This is a list of ocean circulation models, as used in physical oceanography. Ocean circulation models can also be used to study chemical oceanography, biological oceanography, geological oceanography, and climate science.
Acronym | Full name |
---|---|
ADCIRC | ADvanced CIRCulation model |
COCO | CCSR (Center for Climate System Research) Ocean Component Model |
COHERENS | COupled Hydrodynamical Ecological model for REgioNal Shelf seas |
FVCOM | Finite Volume Community Ocean Model |
FESOM | AWI Finite-Element/volumE Sea ice-Ocean Model |
FRAM | Fine Resolution Antarctic Ocean Model |
HOPE | The Hamburg Ocean Primitive Equation General Circulation Model [1] |
HYCOM | HYbrid Coordinate Ocean Model |
LSG | The Hamburg Large Scale Geostrophic Ocean General Circulation Model [2] |
MICOM | Miami Isopycnic Coordinate Ocean Model |
MITgcm | M.I.T. General Circulation Model |
MOHID | MOdelo HIDrodinâmico |
MOM | GFDL Modular Ocean Model |
MOMA | MOM for Array Processors |
OCCAM | Ocean Circulation and Climate Advanced Ocean Model |
NEMO | Nucleus for European Modelling of the Ocean |
OPYC | The Ocean IsoPYCnal General Circulation Model [3][4] |
POM | Princeton Ocean Model |
POP | The Parallel Ocean Program |
ROMS | The Regional Ocean Modeling System |
Veros | Versatile Ocean Simulator in Pure Python[5] |
Integrated ocean modeling systems[further explanation needed]
editIntegrated ocean modeling systems use multiple coupled models. This coupling allows researchers to understand processes that happen among multiple systems that are usually modeled independently, such as the ocean, atmosphere, waves, and sediments. Integrated ocean modeling systems is helpful for specific regions: for example, the ESPreSSO model is used to study the Mid-Atlantic Bight region. Integrated ocean modeling systems often use data from buoys and weather stations for atmospheric forcing and boundary conditions. Two examples of integrated ocean modeling systems are:
References
edit- ^ Wolff J-O, Maier-Reimer E, Legutke S (1997) The Hamburg Ocean Primitive Equation Model HOPE. DKRZ report 13, Hamburg, Germany, doi:10.2312/WDCC/DKRZ_Report_No13.
- ^ Maier-Reimer E, Mikolajewicz U (1992) The Hamburg Large Scale Geostrophic Ocean General Circulation Model (Cycle 1). DKRZ report 2, Hamburg, Germany, doi:10.2312/WDCC/DKRZ_Report_No02.
- ^ Oberhuber JM (1993) Simulation of the Atlantic circulation with a coupled sea ice-mixed layer-isopycnal general circulation model, part I: model description. Journal of Physical Oceanography, 23, 808–829 doi:10.1175/1520-0485(1993)023<0808:SOTACW>2.0.CO;2.
- ^ Oberhuber JM (1993) The OPYC Ocean General Circulation Model. DKRZ report 7, Hamburg, Germany, doi:10.2312/WDCC/DKRZ_Report_No07.
- ^ "Versatile Ocean Simulator in Pure Python — documentation". veros.readthedocs.io. Retrieved 2021-09-10.
- ^ Warner, John C.; Armstrong, Brandy; He, Ruoying; Zambon, Joseph B. (2010). "Development of a Coupled Ocean–Atmosphere–Wave–Sediment Transport (COAWST) Modeling System". Ocean Modelling. 35 (3): 230–244. Bibcode:2010OcMod..35..230W. doi:10.1016/j.ocemod.2010.07.010. hdl:1912/4099. ISSN 1463-5003.
- ^ "COAWST". coawstmodel-trac.sourcerepo.com. Archived from the original on 2019-02-09. Retrieved 2019-02-08.
- ^ Wilkin, John; Zavala-Garay, Javier; Levin, Julia. "Integrating modeling and data assimilation using ROMS with a Coastal Ocean Observing System for the US Middle Atlantic Bight" (PDF). Workshop Report: The Australian Coastal and Oceans Modelling and Observations Workshop (ACOMO 2012). p. 3. Archived from the original (PDF) on 2017-04-07. Retrieved 2016-10-25.
- ^ "ESPRESSO ocean modeling from Rutgers ROMS group". www.myroms.org. Retrieved 2019-02-08.