Mixing and coherent structures in two-dimensional viscous flows
Abstract
We introduce a dynamical description based on a probability density of the vorticity in two-dimensional viscous flows such that the average vorticity evolves according to the Navier-Stokes equations. A time-dependent mixing index is defined and the class of probability densities that maximizes this index is studied. The time dependence of the Lagrange multipliers can be chosen in such a way that the masses associated with each vorticity value are conserved. When the masses are conserved then 1) the mixing index satisfies an H-theorem and 2) the mixing index is the time-dependent analogue of the entropy employed in the statistical mechanical theory of inviscid 2D flows [Miller, Weichman & Cross, Phys. Rev. A \textbf{45} (1992); Robert & Sommeria, Phys. Rev. Lett. \textbf{69}, 2776 (1992)]. Within this framework we also show how to reconstruct the probability density of the quasi-stationary coherent structures from the experimentally determined vorticity-stream function relations and we provide a connection between this probability density and an appropriate initial distribution.
Cite
@article{arxiv.physics/0702040,
title = {Mixing and coherent structures in two-dimensional viscous flows},
author = {H. W. Capel and R. A. Pasmanter},
journal= {arXiv preprint arXiv:physics/0702040},
year = {2010}
}