First Passage Time in a Two-Layer System
Abstract
As a first step in the first passage problem for passive tracer in stratified porous media, we consider the case of a two-dimensional system consisting of two layers with different convection velocities. Using a lattice generating function formalism and a variety of analytic and numerical techniques, we calculate the asymptotic behavior of the first passage time probability distribution. We show analytically that the asymptotic distribution is a simple exponential in time for any choice of the velocities. The decay constant is given in terms of the largest eigenvalue of an operator related to a half-space Green's function. For the anti-symmetric case of opposite velocities in the layers, we show that the decay constant for system length crosses over from behavior in diffusive limit to behavior in the convective regime, where the crossover length is given in terms of the velocities. We also have formulated a general self-consistency relation, from which we have developed a recursive approach which is useful for studying the short time behavior.
Cite
@article{arxiv.cond-mat/9407057,
title = {First Passage Time in a Two-Layer System},
author = {Jysoo Lee and Joel Koplik},
journal= {arXiv preprint arXiv:cond-mat/9407057},
year = {2009}
}
Comments
LaTeX, 28 pages, 7 figures not included