dynadv_ubs = .false. ! flux form - 3rd order UBS scheme
821	ln_dynzad_zts = .false. ! Use (T) sub timestepping for vertical momentum advection
822	/
823	!-----------------------------------------------------------------------
824	&nam_vvl ! vertical coordinate options
825	!-----------------------------------------------------------------------
826	ln_vvl_zstar = .true. ! zstar vertical coordinate
827	ln_vvl_ztilde = .false. ! ztilde vertical coordinate: only high frequency variations
828	ln_vvl_layer = .false. ! full layer vertical coordinate
829	ln_vvl_ztilde_as_zstar = .false. ! ztilde vertical coordinate emulating zstar
830	ln_vvl_zstar_at_eqtor = .false. ! ztilde near the equator
831	rn_ahe3 = 0.0e0 ! thickness diffusion coefficient
832	rn_rst_e3t = 30.e0 ! ztilde to zstar restoration timescale [days]
833	rn_lf_cutoff = 5.0e0 ! cutoff frequency for low-pass filter [days]
834	rn_zdef_max = 0.9e0 ! maximum fractional e3t deformation
835	ln_vvl_dbg = .true. ! debug prints (T/F)
836	/
837	!-----------------------------------------------------------------------
838	&namdyn_vor ! option of physics/algorithm (not control by CPP keys)
839	!-----------------------------------------------------------------------
840	ln_dynvor_ene = .false. ! enstrophy conserving scheme
841	ln_dynvor_ens = .false. ! energy conserving scheme
842	ln_dynvor_mix = .false. ! mixed scheme
843	ln_dynvor_een = .true. ! energy & enstrophy scheme
844	ln_dynvor_een_old = .false. ! energy & enstrophy scheme - original formulation
845	/
846	!-----------------------------------------------------------------------
847	&namdyn_hpg ! Hydrostatic pressure gradient option
848	!-----------------------------------------------------------------------
849	ln_hpg_zco = .false. ! z-coordinate - full steps
850	ln_hpg_zps = .true. ! z-coordinate - partial steps (interpolation)
851	ln_hpg_sco = .false. ! s-coordinate (standard jacobian formulation)
852	ln_hpg_djc = .false. ! s-coordinate (Density Jacobian with Cubic polynomial)
853	ln_hpg_prj = .false. ! s-coordinate (Pressure Jacobian scheme)
854	ln_dynhpg_imp = .false. ! time stepping: semi-implicit time scheme (T)
855	! centered time scheme (F)
856	/
857	!-----------------------------------------------------------------------
858	!namdyn_spg ! surface pressure gradient (CPP key only)
859	!-----------------------------------------------------------------------
860	! ! explicit free surface ("key_dynspg_exp")
861	! ! filtered free surface ("key_dynspg_flt")
862	! ! split-explicit free surface ("key_dynspg_ts")
863
864	!-----------------------------------------------------------------------
865	&namdyn_ldf ! lateral diffusion on momentum
866	!-----------------------------------------------------------------------
867	! ! Type of the operator :
868	ln_dynldf_lap = .true. ! laplacian operator
869	ln_dynldf_bilap = .false. ! bilaplacian operator
870	! ! Direction of action :
871	ln_dynldf_level = .false. ! iso-level
872	ln_dynldf_hor = .true. ! horizontal (geopotential) (require "key_ldfslp" in s-coord.)
873	ln_dynldf_iso = .false. ! iso-neutral (require "key_ldfslp")
874	! ! Coefficient
875	rn_ahm_0_lap = 40000. ! horizontal laplacian eddy viscosity [m2/s]
876	rn_ahmb_0 = 0. ! background eddy viscosity for ldf_iso [m2/s]
877	rn_ahm_0_blp = 0. ! horizontal bilaplacian eddy viscosity [m4/s]
878	rn_cmsmag_1 = 3. ! constant in laplacian Smagorinsky viscosity
879	rn_cmsmag_2 = 3 ! constant in bilaplacian Smagorinsky viscosity
880	rn_cmsh = 1. ! 1 or 0 , if 0 -use only shear for Smagorinsky viscosity
881	rn_ahm_m_blp = -1.e12 ! upper limit for bilap abs(ahm) < min( dx^4/128rdt, rn_ahm_m_blp)
882	rn_ahm_m_lap = 40000. ! upper limit for lap ahm < min(dx^2/16rdt, rn_ahm_m_lap)
883	/
884
885	!!======================================================================
886	!! Tracers & Dynamics vertical physics namelists
887	!!======================================================================
888	!! namzdf vertical physics
889	!! namzdf_ric richardson number dependent vertical mixing ("key_zdfric")
890	!! namzdf_tke TKE dependent vertical mixing ("key_zdftke")
891	!! namzdf_kpp KPP dependent vertical mixing ("key_zdfkpp")
892	!! namzdf_ddm double diffusive mixing parameterization ("key_zdfddm")
893	!! namzdf_tmx tidal mixing parameterization ("key_zdftmx")
894	!!======================================================================
895	!
896	!-----------------------------------------------------------------------
897	&namzdf ! vertical physics
898	!-----------------------------------------------------------------------
899	rn_avm0 = 1.2e-4 ! vertical eddy viscosity [m2/s] (background Kz if not "key_zdfcst")
900	rn_avt0 = 1.2e-5 ! vertical eddy diffusivity [m2/s] (background Kz if not "key_zdfcst")
901	nn_avb = 0 ! profile for background avt & avm (=1) or not (=0)
902	nn_havtb = 0 ! horizontal shape for avtb (=1) or not (=0)
903	ln_zdfevd = .true. ! enhanced vertical diffusion (evd) (T) or not (F)
904	nn_evdm = 0 ! evd apply on tracer (=0) or on tracer and momentum (=1)
905	rn_avevd = 100. ! evd mixing coefficient [m2/s]
906	ln_zdfnpc = .false. ! Non-Penetrative Convective algorithm (T) or not (F)
907	nn_npc = 1 ! frequency of application of npc
908	nn_npcp = 365 ! npc control print frequency
909	ln_zdfexp = .false. ! time-stepping: split-explicit (T) or implicit (F) time stepping
910	nn_zdfexp = 3 ! number of sub-timestep for ln_zdfexp=T
911	/
912	!-----------------------------------------------------------------------
913	&namzdf_ric ! richardson number dependent vertical diffusion ("key_zdfric" )
914	!-----------------------------------------------------------------------
915	rn_avmri = 100.e-4 ! maximum value of the vertical viscosity
916	rn_alp = 5. ! coefficient of the parameterization
917	nn_ric = 2 ! coefficient of the parameterization
918	rn_ekmfc = 0.7 ! Factor in the Ekman depth Equation
919	rn_mldmin = 1.0 ! minimum allowable mixed-layer depth estimate (m)
920	rn_mldmax =1000.0 ! maximum allowable mixed-layer depth estimate (m)
921	rn_wtmix = 10.0 ! vertical eddy viscosity coeff [m2/s] in the mixed-layer
922	rn_wvmix = 10.0 ! vertical eddy diffusion coeff [m2/s] in the mixed-layer
923	ln_mldw = .true. ! Flag to use or not the mized layer depth param.
924	/
925	!-----------------------------------------------------------------------
926	&namzdf_tke ! turbulent eddy kinetic dependent vertical diffusion ("key_zdftke")
927	!-----------------------------------------------------------------------
928	rn_ediff = 0.1 ! coef. for vertical eddy coef. (avt=rn_ediffmxlsqrt(e) )
929	rn_ediss = 0.7 ! coef. of the Kolmogoroff dissipation
930	rn_ebb = 67.83 ! coef. of the surface input of tke (=67.83 suggested when ln_mxl0=T)
931	rn_emin = 1.e-6 ! minimum value of tke [m2/s2]
932	rn_emin0 = 1.e-4 ! surface minimum value of tke [m2/s2]
933	rn_bshear = 1.e-20 ! background shear (>0) currently a numerical threshold (do not change it)
934	nn_mxl = 2 ! mixing length: = 0 bounded by the distance to surface and bottom
935	! = 1 bounded by the local vertical scale factor
936	! = 2 first vertical derivative of mixing length bounded by 1
937	! = 3 as =2 with distinct disspipative an mixing length scale
938	nn_pdl = 1 ! Prandtl number function of richarson number (=1, avt=pdl(Ri)*avm) or not (=0, avt=avm)
939	ln_mxl0 = .true. ! surface mixing length scale = F(wind stress) (T) or not (F)
940	rn_mxl0 = 0.04 ! surface buoyancy lenght scale minimum value
941	ln_lc = .true. ! Langmuir cell parameterisation (Axell 2002)
942	rn_lc = 0.15 ! coef. associated to Langmuir cells
943	nn_etau = 1 ! penetration of tke below the mixed layer (ML) due to internal & intertial waves
944	! = 0 no penetration
945	! = 1 add a tke source below the ML
946	! = 2 add a tke source just at the base of the ML
947	! = 3 as = 1 applied on HF part of the stress ("key_coupled")
948	rn_efr = 0.05 ! fraction of surface tke value which penetrates below the ML (nn_etau=1 or 2)
949	nn_htau = 1 ! type of exponential decrease of tke penetration below the ML
950	! = 0 constant 10 m length scale
951	! = 1 0.5m at the equator to 30m poleward of 40 degrees
952	/
953	!------------------------------------------------------------------------
954	&namzdf_kpp ! K-Profile Parameterization dependent vertical mixing ("key_zdfkpp", and optionally:
955	!------------------------------------------------------------------------ "key_kppcustom" or "key_kpplktb")
956	ln_kpprimix = .true. ! shear instability mixing
957	rn_difmiw = 1.0e-04 ! constant internal wave viscosity [m2/s]
958	rn_difsiw = 0.1e-04 ! constant internal wave diffusivity [m2/s]
959	rn_riinfty = 0.8 ! local Richardson Number limit for shear instability
960	rn_difri = 0.0050 ! maximum shear mixing at Rig = 0 [m2/s]
961	rn_bvsqcon = -0.01e-07 ! Brunt-Vaisala squared for maximum convection [1/s2]
962	rn_difcon = 1. ! maximum mixing in interior convection [m2/s]
963	nn_avb = 0 ! horizontal averaged (=1) or not (=0) on avt and amv
964	nn_ave = 1 ! constant (=0) or profile (=1) background on avt
965	/
966	!-----------------------------------------------------------------------
967	&namzdf_gls ! GLS vertical diffusion ("key_zdfgls")
968	!-----------------------------------------------------------------------
969	rn_emin = 1.e-6 ! minimum value of e [m2/s2]
970	rn_epsmin = 1.e-12 ! minimum value of eps [m2/s3]
971	ln_length_lim = .true. ! limit on the dissipation rate under stable stratification (Galperin et al., 1988)
972	rn_clim_galp = 0.53 ! galperin limit
973	ln_crban = .true. ! Use Craig & Banner (1994) surface wave mixing parametrisation
974	ln_sigpsi = .true. ! Activate or not Burchard 2001 mods on psi schmidt number in the wb case
975	rn_crban = 100. ! Craig and Banner 1994 constant for wb tke flux
976	rn_charn = 70000. ! Charnock constant for wb induced roughness length
977	nn_tkebc_surf = 1 ! surface tke condition (0/1/2=Dir/Neum/Dir Mellor-Blumberg)
978	nn_tkebc_bot = 1 ! bottom tke condition (0/1=Dir/Neum)
979	nn_psibc_surf = 1 ! surface psi condition (0/1/2=Dir/Neum/Dir Mellor-Blumberg)
980	nn_psibc_bot = 1 ! bottom psi condition (0/1=Dir/Neum)
981	nn_stab_func = 2 ! stability function (0=Galp, 1= KC94, 2=CanutoA, 3=CanutoB)
982	nn_clos = 1 ! predefined closure type (0=MY82, 1=k-eps, 2=k-w, 3=Gen)
983	/
984	!-----------------------------------------------------------------------
985	&namzdf_ddm ! double diffusive mixing parameterization ("key_zdfddm")
986	!-----------------------------------------------------------------------
987	rn_avts = 1.e-4 ! maximum avs (vertical mixing on salinity)
988	rn_hsbfr = 1.6 ! heat/salt buoyancy flux ratio
989	/
990	!-----------------------------------------------------------------------
991	&namzdf_tmx ! tidal mixing parameterization ("key_zdftmx")
992	!-----------------------------------------------------------------------
993	rn_htmx = 500. ! vertical decay scale for turbulence (meters)
994	rn_n2min = 1.e-8 ! threshold of the Brunt-Vaisala frequency (s-1)
995	rn_tfe = 0.333 ! tidal dissipation efficiency
996	rn_me = 0.2 ! mixing efficiency
997	ln_tmx_itf = .true. ! ITF specific parameterisation
998	rn_tfe_itf = 1. ! ITF tidal dissipation efficiency
999	/
1000
1001	!!======================================================================
1002	!! * Miscellaneous namelists *
1003	!!======================================================================
1004	!! namsol elliptic solver / island / free surface
1005	!! nammpp Massively Parallel Processing ("key_mpp_mpi)
1006	!! namctl Control prints & Benchmark
1007	!! namc1d 1D configuration options ("key_c1d")
1008	!! namc1d_uvd data: U & V currents ("key_c1d")
1009	!! namc1d_dyndmp U & V newtonian damping ("key_c1d")
1010	!!======================================================================
1011	!
1012	!-----------------------------------------------------------------------
1013	&namsol ! elliptic solver / island / free surface
1014	!-----------------------------------------------------------------------
1015	nn_solv = 1 ! elliptic solver: =1 preconditioned conjugate gradient (pcg)
1016	! =2 successive-over-relaxation (sor)
1017	nn_sol_arp = 0 ! absolute/relative (0/1) precision convergence test
1018	rn_eps = 1.e-6 ! absolute precision of the solver
1019	nn_nmin = 300 ! minimum of iterations for the SOR solver
1020	nn_nmax = 800 ! maximum of iterations for the SOR solver
1021	nn_nmod = 10 ! frequency of test for the SOR solver
1022	rn_resmax = 1.e-10 ! absolute precision for the SOR solver
1023	rn_sor = 1.92 ! optimal coefficient for SOR solver (to be adjusted with the domain)
1024	/
1025	!-----------------------------------------------------------------------
1026	&nammpp ! Massively Parallel Processing ("key_mpp_mpi)
1027	!-----------------------------------------------------------------------
1028	cn_mpi_send = 'I' ! mpi send/recieve type ='S', 'B', or 'I' for standard send,
1029	! buffer blocking send or immediate non-blocking sends, resp.
1030	nn_buffer = 0 ! size in bytes of exported buffer ('B' case), 0 no exportation
1031	ln_nnogather= .false. ! activate code to avoid mpi_allgather use at the northfold
1032	jpni = 0 ! jpni number of processors following i (set automatically if < 1)
1033	jpnj = 0 ! jpnj number of processors following j (set automatically if < 1)
1034	jpnij = 0 ! jpnij number of local domains (set automatically if < 1)
1035	/
1036	!-----------------------------------------------------------------------
1037	&namctl ! Control prints & Benchmark
1038	!-----------------------------------------------------------------------
1039	ln_ctl = .false. ! trends control print (expensive!)
1040	nn_print = 0 ! level of print (0 no extra print)
1041	nn_ictls = 0 ! start i indice of control sum (use to compare mono versus
1042	nn_ictle = 0 ! end i indice of control sum multi processor runs
1043	nn_jctls = 0 ! start j indice of control over a subdomain)
1044	nn_jctle = 0 ! end j indice of control
1045	nn_isplt = 1 ! number of processors in i-direction
1046	nn_jsplt = 1 ! number of processors in j-direction
1047	nn_bench = 0 ! Bench mode (1/0): CAUTION use zero except for bench
1048	! (no physical validity of the results)
1049	nn_timing = 0 ! timing by routine activated (=1) creates timing.output file, or not (=0)
1050	/
1051	!-----------------------------------------------------------------------
1052	&namc1d_uvd ! data: U & V currents ("key_c1d")
1053	!-----------------------------------------------------------------------
1054	! ! file name ! frequency (hours) ! variable ! time interp. ! clim ! 'yearly'/ ! weights ! rotation ! land/sea mask !
1055	! ! ! (if <0 months) ! name ! (logical) ! (T/F) ! 'monthly' ! filename ! pairing ! filename !
1056	sn_ucur = 'ucurrent' , -1 ,'u_current', .false. , .true. , 'monthly' , '' , 'Ume' , ''
1057	sn_vcur = 'vcurrent' , -1 ,'v_current', .false. , .true. , 'monthly' , '' , 'Vme' , ''
1058	!
1059	cn_dir = './' ! root directory for the location of the files
1060	ln_uvd_init = .false. ! Initialisation of ocean U & V with U & V input data (T) or not (F)
1061	ln_uvd_dyndmp = .false. ! damping of ocean U & V toward U & V input data (T) or not (F)
1062	/
1063	!-----------------------------------------------------------------------
1064	&namc1d_dyndmp ! U & V newtonian damping ("key_c1d")
1065	!-----------------------------------------------------------------------
1066	ln_dyndmp = .false. ! add a damping term (T) or not (F)
1067	/
1068
1069	!!======================================================================
1070	!! * Diagnostics namelists *
1071	!!======================================================================
1072	!! namnc4 netcdf4 chunking and compression settings ("key_netcdf4")
1073	!! namtrd dynamics and/or tracer trends
1074	!! namflo float parameters ("key_float")
1075	!! namptr Poleward Transport Diagnostics
1076	!! namhsb Heat and salt budgets
1077	!!======================================================================
1078	!
1079	!-----------------------------------------------------------------------
1080	&namnc4 ! netcdf4 chunking and compression settings ("key_netcdf4")
1081	!-----------------------------------------------------------------------
1082	nn_nchunks_i= 4 ! number of chunks in i-dimension
1083	nn_nchunks_j= 4 ! number of chunks in j-dimension
1084	nn_nchunks_k= 31 ! number of chunks in k-dimension
1085	! setting nn_nchunks_k = jpk will give a chunk size of 1 in the vertical which
1086	! is optimal for postprocessing which works exclusively with horizontal slabs
1087	ln_nc4zip = .true. ! (T) use netcdf4 chunking and compression
1088	! (F) ignore chunking information and produce netcdf3-compatible files
1089	/
1090	!-----------------------------------------------------------------------
1091	&namtrd ! diagnostics on dynamics and/or tracer trends
1092	! ! and/or mixed-layer trends and/or barotropic vorticity
1093	!-----------------------------------------------------------------------
1094	ln_glo_trd = .false. ! (T) global domain averaged diag for T, T^2, KE, and PE
1095	ln_dyn_trd = .false. ! (T) 3D momentum trend output
1096	ln_dyn_mxl = .FALSE. ! (T) 2D momentum trends averaged over the mixed layer (not coded yet)
1097	ln_vor_trd = .FALSE. ! (T) 2D barotropic vorticity trends (not coded yet)
1098	ln_KE_trd = .false. ! (T) 3D Kinetic Energy trends
1099	ln_PE_trd = .false. ! (T) 3D Potential Energy trends
1100	ln_tra_trd = .FALSE. ! (T) 3D tracer trend output
1101	ln_tra_mxl = .false. ! (T) 2D tracer trends averaged over the mixed layer (not coded yet)
1102	nn_trd = 365 ! print frequency (ln_glo_trd=T) (unit=time step)
1103	/
1104	!!gm nn_ctls = 0 ! control surface type in mixed-layer trends (0,1 or n<jpk)
1105	!!gm rn_ucf = 1. ! unit conversion factor (=1 -> /seconds ; =86400. -> /day)
1106	!!gm cn_trdrst_in = "restart_mld" ! suffix of ocean restart name (input)
1107	!!gm cn_trdrst_out = "restart_mld" ! suffix of ocean restart name (output)
1108	!!gm ln_trdmld_restart = .false. ! restart for ML diagnostics
1109	!!gm ln_trdmld_instant = .false. ! flag to diagnose trends of instantantaneous or mean ML T/S
1110	!!gm
1111	!-----------------------------------------------------------------------
1112	&namflo ! float parameters ("key_float")
1113	!-----------------------------------------------------------------------
1114	jpnfl = 1 ! total number of floats during the run
1115	jpnnewflo = 0 ! number of floats for the restart
1116	ln_rstflo = .false. ! float restart (T) or not (F)
1117	nn_writefl = 75 ! frequency of writing in float output file
1118	nn_stockfl = 5475 ! frequency of creation of the float restart file
1119	ln_argo = .false. ! Argo type floats (stay at the surface each 10 days)
1120	ln_flork4 = .false. ! trajectories computed with a 4th order Runge-Kutta (T)
1121	! or computed with Blanke' scheme (F)
1122	ln_ariane = .true. ! Input with Ariane tool convention(T)
1123	ln_flo_ascii = .true. ! Output with Ariane tool netcdf convention(F) or ascii file (T)
1124	/
1125	!-----------------------------------------------------------------------
1126	&namptr ! Poleward Transport Diagnostic
1127	!-----------------------------------------------------------------------
1128	ln_diaptr = .false. ! Poleward heat and salt transport (T) or not (F)
1129	ln_diaznl = .true. ! Add zonal means and meridional stream functions
1130	ln_subbas = .true. ! Atlantic/Pacific/Indian basins computation (T) or not
1131	! (orca configuration only, need input basins mask file named "subbasins.nc"
1132	ln_ptrcomp = .true. ! Add decomposition : overturning
1133	nn_fptr = 1 ! Frequency of ptr computation [time step]
1134	nn_fwri = 15 ! Frequency of ptr outputs [time step]
1135	/
1136	!-----------------------------------------------------------------------
1137	&namhsb ! Heat and salt budgets
1138	!-----------------------------------------------------------------------
1139	ln_diahsb = .false. ! check the heat and salt budgets (T) or not (F)
1140	/
1141	!-----------------------------------------------------------------------
1142	&nam_diaharm ! Harmonic analysis of tidal constituents ('key_diaharm')
1143	!-----------------------------------------------------------------------
1144	nit000_han = 1 ! First time step used for harmonic analysis
1145	nitend_han = 75 ! Last time step used for harmonic analysis
1146	nstep_han = 15 ! Time step frequency for harmonic analysis
1147	tname(1) = 'M2' ! Name of tidal constituents
1148	tname(2) = 'K1'
1149	/
1150	!-----------------------------------------------------------------------
1151	&namdct ! transports through sections
1152	!-----------------------------------------------------------------------
1153	nn_dct = 15 ! time step frequency for transports computing
1154	nn_dctwri = 15 ! time step frequency for transports writing
1155	nn_secdebug = 112 ! 0 : no section to debug
1156	! -1 : debug all section
1157	! 0 < n : debug section number n
1158	/
1159
1160	!!======================================================================
1161	!! * Observation & Assimilation namelists *
1162	!!======================================================================
1163	!! namobs observation and model comparison ('key_diaobs')
1164	!! nam_asminc assimilation increments ('key_asminc')
1165	!!======================================================================
1166	!
1167	!-----------------------------------------------------------------------
1168	&namobs ! observation usage switch ('key_diaobs')
1169	!-----------------------------------------------------------------------
1170	ln_t3d = .false. ! Logical switch for T profile observations
1171	ln_s3d = .false. ! Logical switch for S profile observations
1172	ln_ena = .false. ! Logical switch for ENACT insitu data set
1173	! ! ln_cor Logical switch for Coriolis insitu data set
1174	ln_profb = .false. ! Logical switch for feedback insitu data set
1175	ln_sla = .false. ! Logical switch for SLA observations
1176
1177	ln_sladt = .false. ! Logical switch for AVISO SLA data
1178
1179	ln_slafb = .false. ! Logical switch for feedback SLA data
1180	! ln_ssh Logical switch for SSH observations
1181
1182	ln_sst = .false. ! Logical switch for SST observations
1183	ln_reysst = .false. ! ln_reysst Logical switch for Reynolds observations
1184	ln_ghrsst = .false. ! ln_ghrsst Logical switch for GHRSST observations
1185
1186	ln_sstfb = .false. ! Logical switch for feedback SST data
1187	! ln_sss Logical switch for SSS observations
1188	ln_seaice = .false. ! Logical switch for Sea Ice observations
1189	! ln_vel3d Logical switch for velocity observations
1190	! ln_velavcur Logical switch for velocity daily av. cur.
1191	! ln_velhrcur Logical switch for velocity high freq. cur.
1192	! ln_velavadcp Logical switch for velocity daily av. ADCP
1193	! ln_velhradcp Logical switch for velocity high freq. ADCP
1194	! ln_velfb Logical switch for feedback velocity data
1195	! ln_grid_global Global distribtion of observations
1196	! ln_grid_search_lookup Logical switch for obs grid search w/lookup table
1197	! grid_search_file Grid search lookup file header
1198	! enactfiles ENACT input observation file names
1199	! coriofiles Coriolis input observation file name
1200	! ! profbfiles: Profile feedback input observation file name
1201	profbfiles = 'profiles_01.nc'
1202	! ln_profb_enatim Enact feedback input time setting switch
1203	! slafilesact Active SLA input observation file name
1204	! slafilespas Passive SLA input observation file name
1205	! ! slafbfiles: Feedback SLA input observation file name
1206	slafbfiles = 'sla_01.nc'
1207	! sstfiles GHRSST input observation file name
1208	! ! sstfbfiles: Feedback SST input observation file name
1209	sstfbfiles = 'sst_01.nc'
1210	! seaicefiles Sea Ice input observation file names
1211	seaicefiles = 'seaice_01.nc'
1212	! velavcurfiles Vel. cur. daily av. input file name
1213	! velhvcurfiles Vel. cur. high freq. input file name
1214	! velavadcpfiles Vel. ADCP daily av. input file name
1215	! velhvadcpfiles Vel. ADCP high freq. input file name
1216	! velfbfiles Vel. feedback input observation file name
1217	! dobsini Initial date in window YYYYMMDD.HHMMSS
1218	! dobsend Final date in window YYYYMMDD.HHMMSS
1219	! n1dint Type of vertical interpolation method
1220	! n2dint Type of horizontal interpolation method
1221	! ln_nea Rejection of observations near land switch
1222	nmsshc = 0 ! MSSH correction scheme
1223	! mdtcorr MDT correction
1224	! mdtcutoff MDT cutoff for computed correction
1225	ln_altbias = .false. ! Logical switch for alt bias
1226	ln_ignmis = .true. ! Logical switch for ignoring missing files
1227	! endailyavtypes ENACT daily average types
1228	ln_grid_global = .true.
1229	ln_grid_search_lookup = .false.
1230	/
1231	!-----------------------------------------------------------------------
1232	&nam_asminc ! assimilation increments ('key_asminc')
1233	!-----------------------------------------------------------------------
1234	ln_bkgwri = .false. ! Logical switch for writing out background state
1235	ln_trainc = .false. ! Logical switch for applying tracer increments
1236	ln_dyninc = .false. ! Logical switch for applying velocity increments
1237	ln_sshinc = .false. ! Logical switch for applying SSH increments
1238	ln_asmdin = .false. ! Logical switch for Direct Initialization (DI)
1239	ln_asmiau = .false. ! Logical switch for Incremental Analysis Updating (IAU)
1240	nitbkg = 0 ! Timestep of background in [0,nitend-nit000-1]
1241	nitdin = 0 ! Timestep of background for DI in [0,nitend-nit000-1]
1242	nitiaustr = 1 ! Timestep of start of IAU interval in [0,nitend-nit000-1]
1243	nitiaufin = 15 ! Timestep of end of IAU interval in [0,nitend-nit000-1]
1244	niaufn = 0 ! Type of IAU weighting function
1245	ln_salfix = .false. ! Logical switch for ensuring that the sa > salfixmin
1246	salfixmin = -9999 ! Minimum salinity after applying the increments
1247	nn_divdmp = 0 ! Number of iterations of divergence damping operator
1248	/
1249	!-----------------------------------------------------------------------
1250	&namsbc_wave ! External fields from wave model
1251	!-----------------------------------------------------------------------
1252	! ! file name ! frequency (hours) ! variable ! time interp. ! clim ! 'yearly'/ ! weights ! rotation ! land/sea mask !
1253	! ! ! (if <0 months) ! name ! (logical) ! (T/F) ! 'monthly' ! filename ! pairing ! filename !
1254	sn_cdg = 'cdg_wave' , 1 , 'drag_coeff' , .true. , .false. , 'daily' , '' , '' , ''
1255	sn_usd = 'sdw_wave' , 1 , 'u_sd2d' , .true. , .false. , 'daily' , '' , '' , ''
1256	sn_vsd = 'sdw_wave' , 1 , 'v_sd2d' , .true. , .false. , 'daily' , '' , '' , ''
1257	sn_wn = 'sdw_wave' , 1 , 'wave_num' , .true. , .false. , 'daily' , '' , '' , ''
1258	!
1259	cn_dir_cdg = './' ! root directory for the location of drag coefficient files
1260	/
1261	!-----------------------------------------------------------------------
1262	&namdyn_nept ! Neptune effect (simplified: lateral and vertical diffusions removed)
1263	!-----------------------------------------------------------------------
1264	! Suggested lengthscale values are those of Eby & Holloway (1994) for a coarse model
1265	ln_neptsimp = .false. ! yes/no use simplified neptune
1266
1267	ln_smooth_neptvel = .false. ! yes/no smooth zunep, zvnep
1268	rn_tslse = 1.2e4 ! value of lengthscale L at the equator
1269	rn_tslsp = 3.0e3 ! value of lengthscale L at the pole
1270	! Specify whether to ramp down the Neptune velocity in shallow
1271	! water, and if so the depth range controlling such ramping down
1272	ln_neptramp = .true. ! ramp down Neptune velocity in shallow water
1273	rn_htrmin = 100.0 ! min. depth of transition range
1274	rn_htrmax = 200.0 ! max. depth of transition range
1275	/

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