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The impact of resolving the Rossby radius at mid-latitudes in the ocean: results from a high-resolution version of the Met Office GC2 coupled model

The impact of resolving the Rossby radius at mid-latitudes in the ocean: results from a high-resolution version of the Met Office GC2 coupled model
The impact of resolving the Rossby radius at mid-latitudes in the ocean: results from a high-resolution version of the Met Office GC2 coupled model
There is mounting evidence that resolving mesoscale eddies and western boundary currents as well as topographically controlled flows can play an important role in air–sea interaction associated with vertical and lateral transports of heat and salt. Here we describe the development of the Met Office Global Coupled Model version 2 (GC2) with increased resolution relative to the standard model: the ocean resolution is increased from 1/4 to 1/12° (28 to 9 km at the Equator), the atmosphere resolution increased from 60 km (N216) to 25 km (N512) and the coupling period reduced from 3 hourly to hourly. The technical developments that were required to build a version of the model at higher resolution are described as well as results from a 20-year simulation. The results demonstrate the key role played by the enhanced resolution of the ocean model: reduced sea surface temperature (SST) biases, improved ocean heat transports, deeper and stronger overturning circulation and a stronger Antarctic Circumpolar Current. Our results suggest that the improvements seen here require high resolution in both atmosphere and ocean components as well as high-frequency coupling. These results add to the body of evidence suggesting that ocean resolution is an important consideration when developing coupled models for weather and climate applications.
1991-9603
3655-3670
Hewitt, Helene T.
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Roberts, Malcolm J.
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Hyder, Pat
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Graham, Tim
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Rae, Jamie
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Belcher, Stephen E.
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Bourdallé-badie, Romain
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Copsey, Dan
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Coward, Andrew
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Guiavarch, Catherine
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Harris, Chris
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Hill, Richard
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Hirschi, Joël J.-m.
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Madec, Gurvan
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Mizielinski, Matthew S.
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Neininger, Erica
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New, Adrian L.
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Rioual, Jean-christophe
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Sinha, Bablu
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Wood, Richard A.
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Hewitt, Helene T.
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Roberts, Malcolm J.
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Hyder, Pat
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Graham, Tim
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Rae, Jamie
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Belcher, Stephen E.
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Bourdallé-badie, Romain
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Copsey, Dan
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Coward, Andrew
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Guiavarch, Catherine
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Harris, Chris
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Hill, Richard
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Hirschi, Joël J.-m.
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Madec, Gurvan
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Mizielinski, Matthew S.
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Neininger, Erica
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New, Adrian L.
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Rioual, Jean-christophe
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Sinha, Bablu
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Storkey, David
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Shelly, Ann
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Thorpe, Livia
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Wood, Richard A.
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Hewitt, Helene T., Roberts, Malcolm J., Hyder, Pat, Graham, Tim, Rae, Jamie, Belcher, Stephen E., Bourdallé-badie, Romain, Copsey, Dan, Coward, Andrew, Guiavarch, Catherine, Harris, Chris, Hill, Richard, Hirschi, Joël J.-m., Madec, Gurvan, Mizielinski, Matthew S., Neininger, Erica, New, Adrian L., Rioual, Jean-christophe, Sinha, Bablu, Storkey, David, Shelly, Ann, Thorpe, Livia and Wood, Richard A. (2016) The impact of resolving the Rossby radius at mid-latitudes in the ocean: results from a high-resolution version of the Met Office GC2 coupled model. Geoscientific Model Development, 9 (10), 3655-3670. (doi:10.5194/gmd-9-3655-2016).

Record type: Article

Abstract

There is mounting evidence that resolving mesoscale eddies and western boundary currents as well as topographically controlled flows can play an important role in air–sea interaction associated with vertical and lateral transports of heat and salt. Here we describe the development of the Met Office Global Coupled Model version 2 (GC2) with increased resolution relative to the standard model: the ocean resolution is increased from 1/4 to 1/12° (28 to 9 km at the Equator), the atmosphere resolution increased from 60 km (N216) to 25 km (N512) and the coupling period reduced from 3 hourly to hourly. The technical developments that were required to build a version of the model at higher resolution are described as well as results from a 20-year simulation. The results demonstrate the key role played by the enhanced resolution of the ocean model: reduced sea surface temperature (SST) biases, improved ocean heat transports, deeper and stronger overturning circulation and a stronger Antarctic Circumpolar Current. Our results suggest that the improvements seen here require high resolution in both atmosphere and ocean components as well as high-frequency coupling. These results add to the body of evidence suggesting that ocean resolution is an important consideration when developing coupled models for weather and climate applications.

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Accepted/In Press date: 25 September 2016
e-pub ahead of print date: 13 October 2016

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Local EPrints ID: 412499
URI: http://eprints.soton.ac.uk/id/eprint/412499
ISSN: 1991-9603
PURE UUID: fca0a317-df84-405f-9b63-1601c2d0e1f4

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Date deposited: 17 Jul 2017 14:00
Last modified: 15 Mar 2024 12:37

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Contributors

Author: Helene T. Hewitt
Author: Malcolm J. Roberts
Author: Pat Hyder
Author: Tim Graham
Author: Jamie Rae
Author: Stephen E. Belcher
Author: Romain Bourdallé-badie
Author: Dan Copsey
Author: Andrew Coward
Author: Catherine Guiavarch
Author: Chris Harris
Author: Richard Hill
Author: Joël J.-m. Hirschi
Author: Gurvan Madec
Author: Matthew S. Mizielinski
Author: Erica Neininger
Author: Adrian L. New
Author: Jean-christophe Rioual
Author: Bablu Sinha
Author: David Storkey
Author: Ann Shelly
Author: Livia Thorpe
Author: Richard A. Wood

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