Impact of including surface currents on simulation of Indian Ocean variability with the POAMA coupled model

Impact of including surface currents on simulation of Indian Ocean variability with the POAMA coupled model

Impacts on the coupled variability of the Indo-Pacific by including the effects of surface currents on surface stress are explored in four extended integrations of an experimental version of the Bureau of Meteorology’s coupled seasonal forecast model POAMA. The first pair of simulations differs only...

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Bibliographic Details
Published in:Climate dynamics 2011-04, Vol.36 (7-8), p.1291-1302
Main Authors: Zhao, Mei, Wang, Guomin, Hendon, Harry H., Alves, Oscar
Format: Article
Language:eng
Subjects:
Atmospheric models
Climate
Climatology
Climatology. Bioclimatology. Climate change
Earth and Environmental Science
Earth Sciences
Earth, ocean, space
Exact sciences and technology
External geophysics
Geophysics/Geodesy
Marine
Meteorology
Ocean currents
Ocean-atmosphere interaction
Oceanography
Seasons
Weather forecasting
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Summary:Impacts on the coupled variability of the Indo-Pacific by including the effects of surface currents on surface stress are explored in four extended integrations of an experimental version of the Bureau of Meteorology’s coupled seasonal forecast model POAMA. The first pair of simulations differs only in their treatment of momentum coupling: one version includes the effects of surface currents on the surface stress computation and the other does not. The version that includes the effect of surface currents has less mean-state bias in the equatorial Pacific cold tongue but produces relatively weak coupled variability in the Tropics, especially that related to the Indian Ocean dipole (IOD) and El Niño/Southern Oscillation (ENSO). The version without the effects of surface currents has greater bias in the Pacific cold tongue but stronger IOD and ENSO variability. In order to diagnose the role of changes in local coupling from changes in remote forcing by ENSO for causing changes in IOD variability, a second set of simulations is conducted where effects of surface currents are included only in the Indian Ocean and only in the Pacific Ocean. IOD variability is found to be equally reduced by inclusion of the local effects of surface currents in the Indian Ocean and by the reduction of ENSO variability as a result of including effects of surface currents in the Pacific. Some implications of these results for predictability of the IOD and its dependence on ENSO, and for ocean subsurface data assimilation are discussed.
ISSN:0930-7575
1432-0894