source: trunk/LMDZ.MARS/deftank/run.def.32x24x32.GCM5 @ 2942

Last change on this file since 2942 was 2637, checked in by abierjon, 3 years ago

Mars GCM:
Update .def* files in LMDZ.MARS/deftank/
*.def.GCM6 files are bound to change later but are ready to use.

AB

File size: 2.6 KB
Line 
1#
2#-----------------------------------------------------------------------
3#GCM run control parameters:                                         
4#---------------------------                                     
5
6# planet type
7   planet_type=mars
8
9# Number of days to run model for                                     
10     nday=9999
11
12# Number of dynamical steps per day (must be a multiple of iperiod)
13 day_step = 480
14
15# Apply a Matsuno step every iperiod dynamical step
16  iperiod=5
17
18# Control output information in the dynamics every iconser dynamical steps
19  iconser=120
20
21# Apply dissipation every idissip dynamical steps
22  idissip=1
23
24# dissipation operator to use (star or non-star)
25 lstardis=.true.
26
27# use hybrid vertical coordinate (else will use sigma levels)
28 hybrid=.true.
29
30# iterate lateral dissipation operator gradiv nitergdiv times
31nitergdiv=1
32
33# iterate lateral dissipation operator nxgradrot nitergrot times         
34nitergrot=2
35
36# iterate lateral dissipation operator divgrad niterh times         
37   niterh=2
38
39# time scale (s) for shortest wavelengths for u,v (gradiv)
40 tetagdiv= 3000.
41
42# time scale (s) for shortest wavelengths for u,v (nxgradrot)
43 tetagrot=9000.
44
45# time scale (s) for shortest wavelengths for h (divgrad)
46 tetatemp=9000.
47
48# coefficient for gamdissip                                           
49  coefdis=0.
50
51# time marching scheme (Matsuno if purmats is true, else Matsuno-Leapfrog)
52  purmats=.false.
53
54# run with (true) or without (false) physics
55   physic=.true.
56
57# call physics every iphysiq dynamical steps
58  iphysiq=10
59
60# Use a regular grid
61  grireg=.true.
62
63# Output in diagfi file every ecritphy dynamical steps
64 ecritphy=120
65
66# longitude (degrees) of zoom center
67   clon=63.
68
69# latitude (degrees) of zoom center
70   clat=0.
71
72# enhancement factor of zoom, along longitudes
73  grossismx=1.
74
75# enhancement factor of zoom, along latitudes                     
76 grossismy=1.
77
78#  Use an hyperbolic function f(y) if .true., else use a sine     
79  fxyhypb=.false.
80
81# extention along longitudes of zoom region (fraction of global domain)
82   dzoomx= 0.
83
84# extention along latitudes of zoom region (fraction of global domain)
85   dzoomy=0.
86
87# zoom stiffness along longitudes
88    taux=2.
89
90# zoom stiffness along latitudes
91    tauy=2.
92
93#  Fonction  f(y) as y = Sin(latitude) if = .true. ,  else  y = latitude
94  ysinus= .false.
95
96# Use a sponge layer
97  callsponge  = .true.
98 
99# Sponge layer extends over topmost nsponge layers
100  nsponge = 3
101
102# Sponge:  mode0(u=v=0), mode1(u=umoy,v=0), mode2(u=umoy,v=vmoy)
103  mode_sponge= 2
104
105# Sponge layer time scale (s):  tetasponge
106  tetasponge = 30000
107
108# some definitions for the physics, in file 'callphys.def'
109INCLUDEDEF=callphys.def
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