A higher-order large-scale regularity theory for random elliptic operators
Abstract
We develop a large-scale regularity theory of higher order for divergence-form elliptic equations with heterogeneous coefficient fields in the context of stochastic homogenization. The large-scale regularity of -harmonic functions is encoded by Liouville principles: The space of -harmonic functions that grow at most like a polynomial of degree has the same dimension as in the constant-coefficient case. This result can be seen as the qualitative side of a large-scale -regularity theory, which in the present work is developed in the form of a corresponding -"excess decay" estimate: For a given -harmonic function on a ball , its energy distance on some ball to the above space of -harmonic functions that grow at most like a polynomial of degree has the natural decay in the radius above some minimal radius . Though motivated by stochastic homogenization, the contribution of this paper is of purely deterministic nature: We work under the assumption that for the given realization of the coefficient field, the couple of scalar and vector potentials of the harmonic coordinates, where is the usual corrector, grows sublinearly in a mildly quantified way. We then construct "th-order correctors" and thereby the space of -harmonic functions that grow at most like a polynomial of degree , establish the above excess decay and then the corresponding Liouville principle.
Cite
@article{arxiv.1503.07578,
title = {A higher-order large-scale regularity theory for random elliptic operators},
author = {Julian Fischer and Felix Otto},
journal= {arXiv preprint arXiv:1503.07578},
year = {2015}
}
Comments
37 pages; revised version, now includes the regularity theory of arbitrary order