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Spatial and Temporal Variability of North Atlantic Eddy Field at Scale less than 100km.
  • +4
  • Adekunle Ajayi,
  • Julien Le Sommer,
  • Eric Chassignet,
  • Jean-Marc Molines,
  • Xiaobiao Xu,
  • Aurelie Albert,
  • Emmanuel Cosme
Adekunle Ajayi
Universite Grenoble Alpes /CNRS/IGE, Grenoble, France.

Corresponding Author:[email protected]

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Julien Le Sommer
Universite Grenoble Alpes /CNRS/IGE, Grenoble, France.
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Eric Chassignet
COAPS / Florida State University, Tallahassee, USA.
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Jean-Marc Molines
Universite Grenoble Alpes /CNRS/IGE, Grenoble, France.
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Xiaobiao Xu
COAPS / Florida State University,Tallahassee, USA
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Aurelie Albert
Universite Grenoble Alpes /CNRS/IGE, Grenoble, France.
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Emmanuel Cosme
Universite Grenoble Alpes /CNRS/IGE, Grenoble, France.
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Abstract

Ocean circulation is dominated by turbulent geostrophic eddy fields with typical scales ranging from 10 km to 300 km. At mesoscales (> 50 km), the size of eddy structures varies regionally following the Rossby radius of deformation. The variability of the scale of smaller eddies is not well known due to the limitations in existing numerical simulations and satellite capability. But it is well established that oceanic flows (< 50km) generally exhibit strong seasonality. In this study, we present a basin-scale analysis of coherent structures down to 10\,km in the North Atlantic Ocean using two submesoscale-permitting ocean models, a NEMO-based North Atlantic simulation with a horizontal resolution of 1/60 (NATL60) and an HYCOM-based Atlantic simulation with a horizontal resolution of 1/50 (HYCOM50). We investigate the spatial and temporal variability of the scale of eddy structures with a particular focus on eddies with scales of 10 to 100\,km, and examine the impact of the seasonality of submesoscale energy on the seasonality and distribution of coherent structures in the North Atlantic. Our results show an overall good agreement between the two models in terms of surface wavenumber spectra and seasonal variability. The key findings of the paper are that (i) the mean size of ocean eddies show strong seasonality; (ii) this seasonality is associated with an increased population of submesoscale eddies (10\,–\,50\,km) in winter; and (iii) the net release of available potential energy associated with mixed layer instability is responsible for the emergence of the increased population of submesoscale eddies in wintertime.