Tightness of exponential metrics for log-correlated Gaussian fields in arbitrary dimension

Abstract

We prove the tightness of a natural approximation scheme for an analog of the Liouville quantum gravity metric on Rd for arbitrary d≥ 2. More precisely, let \hn\n≥ 1 be a suitable sequence of Gaussian random functions which approximates a log-correlated Gaussian field on Rd. Consider the family of random metrics on Rd obtained by weighting the lengths of paths by e hn, where > 0 is a parameter. We prove that if belongs to the subcritical phase (which is defined by the condition that the distance exponent Q() is greater than 2d), then after appropriate re-scaling, these metrics are tight and that every subsequential limit is a metric on Rd which induces the Euclidean topology. We include a substantial list of open problems.

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