The role of mixed-layer instabilities in submesoscale turbulence

Author(s)

Callies, Joern; Flierl, Glenn Richard; Ferrari, Raffaele; Fox-Kemper, Baylor

Abstract

Upper-ocean turbulence at scales smaller than the mesoscale is believed to exchange surface and thermocline waters, which plays an important role in both physical and biogeochemical budgets. But what energizes this submesoscale turbulence remains a topic of debate. Two mechanisms have been proposed: mesoscale-driven surface frontogenesis and baroclinic mixed-layer instabilities. The goal here is to understand the differences between the dynamics of these two mechanisms, using a simple quasi-geostrophic model. The essence of mesoscale-driven surface frontogenesis is captured by the well-known surface quasi-geostrophic model, which describes the sharpening of surface buoyancy gradients and the subsequent breakup in secondary roll-up instabilities. We formulate a similarly archetypical Eady-like model of submesoscale turbulence induced by mixed-layer instabilities. The model captures the scale and structure of this baroclinic instability in the mixed layer. A wide range of scales are energized through a turbulent inverse cascade of kinetic energy that is fuelled by the submesoscale mixed-layer instability. Major differences to mesoscale-driven surface frontogenesis are that mixed-layer instabilities energize the entire depth of the mixed layer and produce larger vertical velocities. The distribution of energy across scales and in the vertical produced by our simple model of mixed-layer instabilities compares favourably to observations of energetic wintertime submesoscale flows, suggesting that it captures the leading-order balanced dynamics of these flows. The dynamics described here in an oceanographic context have potential applications to other geophysical fluids with layers of different stratifications.

Date issued

2015-12

URI

http://hdl.handle.net/1721.1/116612

Department

Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences

Journal

Journal of Fluid Mechanics

Publisher

Cambridge University Press (CUP)

Citation

Callies, Jörn, Glenn Flierl, Raffaele Ferrari, and Baylor Fox-Kemper. “The Role of Mixed-Layer Instabilities in Submesoscale Turbulence.” Journal of Fluid Mechanics 788 (December 2015): 5–41 © 2016 Cambridge University Press

Version: Author's final manuscript

ISSN

0022-1120

1469-7645