English

A Localized Diffusive Time Exponent for Compact Metric Spaces

Metric Geometry 2017-11-03 v2

Abstract

We provide a definition of a new critical exponent β\beta that has the interpretation of a type of local walk dimension, and may be defined on any compact metric space. We then specialize to the case of random walks that jump uniformly in metric balls with respect to a given Borel measure of full support. We use the local exponent β\beta as a local time scaling exponent to re-normalize the time scale and produce approximating continuous time walks. We show a Faber-Krahn type inequality λ1,r(B)cRβ(x0),\lambda_{1,r}(B)\geq \frac{c}{R^{\beta(x_0)}}, where cc is a constant independent of rr and x0x_0 and where λ1,r(B)\lambda_{1,r}(B) is the bottom of the spectrum of the generator for the re-normalized continuous time walk at stage rr killed outside of B=BR(x0).B=B_R(x_0). In addition, we examine the local Hausdorff dimension α.\alpha. We show that any variable Ahlfors QQ-regular measure is strongly equivalent to the local Hausdorff measure and that Q=α.Q=\alpha. We also provide new examples of variable dimensional spaces, including a variable dimensional Sierpinski carpet.

Keywords

Cite

@article{arxiv.1710.07872,
  title  = {A Localized Diffusive Time Exponent for Compact Metric Spaces},
  author = {John Dever},
  journal= {arXiv preprint arXiv:1710.07872},
  year   = {2017}
}
R2 v1 2026-06-22T22:21:39.503Z