Model:MITgcm: Difference between revisions

Latest revision as of 06:56, 21 June 2021

MITgcm

Metadata

Also known as
Model type	Modular
Model part of larger framework
Note on status model
Date note status model

Spatial dimensions	3D
Spatial extent	Global
Model domain	Climate
One-line model description	The MITgcm (MIT General Circulation Model) is a numerical model designed for study of the atmosphere, ocean, and climate.
Extended model description	The MITgcm (MIT General Circulation Model) is a numerical model designed for study of the atmosphere, ocean, and climate. Its non-hydrostatic formulation enables it to simulate fluid phenomena over a wide range of scales; its adjoint capability enables it to be applied to parameter and state estimation problems. By employing fluid isomorphisms, one hydrodynamical kernel can be used to simulate flow in both the atmosphere and ocean.

Keywords:

Name	Nicole Lovenduski
Type of contact	Project manager
Institute / Organization	University of Colorado at Boulder
Postal address 1	Institute of Arctic and Alpine Research
Postal address 2	Campus Box 450
Town / City	Boulder
Postal code	80309
State	Colorado
Country	United States
Email address	nicole.lovenduski@colorado.edu
Phone
Fax

Supported platforms	Unix, Linux, Mac OS
Other platform
Programming language	Fortran90
Other program language
Code optimized	Multiple Processors
Multiple processors implemented
Nr of distributed processors
Nr of shared processors
Start year development	1997
Does model development still take place?	Yes
If above answer is no, provide end year model development
Code development status
When did you indicate the 'code development status'?
Model availability
Source code availability (Or provide future intension)	Through web repository
Source web address	http://mitgcm.org/
Source csdms web address
Program license type	Other
Program license type other	--
Memory requirements	Memory requirements range from around 10^7 bytes (≈ 10 megabytes) to 10^11 bytes (≈ 100 gigabytes).
Typical run time	Run time can range from minutes to weeks, depending on length of simulation and size/resolution of domain.

Describe input parameters
Input format	Binary
Other input format
Describe output parameters
Output format	Binary
Other output format	NetCDF
Pre-processing software needed?	No
Describe pre-processing software
Post-processing software needed?	No
Describe post-processing software
Visualization software needed?	No
If above answer is yes
Other visualization software

Describe processes represented by the model	too many to describe
Describe key physical parameters and equations	too many to describe
Describe length scale and resolution constraints
Describe time scale and resolution constraints
Describe any numerical limitations and issues

Describe available calibration data sets
Upload calibration data sets if available:
Describe available test data sets
Upload test data sets if available:
Describe ideal data for testing

Do you have current or future plans for collaborating with other researchers?

Is there a manual available?	No
Upload manual if available:
Model website if any
Model forum / discussion board

Do you have current or future plans for collaborating with other researchers?

Is there a manual available?	Yes
Upload manual if available:	Media:Manual_MITgcm.pdf
Model website if any
Model forum / discussion board

Comments	Notice: Code is freely available through the following site: http://mitgcm.org/ No need to register

This part will be filled out by CSDMS staff

OpenMI compliant	No but possible
BMI compliant	No but possible
WMT component	No but possible
PyMT component
Is this a data component

Can be coupled with:

Model info

Authors

Nicole Lovenduski

Source code

Go to external source code site

Model citations

Nr. of publications:	121
Total citations:	7909
h-index:	35
m-quotient:	0.76

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Link to this page

Other models by author

MITgcm

Introduction

History

References

Nr. of publications:	121
Total citations:	7909
h-index:	35
m-quotient:	0.76

Featured publication(s)	Year	Model described	Type of Reference	Citations
Marshall, John; Hill, Chris; Perelman, Lev; Adcroft, Alistair; 1997. Hydrostatic, quasi-hydrostatic, and nonhydrostatic ocean modeling. Journal of Geophysical Research: Oceans, 102, 5733–5752. 10.1029/96JC02776 (View/edit entry)	1997	MITgcm	Model overview	1366
Marshall, J.; Adcroft, A.; Hill, C.; Perelman, L.; Heisey, C. 1997. A finite-volume, incompressible Navier Stokes model for studies of the ocean on parallel computers. Journal of Geophysical Research - Oceans, 102, 5753–5766. 10.1029/96JC02775 (View/edit entry)	1997	MITgcm	Model overview	2385
Bett, D.T.; Bradley, A.T.; Williams, C.R.; Holland, P.R.; Arthern, R.J.; Goldberg, D.N.; 2024. Coupled ice–ocean interactions during future retreat of West Antarctic ice streams in the Amundsen Sea sector. The Cryosphere, 18, . 0.5194/tc-18-2653-2024 (View/edit entry)	2024	MITgcm WAVI.jl	Model application	2
See more publications of MITgcm

Issues

Help

Input Files

Output Files

@@ Line 1: / Line 1: @@
+{{Model identity
+|Model type=Modular
+}}
+{{Model identity2
+|ModelDomain=Climate
+|Spatial dimensions=3D
+|Spatialscale=Global
+|One-line model description=The MITgcm (MIT General Circulation Model) is a numerical model designed for study of the atmosphere, ocean, and climate.
+|Extended model description=The MITgcm (MIT General Circulation Model) is a numerical model designed for study of the atmosphere, ocean, and climate. Its non-hydrostatic formulation enables it to simulate fluid phenomena over a wide range of scales; its adjoint capability enables it to be applied to parameter and state estimation problems. By employing fluid isomorphisms, one hydrodynamical kernel can be used to simulate flow in both the atmosphere and ocean.
+}}
+{{Start model keyword table}}
+{{End a table}}
 {{Modeler information
 |First name=Nicole
@@ Line 9: / Line 21: @@
 |Postal code=80309
 |State=Colorado
-|Country=USA
+|Country=United States
 |Email address=nicole.lovenduski@colorado.edu
-}}
-{{Model identity
-|Model type=Modular
-|Categories=Climate
-|Spatial dimensions=3D
-|Spatialscale=Global
-|One-line model description=The MITgcm (MIT General Circulation Model) is a numerical model designed for study of the atmosphere, ocean, and climate.
-|Extended model description=The MITgcm (MIT General Circulation Model) is a numerical model designed for study of the atmosphere, ocean, and climate. Its non-hydrostatic formulation enables it to simulate fluid phenomena over a wide range of scales; its adjoint capability enables it to be applied to parameter and state estimation problems. By employing fluid isomorphisms, one hydrodynamical kernel can be used to simulate flow in both the atmosphere and ocean.
-}}
-{{Start model keyword table
-}}
-{{End a table
 }}
 {{Model technical information
@@ Line 49: / Line 49: @@
 |Describe key physical parameters and equations=too many to describe
 }}
-{{Model testing
+{{Model testing}}
-}}
+{{Users groups model}}
-{{Users groups model
+{{Documentation model
+|Manual model available=No
 }}
+{{Users groups model}}
 {{Documentation model
-|Provide key papers on model if any=Hill, C. and J. Marshall, (1995), Application of a Parallel Navier-Stokes Model to Ocean Circulation in Parallel Computational Fluid Dynamics, In Proceedings of Parallel Computational Fluid Dynamics: Implementations and Results Using Parallel Computers, 545-552. Elsevier Science B.V.: New York
+|Manual model available=Yes
+|Model manual=Manual_MITgcm.pdf,
-Marshall, J., C. Hill, L. Perelman, and A. Adcroft, (1997), Hydrostatic, quasi-hydrostatic, and nonhydrostatic ocean modeling, J. Geophysical Res., 102(C3), 5733-5752.
-Marshall, J., A. Adcroft, C. Hill, L. Perelman, and C. Heisey, (1997), A finite-volume, incompressible Navier Stokes model for studies of the ocean on parallel computers, J. Geophysical Res.,102(C3),5753-5766.
-Adcroft,A.J.,Hill,C.N. and J.Marshall,(1997), Representation of topography by shaved cells in a height coordinate ocean model, Mon Wea Rev, vol 125, 2293-2315.
-Marshall,J.,Jones,H.andC.Hill,(1998), Efficient ocean modeling using non-hydrostatic algorithms, Journal of Marine Systems,18,115-134.
-Adcroft,A.,Hill C.and J.Marshall:(1999), A new treatment of the Coriolis terms in C-grid models at both high and low resolutions, Mon. Wea. Rev. Vol 127, pages 1928-1936.
-Hill, C, Adcroft, A., Jamous, D.,and J.Marshall,(1999), A Strategy for Terascale Climate Modeling. In Proceedings of the Eighth ECMWF Workshop on the Use of Parallel Processors in Meteorology, pages 406-425, World Scientific Publishing Co:UK.
-Marotzke,J,Giering,R.,Zhang,K.Q.,Stammer,D.,Hill,C.,and T.Lee,(1999),Construction of the adjoint MIT ocean general circulation model and
-application to Atlantic heat transport variability, J. Geophysical Res., 104(C12), 29, 529-29,547.
 }}
 {{Additional comments model
@@ Line 80: / Line 68: @@
 |CCA component=No but possible
 |IRF interface=No but possible
-|CMT component=Not yet
+|CMT component=No but possible
-}}
-{{Start coupled table
 }}
+{{Start coupled table}}
+{{End a table}}
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+{{{{PAGENAME}}_autokeywords}}
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 ==Introduction==
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 == History ==
-== Papers ==
+== References  ==
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+{{#ifexist:Template:{{PAGENAME}}-citation-indices|{{{{PAGENAME}}-citation-indices}}|}}<br>
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 == Issues ==
 == Help ==
+{{#ifexist:Model_help:{{PAGENAME}}|[[Model_help:{{PAGENAME}}]]|}}
 == Input Files ==
 == Output Files ==
-== Download ==
-== Source ==