4.5 Article

Global coarse-grained mesoscale eddy statistics based on integrated kinetic energy and enstrophy correlations

Journal

OCEAN SCIENCE
Volume 18, Issue 5, Pages 1361-1375

Publisher

COPERNICUS GESELLSCHAFT MBH
DOI: 10.5194/os-18-1361-2022

Keywords

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Funding

  1. Max-Planck-Institut fur Physik Komplexer Systeme (Visitor Programme)
  2. Nemzeti Kutatasi Fejlesztesi es Innovacios Hivatal, National Research, Development and Innovation Office [FK-125024, K-125171]
  3. Conselho Nacional de Desenvolvimento Cientifico e Tecnologico, Ciencia sem Fronteiras [PQ-305305/2020-4]

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This study introduces the concept of a vortex proxy and demonstrates its effectiveness in obtaining surface flow statistics of mesoscale vortices on a global scale. The study compares the results with a global vortex database and shows good agreement. The study also analyzes the drift velocities and kinetic energy transport of the vortices.
Recently, introduced the concept of a vortex proxy based on an observation of strong correlations between integrated kinetic energy and integrated enstrophy over a large enough surface area. When mesoscale vortices are assumed to exhibit a Gaussian shape, the two spatial integrals have particularly simple functional forms, and a ratio of them defines an effective radius of a proxy vortex. In the original work, the idea was tested over a restricted area in the Californian Current System. Here we extend the analysis to global scale by means of 25 years of AVISO altimetry data covering the (ice-free) global ocean. The results are compared with a global vortex database containing over 64 million mesoscale eddies. We demonstrate that the proxy vortex representation of surface flow fields also works globally and provides a quick and reliable way to obtain coarse-grained vortex statistics. Estimated mean eddy sizes (effective radii) are extracted in very good agreement with the data from the vortex census. Recorded eddy amplitudes are directly used to infer the kinetic energy transported by the mesoscale vortices. The ratio of total and eddy kinetic energies is somewhat higher than found in previous studies. The characteristic westward drift velocities are evaluated by a time-lagged cross-correlation analysis of the kinetic energy fields. While zonal mean drift speeds are in good agreement with vortex trajectory evaluation in the latitude bands 30-5 degrees S and 5-30 degrees N, discrepancies are exhibited mostly at higher latitudes on both hemispheres. A plausible reason for somewhat different drift velocities obtained by eddy tracking and cross-correlation analysis is the fact that the drift of mesoscale eddies is only one component of the surface flow fields. Rossby wave activities, coherent currents, and other propagating features on the ocean surface apparently contribute to the zonal transport of kinetic energy.

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