Wave-vortex decomposition of one-dimensional ship-track data

We present a simple two-step method by which one-dimensional spectra of horizontal velocity and buoyancy measured along a ship track can be decomposed into a wave component consisting of inertia-gravity waves and a vortex component consisting of a horizontal flow in geostrophic balance. The method r...

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Bibliographic Details
Main Authors: Ferrari, Raffaele (Contributor), Callies, Joern (Contributor), Buhler, Oliver (Author)
Other Authors: Joint Program in Oceanography/Applied Ocean Science and Engineering (Contributor), Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences (Contributor), Woods Hole Oceanographic Institution (Contributor)
Format: Article
Language:English
Published: Cambridge University Press, 2015-10-06T17:57:31Z.
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Summary:We present a simple two-step method by which one-dimensional spectra of horizontal velocity and buoyancy measured along a ship track can be decomposed into a wave component consisting of inertia-gravity waves and a vortex component consisting of a horizontal flow in geostrophic balance. The method requires certain assumptions for the data regarding stationarity, homogeneity, and horizontal isotropy. In the first step an exact Helmholtz decomposition of the horizontal velocity spectra into rotational and divergent components is performed and in the second step an energy equipartition property of hydrostatic inertia-gravity waves is exploited that allows a diagnosis of the wave energy spectrum solely from the observed horizontal velocities. The observed buoyancy spectrum can then be used to compute the residual vortex energy spectrum. Further wave-vortex decompositions of the observed fields are possible if additional information about the frequency content of the waves is available. We illustrate the method on two recent oceanic data sets from the North Pacific and the Gulf Stream. Notably, both steps in our new method might be of broader use in the theoretical and observational study of atmosphere and ocean fluid dynamics.
United States. Office of Naval Research (Grant N-00014-09-1-0458)
Grant GMG-1024198