Journal of Geological Society of India (Online archive from Vol 1 to Vol 78)

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Ocean Model Derived Global Surface Circulation and Vertical Velocity


Affiliations
1 Nehru Science Center, K. Banerjee Center of Atmospheric and Ocean Studies, University of Allahabad, Allahabad - 211 002, India
     

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In this article, the authors examine Sea surface temperature (SST), Sea surface circulation (SSC) and Vertical velocity (VV) fields from simulation of 25 layers coarse resolution Modular ocean model (MOM version 3.0) with prescribed wind forcing for the region 74.25°S to 65°N, 180°W-180°E.

It is found that distribution of SST simulated by the model shows its consistency with the observed climatology. However, simulated SST in the areas of Arabian Sea, Bay of Bengal, Indonesian Throughflow (ITF) region and east of North America near equator exhibit slight warming with respect to observation, which may be due to model deficiency and forcing problems. Circulation features suggest that one of the strongest current viz. Antarctic circumpolar current (ACC) along with other major current systems viz. Gulf stream current, North and South Pacific current, Agulhas current, Labrador current, Canary current, etc. are captured well by the model. In the Indian Ocean and other ocean basins, current patterns are well captured by the model simulation. Intense upwelling as well as downwelling areas is marked in the horizontal distribution of VV, which is as expected. VV show quasi-stagnant and convergent regions suggesting that floating materials may be accumulated during January/July in the real ocean and wind driven circulation may act as an important contribution for such transport of floating materials in these regions. An attempt has also been made to understand the fluctuations of the SST in NINO 3.4 region during the period of model simulation using SST anomalies.


Keywords

Modular Ocean Model (MOM), Antarctic Circumpolar Current, Vertical Velocity, Sea Surface Current, Sea Surface Temperature, Quasi-Stagnant, Convergent.
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  • Ocean Model Derived Global Surface Circulation and Vertical Velocity

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Authors

Anshu Prakash Mishra
Nehru Science Center, K. Banerjee Center of Atmospheric and Ocean Studies, University of Allahabad, Allahabad - 211 002, India
A. C. Pandey
Nehru Science Center, K. Banerjee Center of Atmospheric and Ocean Studies, University of Allahabad, Allahabad - 211 002, India
S. Rai
Nehru Science Center, K. Banerjee Center of Atmospheric and Ocean Studies, University of Allahabad, Allahabad - 211 002, India

Abstract


In this article, the authors examine Sea surface temperature (SST), Sea surface circulation (SSC) and Vertical velocity (VV) fields from simulation of 25 layers coarse resolution Modular ocean model (MOM version 3.0) with prescribed wind forcing for the region 74.25°S to 65°N, 180°W-180°E.

It is found that distribution of SST simulated by the model shows its consistency with the observed climatology. However, simulated SST in the areas of Arabian Sea, Bay of Bengal, Indonesian Throughflow (ITF) region and east of North America near equator exhibit slight warming with respect to observation, which may be due to model deficiency and forcing problems. Circulation features suggest that one of the strongest current viz. Antarctic circumpolar current (ACC) along with other major current systems viz. Gulf stream current, North and South Pacific current, Agulhas current, Labrador current, Canary current, etc. are captured well by the model. In the Indian Ocean and other ocean basins, current patterns are well captured by the model simulation. Intense upwelling as well as downwelling areas is marked in the horizontal distribution of VV, which is as expected. VV show quasi-stagnant and convergent regions suggesting that floating materials may be accumulated during January/July in the real ocean and wind driven circulation may act as an important contribution for such transport of floating materials in these regions. An attempt has also been made to understand the fluctuations of the SST in NINO 3.4 region during the period of model simulation using SST anomalies.


Keywords


Modular Ocean Model (MOM), Antarctic Circumpolar Current, Vertical Velocity, Sea Surface Current, Sea Surface Temperature, Quasi-Stagnant, Convergent.