Westward Motion of Mesoscale Eddies

Benoit Cushman-Roisin Department of Oceanography, Florida State University, Tallahassee, Florida

Search for other papers by Benoit Cushman-Roisin in
Current site
Google Scholar
PubMed
Close
,
Benyang Tang Department of Oceanography, Florida State University, Tallahassee, Florida

Search for other papers by Benyang Tang in
Current site
Google Scholar
PubMed
Close
, and
Eric P. Chassignet National Center for Atmospheric Research, Boulder, Colorado

Search for other papers by Eric P. Chassignet in
Current site
Google Scholar
PubMed
Close
Full access

Abstract

Since the pioneering work of Nof, the determination of the westward drift of mesoscale eddies under the planetary (beta) effect has been a recurrent theme in mesoscale oceanography, and several different formulae have been proposed in the literature. Here, recpatiulation is sought, and, within the confines of a single-layer model, a generalized formula is derived. Although it is similar to Nof's, the present formula is established from a modified definition and with fewer assumptions. It also recaptiulates all other formulae for the one-layer model and applies to a wide variety of situations, including cases when the vortex develops a wake of Rossby waves or undergoes axismmetrization.

Following the derivation of the formula, a physical interpretation clarifies the migration mechanism, which can be divided between a self-induced propulsion and a reaction from the displaced ambient fluid. Numerical simulations with primitive and geostrophic equations validate the formula for a variety of length scales and amplitudes. The work concludes with an attempt to extend the result to systems with two moving layers.

Abstract

Since the pioneering work of Nof, the determination of the westward drift of mesoscale eddies under the planetary (beta) effect has been a recurrent theme in mesoscale oceanography, and several different formulae have been proposed in the literature. Here, recpatiulation is sought, and, within the confines of a single-layer model, a generalized formula is derived. Although it is similar to Nof's, the present formula is established from a modified definition and with fewer assumptions. It also recaptiulates all other formulae for the one-layer model and applies to a wide variety of situations, including cases when the vortex develops a wake of Rossby waves or undergoes axismmetrization.

Following the derivation of the formula, a physical interpretation clarifies the migration mechanism, which can be divided between a self-induced propulsion and a reaction from the displaced ambient fluid. Numerical simulations with primitive and geostrophic equations validate the formula for a variety of length scales and amplitudes. The work concludes with an attempt to extend the result to systems with two moving layers.

Save