Assessing the Quality of Southern Ocean Circulation in CMIP5 AOGCM and Earth System Model Simulations

The Southern Ocean (SO) is vital to Earth’s climate system due to its dominant role in exchanging carbon and heat between the ocean and atmosphere and transforming water masses. Evaluating the ability of fully coupled climate models to accurately simulate SO circulation and properties is crucial for...

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Bibliographic Details
Published in:Journal of climate 2019-09, Vol.32 (18), p.5915-5940
Main Authors: Beadling, R. L., Russell, J. L., Stouffer, R. J., Goodman, P. J., Mazloff, M.
Format: Article
Language:English
Subjects:
Antarctic Circumpolar Current
Atmospheric models
Biogeochemistry
Carbon
Circulation
Climate
Climate change
Climate models
Climate system
Computer simulation
Deep water
Fluxes
Heat
Heat exchange
Intercomparison
Model accuracy
Ocean circulation
Ocean currents
Ocean models
Oceans
Properties
Properties (attributes)
Quality assessment
Representations
Salinity
Simulation
Surface wind
Water circulation
Water masses
Wind
Wind stress
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Summary:The Southern Ocean (SO) is vital to Earth’s climate system due to its dominant role in exchanging carbon and heat between the ocean and atmosphere and transforming water masses. Evaluating the ability of fully coupled climate models to accurately simulate SO circulation and properties is crucial for building confidence in model projections and advancing model fidelity. By analyzing multiple biases collectively across large model ensembles, physical mechanisms governing the diverse mean-state SO circulation found across models can be identified. This analysis 1) assesses the ability of a large ensemble of models contributed to phase 5 of the Coupled Model Intercomparison Project (CMIP5) to simulate observationally based metrics associated with an accurate representation of the Antarctic Circumpolar Current (ACC), and 2) presents a framework by which the quality of the simulation can be categorized and mechanisms governing the resulting circulation can be deduced. Different combinations of biases in critical metrics including the magnitude and position of the zonally averaged westerly wind stress maximum, wind-driven surface divergence, surface buoyancy fluxes, and properties and transport of North Atlantic Deep Water entering the SO produce distinct mean-state ACC transports. Relative to CMIP3, the quality of the CMIP5 SO simulations has improved. Eight of the thirty-one models simulate an ACC within observational uncertainty (2σ) for approximately the right reasons; that is, the models achieve accuracy in the surface wind stress forcing and the representation of the difference in the meridional density across the current. Improved observations allow for a better assessment of the SO circulation and its properties.
ISSN:0894-8755
1520-0442
DOI:10.1175/JCLI-D-19-0263.1