Functional CLT for Random Walk Among Bounded Random Conductances

Marek Biskup (UCLA)
Timothy M Prescott (UCLA)

Abstract


We consider the nearest-neighbor simple random walk on $Z^d$, $d\ge2$, driven by a field of i.i.d. random nearest-neighbor conductances $\omega_{xy}\in[0,1]$. Apart from the requirement that the bonds with positive conductances percolate, we pose no restriction on the law of the $\omega$'s. We prove that, for a.e. realization of the environment, the path distribution of the walk converges weakly to that of non-degenerate, isotropic Brownian motion. The quenched functional CLT holds despite the fact that the local CLT may fail in $d\ge5$ due to anomalously slow decay of the probability that the walk returns to the starting point at a given time.

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Pages: 1323-1348

Publication Date: October 25, 2007

DOI: 10.1214/EJP.v12-456

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