English

The Lightning Model

Probability 2021-10-26 v3

Abstract

We introduce a non-standard model for percolation on the integer lattice Z2\mathbb Z^2. Randomly assign to each vertex aZ2a \in \mathbb Z^2 a potential, denoted ϕa\phi_a, chosen independently and uniformly from the interval [0,1][0, 1]. For fixed ϵ[0,1]\epsilon \in [0,1], draw a directed edge from vertex aa to a nearest-neighbor vertex bb if ϕb<ϕa+ϵ\phi_b < \phi_a + \epsilon, yielding a directed subgraph of the infinite directed graph G\overrightarrow{G} whose vertex set is Z2\mathbb Z^2, with nearest-neighbor edge set. We define notions of weak and strong percolation for our model, and observe that when ϵ=0\epsilon = 0 the model fails to percolate weakly, while for ϵ=1\epsilon = 1 it percolates strongly. We show that there is a positive ϵ0\epsilon_0 so that for 0ϵϵ00 \le \epsilon \le \epsilon_0, the model fails to percolate weakly, and that when ϵ>psite\epsilon > p_\text{site}, the critical probability for standard site percolation in Z2\mathbb Z^2, the model percolates strongly. We study the number of infinite strongly connected clusters occurring in a typical configuration. We show that for these models of percolation on directed graphs, there are some subtle issues that do not arise for undirected percolation. Although our model does not have the finite energy property, we are able to show that, as in the standard model, the number of infinite strongly connected clusters is almost surely 0, 1 or \infty.

Keywords

Cite

@article{arxiv.2101.09383,
  title  = {The Lightning Model},
  author = {James Campbell and Alexandra Deane and Anthony Quas},
  journal= {arXiv preprint arXiv:2101.09383},
  year   = {2021}
}

Comments

To appear: J. Theor. Prob

R2 v1 2026-06-23T22:26:32.605Z