English

Quantitative estimates in stochastic homogenization for correlated coefficient fields

Analysis of PDEs 2022-02-09 v1 Probability

Abstract

This paper is about the homogenization of linear elliptic operators in divergence form with stationary random coefficients that have only slowly decaying correlations. It deduces optimal estimates of the homogenization error from optimal growth estimates of the (extended) corrector. In line with the heuristics, there are transitions at dimension d=2d=2, and for a correlation-decay exponent β=2\beta=2; we capture the correct power of logarithms coming from these two sources of criticality. The decay of correlations is sharply encoded in terms of a multiscale logarithmic Sobolev inequality (LSI) for the ensemble under consideration --- the results would fail if correlation decay were encoded in terms of an α\alpha-mixing condition. Among other ensembles popular in modelling of random media, this class includes coefficient fields that are local transformations of stationary Gaussian fields. The optimal growth of the corrector ϕ\phi is derived from bounding the size of spatial averages F=gϕF=\int g\cdot\nabla\phi of its gradient. This in turn is done by a (deterministic) sensitivity estimate of FF, that is, by estimating the functional derivative Fa\frac{\partial F}{\partial a} of FF w.~r.~t.~the coefficient field aa. Appealing to the LSI in form of concentration of measure yields a stochastic estimate on FF. The sensitivity argument relies on a large-scale Schauder theory for the heterogeneous elliptic operator a-\nabla\cdot a\nabla. The treatment allows for non-symmetric aa and for systems like linear elasticity.

Keywords

Cite

@article{arxiv.1910.05530,
  title  = {Quantitative estimates in stochastic homogenization for correlated coefficient fields},
  author = {Antoine Gloria and Stefan Neukamm and Felix Otto},
  journal= {arXiv preprint arXiv:1910.05530},
  year   = {2022}
}

Comments

Companion article of arXiv:1409.2678

R2 v1 2026-06-23T11:41:50.216Z