The Diffusion Approximation in Turbulent Two-Particle Dispersion
Abstract
We solve an inverse problem for fluid particle pair-statistics: we show that a time sequence of probability density functions (PDF's) of separations can be exactly reproduced by solving the diffusion equation with a suitable time-dependent diffusivity. The diffusivity tensor is given by a time-integral of a conditional Lagrangian velocity structure-function, weighted by a ratio of PDF's. Physical hypotheses for hydrodynamic turbulence (sweeping, short memory, mean-field) yield simpler integral formulas, including one of Kraichnan and Lundgren. We evaluate the latter using a spacetime database from a numerical Navier-Stokes solution for driven turbulence. This diffusion theory reproduces PDF's well at rms separations, but growth rate of mean-square dispersion is overpredicted due to neglect of memory effects. More general applications of our approach are sketched.
Cite
@article{arxiv.1306.6388,
title = {The Diffusion Approximation in Turbulent Two-Particle Dispersion},
author = {Gregory L. Eyink and Damien Benveniste},
journal= {arXiv preprint arXiv:1306.6388},
year = {2015}
}
Comments
5 pages, 4 figures