Statistical mechanics of two-dimensional Euler flows and minimum enstrophy states

A. Naso; P. H. Chavanis; B. Dubrulle

doi:10.1140/epjb/e2010-00269-0

2021 Impact factor 1.398

Condensed Matter and Complex Systems

Eur. Phys. J. B 77, 187-212 (2010)
https://doi.org/10.1140/epjb/e2010-00269-0

Statistical mechanics of two-dimensional Euler flows and minimum enstrophy states

A. Naso¹^,2, P. H. Chavanis³^a and B. Dubrulle²

¹ Laboratoire de Physique, École Normale Supérieure de Lyon and CNRS (UMR 5672), 46 allée d'Italie, 69007 Lyon, France
² SPEC/IRAMIS/CEA Saclay, and CNRS (URA 2464), 91191 Gif-sur-Yvette Cedex, France
³ Laboratoire de Physique Théorique (IRSAMC), CNRS and UPS, Université de Toulouse, 31062 Toulouse, France

Corresponding author: ^a chavanis@irsamc.ups-tlse.fr

Received: 6 November 2009
Revised: 29 June 2010
Published online: 22 September 2010

Abstract

A simplified thermodynamic approach of the incompressible 2D Euler equation is considered based on the conservation of energy, circulation and microscopic enstrophy. Statistical equilibrium states are obtained by maximizing the Miller-Robert-Sommeria (MRS) entropy under these sole constraints. We assume that these constraints are selected by properties of forcing and dissipation. We find that the vorticity fluctuations are Gaussian while the mean flow is characterized by a linear relationship. Furthermore, we prove that the maximization of entropy at fixed energy, circulation and microscopic enstrophy is equivalent to the minimization of macroscopic enstrophy at fixed energy and circulation. This provides a justification of the minimum enstrophy principle from statistical mechanics when only the microscopic enstrophy is conserved among the infinite class of Casimir constraints. Relaxation equations towards the statistical equilibrium state are derived. These equations can serve as numerical algorithms to determine maximum entropy or minimum enstrophy states. We use these relaxation equations to study geometry induced phase transitions in rectangular domains. In particular, we illustrate with the relaxation equations the transition between monopoles and dipoles predicted by Chavanis and Sommeria [J. Fluid Mech. 314, 267 (1996)]. We take into account stable as well as metastable states and show that metastable states are robust and have negative specific heats. This is the first evidence of negative specific heats in that context. We also argue that saddle points of entropy can be long-lived and play a role in the dynamics because the system may not spontaneously generate the perturbations that destabilize them.