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New critical exponent inequalities for percolation and the random cluster model

Tom Hutchcroft

2020Probability and Mathematical Physics24 citationsDOIOpen Access PDF

Abstract

We apply a variation on the methods of Duminil-Copin, Raoufi, and Tassion (Ann. of Math. (2) 189:1 (2019), 75–99) to establish a new differential inequality applying to both Bernoulli percolation and the Fortuin–Kasteleyn random cluster model. This differential inequality has a similar form to that derived for Bernoulli percolation by Menshikov (Dokl. Akad. Nauk 288:6 (1986), 1308–1311) but with the important difference that it describes the distribution of the volume of a cluster rather than of its radius. We apply this differential inequality to prove the following: 
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\n1. The critical exponent inequalities γ ≤ δ − 1 and Δ ≤ γ + 1 hold for percolation and the random cluster model on any transitive graph. These inequalities are new even in the context of Bernoulli percolation on Z^d, and are saturated in mean-field for Bernoulli percolation and for the random cluster model with q ∈ [1,2). 
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\n2. The volume of a cluster has an exponential tail in the entire subcritical phase of the random cluster model on any transitive graph. This proof also applies to infinite-range models, where the result is new even in the Euclidean setting.

Topics & Concepts

MathematicsBernoulli's principlePercolation (cognitive psychology)Cluster (spacecraft)Statistical physicsContext (archaeology)ExponentBernoulli schemePercolation critical exponentsDirected percolationContinuum percolation theoryBernoulli processBernoulli distributionRandom graphExponential functionPercolation thresholdCritical exponentDiscrete mathematicsDistribution (mathematics)CombinatoricsExponential distributionDifferential (mechanical device)Mathematical analysisCluster expansionPercolation theoryStochastic processes and statistical mechanicsRandom Matrices and ApplicationsTheoretical and Computational Physics