Chemical distance in the supercritical phase of planar Gaussian fields
Abstract
Our study concerns the large scale geometry of the excursion set of planar random fields: E = x ∈ R 2 |f (x) -, where ∈ R is a real parameter and f is a continuous, stationary, centered, planar Gaussian field satisfying some regularity assumptions (in particular, this study applies to the planar Bargmann-Fock field). It is already known that under those hypotheses there is a phase transition at c = 0. When > 0, we are in a supercritical regime and almost surely E has a unique unbounded connected component. We prove that in this supercritical regime, whenever two points are in the same connected components of E then, with high probability, the chemical distance (the length of the shortest path in E between these points) is close to the Euclidean distance between those two points Contents
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