Abstract
A reduced-gravity primitive equation eddy resolving model has been used to study the decay of a mesoscale eddy as it migrates toward a western boundary current (WBC) region. The model results indicated that the gradient of the relative vorticity to the east of the WBC is an important factor in the interaction between an eddy and a WBC. A circular eddy is deformed into an elliptical form during the eddy–WBC interaction with the major axis of a cyclonic/anticyclonic eddy aligning in the NW/NNE direction, respectively. Because of the difference in the major axes orientations for the cyclonic and anticyclonic eddies, the kinetic energy transfer between a WBC and a particular eddy has very different behavior. A cyclonic eddy loses its energy to the mean field, whereas an anticyclonic eddy can obtain energy from the mean flow during the WBC–eddy interaction. An anticyclonic eddy, however, still decayed from losing its water and friction dissipation during the interaction period.
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This work was sponsored by the National Science Council, the Republic of China, Grant NSC 98-2611-M-002-015-MY3.
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Kuo, YC., Chern, CS. Numerical study on the interactions between a mesoscale eddy and a western boundary current. J Oceanogr 67, 263–272 (2011). https://doi.org/10.1007/s10872-011-0026-3
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DOI: https://doi.org/10.1007/s10872-011-0026-3