English

Subdiffusive heat-kernel decay in four-dimensional i.i.d. random conductance models

Probability 2012-11-07 v2 Mathematical Physics math.MP

Abstract

We study the diagonal heat-kernel decay for the four-dimensional nearest-neighbor random walk (on Z4\Z^4) among i.i.d. random conductances that are positive, bounded from above but can have arbitrarily heavy tails at zero. It has been known that the quenched return probability \cmssPω2n(0,0)\cmss P_\omega^{2n}(0,0) after 2n2n steps is at most C(ω)n2lognC(\omega) n^{-2} \log n, but the best lower bound till now has been C(ω)n2C(\omega) n^{-2}. Here we will show that the logn\log n term marks a real phenomenon by constructing an environment, for each sequence λn\lambda_n\to\infty, such that \cmssPω2n(0,0)C(ω)log(n)n2/λn, \cmss P_\omega^{2n}(0,0)\ge C(\omega)\log(n)n^{-2}/\lambda_n, with C(ω)>0C(\omega)>0 a.s., along a deterministic subsequence of nn's. Notably, this holds simultaneously with a (non-degenerate) quenched invariance principle. As for the d5d\ge5 cases studied earlier, the source of the anomalous decay is a trapping phenomenon although the contribution is in this case collected from a whole range of spatial scales.

Keywords

Cite

@article{arxiv.1010.5542,
  title  = {Subdiffusive heat-kernel decay in four-dimensional i.i.d. random conductance models},
  author = {Marek Biskup and Omar Boukhadra},
  journal= {arXiv preprint arXiv:1010.5542},
  year   = {2012}
}

Comments

28 pages, version to appear in J. Lond. Math. Soc

R2 v1 2026-06-21T16:34:36.706Z