The motion of a fluid ellipsoid in a general linear background flow

WILLIAM J. McKIVER; DAVID G. DRITSCHEL

doi:10.1017/S0022112002002859

Abstract

The study of the motion of a fluid ellipsoid has a long and fascinating history stretching back originally to Laplace in the late 18th century. Recently, this subject has been revived in the context of geophysical fluid dynamics, where it has been shown that an ellipsoid of uniform potential vorticity remains an ellipsoid in a background flow consisting of horizontal strain, vertical shear, and uniform rotation. The object of the present work is to present a simple, appealing, and practical way of investigating the motion of an ellipsoid not just in geophysical fluid dynamics but in general. The main result is that the motion of an ellipsoid may be reduced to the evolution of a symmetric, 3×3 matrix, under the action of an arbitrary 3×3 ‘flow’ matrix. The latter involves both the background flow, which must be linear in the Cartesian coordinates at the surface of the ellipsoid, and the self-induced flow, which was given by Laplace.

The resulting simple dynamical system lends itself ideally to both numerical and analytical study. We illustrate a few examples and then present a theory for the evolution of a vortex within a slowly varying background flow. We show that a vortex may evolve quasi-adiabatically, that is, it stays close to an equilibrium form associated with the instantaneous background flow. The departure from equilibrium, on the other hand, is proportional to the rate of change of the background flow.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Benilov, E. S. 2005. Stability of a Two-Layer Quasigeostrophic Vortex over Axisymmetric Localized Topography. Journal of Physical Oceanography, Vol. 35, Issue. 1, p. 123.

ÖZUĞURLU, ERSIN REINAUD, JEAN N. and DRITSCHEL, DAVID G. 2008. Interaction between two quasi-geostrophic vortices of unequal potential vorticity. Journal of Fluid Mechanics, Vol. 597, Issue. , p. 395.

Dritschel, David G. 2011. An exact steadily rotating surface quasi-geostrophic elliptical vortex. Geophysical & Astrophysical Fluid Dynamics, Vol. 105, Issue. 4-5, p. 368.

Tsang, Yue-Kin and Dritschel, David G. 2015. Ellipsoidal vortices in rotating stratified fluids: beyond the quasi-geostrophic approximation. Journal of Fluid Mechanics, Vol. 762, Issue. , p. 196.

Koshel, Konstantin V. Ryzhov, Evgeny A. and Zhmur, Vladimir V. 2015. Effect of the vertical component of diffusion on passive scalar transport in an isolated vortex model. Physical Review E, Vol. 92, Issue. 5,

McKiver, William J. 2015. The Ellipsoidal Vortex: A Novel Approach to Geophysical Turbulence. Advances in Mathematical Physics, Vol. 2015, Issue. , p. 1.

Reinaud, Jean N. Dritschel, David G. and Carton, Xavier 2016. Interaction between a surface quasi-geostrophic buoyancy filament and an internal vortex. Geophysical & Astrophysical Fluid Dynamics, Vol. 110, Issue. 6, p. 461.

Ryzhov, Eugene A. and Koshel, Konstantin V. 2016. Resonance phenomena in a two-layer two-vortex shear flow. Chaos: An Interdisciplinary Journal of Nonlinear Science, Vol. 26, Issue. 11,

McKiver, William J. and Dritschel, David G. 2016. Balanced solutions for an ellipsoidal vortex in a rotating stratified flow. Journal of Fluid Mechanics, Vol. 802, Issue. , p. 333.

Arter, Wayne 2017. Beyond linear fields: the Lie–Taylor expansion. Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences, Vol. 473, Issue. 2197, p. 20160525.

Reinaud, J. N. Dritschel, D. G. and Carton, X. 2017. Interaction between a surface quasi-geostrophic buoyancy anomaly jet and internal vortices. Physics of Fluids, Vol. 29, Issue. 8,

Koshel, Konstantin V. and Ryzhov, Eugene A. 2017. Parametric resonance in the dynamics of an elliptic vortex in a periodically strained environment. Nonlinear Processes in Geophysics, Vol. 24, Issue. 1, p. 1.

Lilly, Jonathan 2018. Kinematics of a Fluid Ellipse in a Linear Flow. Fluids, Vol. 3, Issue. 1, p. 16.

Dritschel, David G. Böing, Steven J. Parker, Douglas J. and Blyth, Alan M. 2018. The moist parcel‐in‐cell method for modelling moist convection. Quarterly Journal of the Royal Meteorological Society, Vol. 144, Issue. 715, p. 1695.

Koshel, Konstantin V. Ryzhov, Eugene A. and Carton, Xavier J. 2019. Vortex Interactions Subjected to Deformation Flows: A Review. Fluids, Vol. 4, Issue. 1, p. 14.

Böing, Steven J. Dritschel, David G. Parker, Douglas J. and Blyth, Alan M. 2019. Comparison of the Moist Parcel‐in‐Cell (MPIC) model with large‐eddy simulation for an idealized cloud. Quarterly Journal of the Royal Meteorological Society, Vol. 145, Issue. 722, p. 1865.

McKiver, William J. 2020. Balanced ellipsoidal vortex at finite Rossby number. Geophysical & Astrophysical Fluid Dynamics, Vol. 114, Issue. 4-5, p. 453.

McKiver, William J. 2021. Balanced ellipsoidal vortex equilibria in a background shear flow at finite Rossby number. Journal of Fluid Mechanics, Vol. 926, Issue. ,

Santeva, E. K. Bashmachnikov, I. L. and Sokolovskiy, M. A. 2021. On the Stability of the Lofoten Vortex in the Norwegian Sea. Oceanology, Vol. 61, Issue. 3, p. 308.

Frey, Matthias Dritschel, David and Böing, Steven 2022. EPIC: The Elliptical Parcel-In-Cell method. Journal of Computational Physics: X, Vol. 14, Issue. , p. 100109.

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The motion of a fluid ellipsoid in a general linear background flow

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