Editorial Type:
Article
Article Type:
Research Article

Langmuir Circulation: An Agent for Vertical Restratification?

Ke Li University of New Hampshire, Durham, New Hampshire

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Zhexuan Zhang University of New Hampshire, Durham, New Hampshire

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Greg Chini University of New Hampshire, Durham, New Hampshire

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Glenn Flierl University of New Hampshire, Durham, New Hampshire

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Print Publication:
01 Nov 2012
DOI:
https://doi.org/10.1175/JPO-D-11-0225.1
Page(s):
1945–1958
Restricted access

Abstract

Comparably little is known about the impact of down-front-propagating surface waves on the stability of submesoscale lateral fronts in the ocean surface mixed layer. In this investigation, the stability of lateral fronts in gradient–wind balance to two-dimensional (down-front invariant) disturbances is analyzed using the stratified, rotating Craik–Leibovich (CL) equations. Through the action of the CL vortex force, the surface waves fundamentally alter the superinertial, two-dimensional linear stability of these fronts, with the classical symmetric instability mode being replaced by a hybrid Langmuir circulation/symmetric mode. The hybrid mode is shown to exhibit much larger growth rates than the pure symmetric mode, to exist in a regime in which the vertical Richardson number is greater than 1, and to accomplish significant cross-isopycnal transport. Nonhydrostatic numerical simulations reveal that the nonlinear evolution of this hybrid instability mode can lead to rapid, that is, superinertial, vertical restratification of the mixed layer. Paradoxically, Langmuir circulation—generally viewed as a prominent vertical mixing mechanism in the upper ocean—may thus play a role in mixed layer restratification.

Corresponding author address: Greg Chini, University of New Hampshire, W113 Kingsbury Hall, Durham, NH 03824. E-mail: greg.chini@unh.edu

Abstract

Comparably little is known about the impact of down-front-propagating surface waves on the stability of submesoscale lateral fronts in the ocean surface mixed layer. In this investigation, the stability of lateral fronts in gradient–wind balance to two-dimensional (down-front invariant) disturbances is analyzed using the stratified, rotating Craik–Leibovich (CL) equations. Through the action of the CL vortex force, the surface waves fundamentally alter the superinertial, two-dimensional linear stability of these fronts, with the classical symmetric instability mode being replaced by a hybrid Langmuir circulation/symmetric mode. The hybrid mode is shown to exhibit much larger growth rates than the pure symmetric mode, to exist in a regime in which the vertical Richardson number is greater than 1, and to accomplish significant cross-isopycnal transport. Nonhydrostatic numerical simulations reveal that the nonlinear evolution of this hybrid instability mode can lead to rapid, that is, superinertial, vertical restratification of the mixed layer. Paradoxically, Langmuir circulation—generally viewed as a prominent vertical mixing mechanism in the upper ocean—may thus play a role in mixed layer restratification.

Corresponding author address: Greg Chini, University of New Hampshire, W113 Kingsbury Hall, Durham, NH 03824. E-mail: greg.chini@unh.edu
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