English

From homogenization to averaging in cellular flows

Analysis of PDEs 2015-03-19 v2

Abstract

We consider an elliptic eigenvalue problem with a fast cellular flow of amplitude AA, in a two-dimensional domain with L2L^2 cells. For fixed AA, and LL \to \infty, the problem homogenizes, and has been well studied. Also well studied is the limit when LL is fixed, and AA \to \infty. In this case the solution equilibrates along stream lines. In this paper, we show that if \textit{both} AA \to \infty and LL \to \infty, then a transition between the homogenization and averaging regimes occurs at AL4A \approx L^4. When AL4A\gg L^4, the principal Dirichlet eigenvalue is approximately constant. On the other hand, when AL4A\ll L^4, the principal eigenvalue behaves like σˉ(A)/L2{\bar \sigma(A)}/L^2, where σˉ(A)AI\bar \sigma(A) \approx \sqrt{A} I is the effective diffusion matrix. A similar transition is observed for the solution of the exit time problem. The proof in the homogenization regime involves bounds on the second correctors. Miraculously, if the slow profile is quadratic, these estimates can be obtained using drift independent LpLL^p \to L^\infty estimates for elliptic equations with an incompressible drift. This provides effective sub and super-solutions for our problem.

Keywords

Cite

@article{arxiv.1108.0074,
  title  = {From homogenization to averaging in cellular flows},
  author = {Gautam Iyer and Tomasz Komorowski and Alexei Novikov and Lenya Ryzhik},
  journal= {arXiv preprint arXiv:1108.0074},
  year   = {2015}
}

Comments

v2: This time the paper is really here. (ArXiv mysteriously only kept the figures in v1, but may have retroactively fixed it now). 29 pages, 7 figures

R2 v1 2026-06-21T18:44:17.408Z