Quenched Invariance Principle for a class of random conductance models with long-range jumps

Abstract

We study random walks on Zd among random conductances \Cxy x,y∈ Zd\ that permit jumps of arbitrary length. Apart from joint ergodicity with respect to spatial shifts, we assume only that the nearest-neighbor conductances are uniformly positive and that Σx∈ Zd C0x|x|2 is integrable. Our focus is on the Quenched Invariance Principle (QIP) which we establish in all d3 by a combination of corrector methods and heat-kernel technology. In particular, a QIP thus holds for random walks on long-range percolation graphs with exponents larger than d+2 in all d3, provided all nearest-neighbor edges are present. We then show that, for long-range percolation with exponents between d+2 and 2d, the corrector fails to be sublinear everywhere. Similar examples are constructed also for nearest-neighbor, ergodic conductances in d4 under the conditions close to, albeit not exactly, complementary to those of the recent work of S. Andres, M. Slowik and J.-D. Deuschel.