Some partial results on the convergence of loop-erased random walk to SLE(2) in the natural parametrization

Abstract

We outline a strategy for showing convergence of loop-erased random walk on the $\mathbb{Z}^2$ square lattice to SLE(2), in the supremum norm topology that takes the time parametrization of the curves into account. The discrete curves are parametrized so that the walker moves at a constant speed determined by the lattice spacing, and the SLE(2) curve has the recently introduced natural time parametrization. Our strategy can be seen as an extension of the one used by Lawler, Schramm, and Werner to prove convergence modulo time parametrization. The crucial extra step is showing that the expected occupation measure of the discrete curve, properly renormalized by the chosen time parametrization, converges to the occupation density of the SLE(2) curve, the so-called SLE Green’s function. Although we do not prove this convergence, we rigorously establish some partial results in this direction including a new loop-erased random walk estimate.

Publication
J. Stat. Phys.
Tom Alberts
Tom Alberts
Associate Professor of Mathematics
University of Utah
Michael Kozdron
Michael Kozdron
Associate Professor of Mathematics
University of Regina

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