Selective decay by Casimir dissipation in inviscid fluids

The problem of parameterizing the interactions of larger scales and smaller scales in fluid flows is addressed by considering a property of two-dimensional incompressible turbulence. The property we consider is selective decay, in which a Casimir of the ideal formulation (enstrophy in 2D flows, helicity in 3D flows) decays in time, while the energy stays essentially constant. This paper introduces a mechanism that produces selective decay by enforcing Casimir dissipation in fluid dynamics. This mechanism turns out to be related in certain cases to the numerical method of anticipated vorticity discussed in Sadourny and Basdevant [1981, 1985]. Several examples are given and a general theory of selective decay is developed that uses the Lie-Poisson structure of the ideal theory. A scale-selection operator allows the resulting modifications of the fluid motion equations to be interpreted in several examples as parameterizing the nonlinear, dynamical interactions between disparate scales. The type of modified fluid equation systems derived here may be useful in modelling turbulent geophysical flows where it is computationally prohibitive to rely on the slower, indirect effects of a realistic viscosity, such as in large-scale, coherent, oceanic flows interacting with much smaller eddies. Laboratoire de Météorologie Dynamique, École Normale Supérieure/CNRS, Paris, France. gaybalma@lmd.ens.fr Department of Mathematics, Imperial College, London SW7 2AZ, UK. d.holm@ic.ac.uk

[1]  R. Salmon,et al.  A general method for conserving quantities related to potential vorticity in numerical models , 2005 .

[2]  V. Arnold Sur la géométrie différentielle des groupes de Lie de dimension infinie et ses applications à l'hydrodynamique des fluides parfaits , 1966 .

[3]  W. Matthaeus,et al.  SELECTIVE DECAY HYPOTHESIS AT HIGH MECHANICAL AND MAGNETIC REYNOLDS NUMBERS * , 1980 .

[4]  V. Arnold Variational principle for three-dimensional steady-state flows of an ideal fluid , 1965 .

[5]  P. Gent,et al.  Eliassen–Palm Fluxes and the Momentum Equation in Non-Eddy-Resolving Ocean Circulation Models , 1996 .

[6]  Darryl D. Holm,et al.  Geometric gradient-flow dynamics with singular solutions , 2007, 0704.2369.

[7]  A. J. van der Schaft,et al.  Nonholonomic Mechanics and Control [Book Review] , 2005 .

[8]  S. Leibovich,et al.  A rational model for Langmuir circulations , 1976, Journal of Fluid Mechanics.

[9]  P. Mininni,et al.  Two examples from geophysical and astrophysical turbulence on modeling disparate scale interactions , 2009 .

[10]  Darryl D. Holm,et al.  The Euler–Poincaré Equations and Semidirect Products with Applications to Continuum Theories , 1998, chao-dyn/9801015.

[11]  B. Hoskins,et al.  On the use and significance of isentropic potential vorticity maps , 2007 .

[12]  P. Krishnaprasad,et al.  The Euler-Poincaré equations and double bracket dissipation , 1996 .

[13]  R. Rotunno,et al.  Ertel's Potential Vorticity in Unstratified Turbulence , 1994 .

[14]  R. Brockett Dynamical systems that sort lists, diagonalize matrices, and solve linear programming problems , 1991 .

[15]  Darryl D. Holm,et al.  Multiscale Turbulence Models Based on Convected Fluid Microstructure , 2012 .

[16]  M. McIntyre,et al.  On the Conservation and Impermeability Theorems for Potential Vorticity , 1990 .

[17]  Darryl D. Holm Geometric Mechanics - Part I: Dynamics And Symmetry , 2011 .

[18]  Darryl D. Holm Fluctuation effects on 3D Lagrangian mean and Eulerian mean fluid motion , 1999, chao-dyn/9903034.

[19]  Max Gunzburger,et al.  A Scale-Invariant Formulation of the Anticipated Potential Vorticity Method , 2010, 1010.2723.

[20]  Miroslav Grmela,et al.  Bracket formulation of dissipative fluid mechanics equations , 1984 .