[ ÆüËܸì|English ] [ GFD Dennou Club / DCMODEL Project ]
- Target
- Models
DCPOM project designs and develops ocean general circulation models and sea ice models in order to explore climates realzied on exoplanets.
- Ocean component
- Dynamical core: hydrostatic Boussinesq equations
- Parameterizations for sub-grid scale processes
- Meso-scale eddy mixing
- isopycnal diffusion scheme (Redi, 1982)
- GM scheme based on skew flux (Gent and McWilliams, 1990; Griffies et al, 1998)
- Convective mixing
- convective adjustment scheme (Marotzke, 1991)
- Numerical method
- horizontal discretization: a spectral Eulerian method based spherical harmonics
- vertical discretization: a finite volume method
- time discretization
- a LF-AM3 scheme (Shchepetkin and McWilliams, 2005) for advective process
- a leapfrog scheme for fast wave process and vertical diffusive process, a backward Euler scheme for lateral diffusive process
- Sea ice component
- Thermodynamic 3 layers sea ice model based on a formulation by Winton(2000).
- Note
- This ocean-sea ice model can couple to an atmospheric general circulation model DCPAM.
For details, please see DCPCM project.
- Coast lines can not be considered in the model
- Global shallow water model with a finite volume method (globalSWM-FVM)
- The grid sysyem is triangle - hexagonal grid, and the governing equations are discretized with TRiSK proposed by Ringler et al. (2010).
- Global shallow water model with a discontinuous Galerkin method (globalSWM-DG)
- The model mesh is spherical triangle mesh, and the governing equation are discretized with a DG method proposed by Lauter et al. (2008).
dcmodel Development Group / GFD Dennou Staff 
Last Updated: unknown, Since: unknown