Propagation of coastal‐trapped waves under an ice cover in Hudson Bay* |
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| Authors: | Thierry Reynaud R Grant Ingram Howard J Freeland Andrew J Weaver |
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| Institution: | 1. Department of Atmospheric and Oceanic Sciences , McGill University , 805 Sherbrook Street W., Montréal, Quebec, H3A 2K6;2. Institute of Ocean Sciences , P.O. Box 6000, Sidney, British Columbia, V8L 4B2;3. Centre for Earth and Ocean Research , University of Victoria , P.O. Box 1700, Victoria, B.C., V8W 2Y2 |
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| Abstract: | Abstract Three arrays of current‐meter moorings were deployed under landfast sea ice in southeast Hudson Bay for eight weeks in spring 1986. Spectral analysis shows low‐frequency signals with periods of 3 to 11 days. These signals are interpreted as being due to coastal‐trapped waves propagating cyclonically in Hudson Bay; their theoretical dispersion relations and corresponding modal structures are presented for winter stratification and are compared with observations. At a period of 3 days both the modified external Kelvin wave and higher mode continental shelf waves may be important in describing the observed low‐frequency variability, whereas at a period of 10 days the Kelvin wave appears to be the dominant mode. The generation mechanisms for these coastal trapped waves are also investigated. Two sources have been studied: the longshore atmospheric pressure gradient and the average atmospheric pressure over the ice cover in Hudson Bay. Coherence and phase analyses performed with time series of longshore current and atmospheric forcing data reveal that both the average atmospheric pressure and the longshore atmospheric pressure gradient are important in explaining the observed low‐frequency variability, without indicating which one is the most important. |
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