The Internal Barotropic Instability of Surface-Intensified Eddies. Part II: Modeling of the Tourbillon Site.
International audience Data from the Tourbillon Experiment Intensive Period in the northeast Atlantic presented evidence of a vertical phase shift with time of the main eddy, interpreted as an occurrence of internal barotropic instability. In order to justify this: (i) the idealized case of an isola...
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Other Authors: | , |
Format: | Article in Journal/Newspaper |
Language: | English |
Published: |
HAL CCSD
1988
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Subjects: | |
Online Access: | https://hal.archives-ouvertes.fr/hal-00268781 https://doi.org/10.1175/1520-0485(1988)018<0056:TIBIOS>2.0.CO;2 |
Summary: | International audience Data from the Tourbillon Experiment Intensive Period in the northeast Atlantic presented evidence of a vertical phase shift with time of the main eddy, interpreted as an occurrence of internal barotropic instability. In order to justify this: (i) the idealized case of an isolated eddy immersed in a stratified environment, whose characteristics correspond to the Tourbillon site (see Part I) and (ii) the realistic case using the full three-dimensional data from the experiment as initial conditions (Part II) are modeled. Both studies use a quasi-geostrophic periodic spectral model with six vertical normal modes and a horizontal 128×128 grid. It is demonstrated that a some what realistic “forecast” can be obtained for an integration time of up to one month. While a linear instability analysis revealed that the Tourbillon eddy is very slowly unstable (Part I), its encounter with a Mediterranean Water tongue caused a large-amplitude baroclinic perturbation, triggering a nonlinear destabilization of the eddy, and hence the observed tilting of its vertical axis with time. One failure of the model concerns the final fate of the eddy: at the end of the intensive measurement period, the eddy is observed to remain a single entity, while the quasi-geostrophic modeling predicts its fragmentation into two vertically smaller structures by the strong instability. |
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