Anomalous scaling law for the two-dimensional Gaussian free field
Abstract
We consider the Gaussian free field on Z2 at large spatial scales N and give sharp bounds on the probability θ(a,N) that the radius of a finite cluster in the excursion set \ ≥ a\ on the corresponding metric graph is macroscopic. We prove a scaling law for this probability, by which θ(a,N) transitions from fractional logarithmic decay for near-critical parameters (a,N) to polynomial decay in the off-critical regime. The transition occurs across a certain scaling window determined by a correlation length scale , which is such that θ(a,N) θ(0,)(N)-τ for typical heights a as N/ diverges, with an explicit exponent τ that we identify in the process. This is in stark contrast with recent results from arXiv:2101.02200 and arXiv:2312.10030 in dimension three, where similar observables are shown to follow regular scaling laws, with polynomial decay at and near criticality, and rapid decay in N/ away from it.
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