Constrained-degree percolation on the hypercubic lattice: uniqueness and some of its consequences

Abstract

We consider the constrained-degree percolation (CDP) model on the hypercubic lattice. This is a continuous-time percolation model defined by a sequence (Ue)e∈Ed of i.i.d. uniform random variables and a positive integer k, referred to as the constraint. The model evolves as follows: each edge e attempts to open at a random time Ue, independently of all other edges. It succeeds if, at time Ue, both of its end-vertices have degrees strictly smaller than k. It is known hartarsky2022weakly that this model undergoes a phase transition when d≥3 for most nontrivial values of k. In this work, we prove that, for any fixed constraint, the number of infinite clusters at any time t∈[0,1) is almost surely either 0 or 1. This uniqueness result implies the continuity of the percolation function in the supercritical regime, t∈(tc,1), where tc denotes the percolation critical threshold. The proof relies on a key time-regularity property of the model: the law of the process is continuous with respect to time for local events. In fact, we establish differentiability in time, thereby extending the result of SSS to the CDP setting.

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