Susceptible-Infected Epidemics on Evolving Graphs at Critical Infection Rate
Abstract
Consider an SI process on a graph G where each S--I connection becomes I--I at rate λ. Here S and I stand for ``susceptible'' and ``infected'' respectively. The evoSI model is a modification of the SI model in which S--I edges are broken at rate and the ``S'' connects to a randomly chosen vertex. It is proven in Durrett and Yao [2022, Electron. J. Probab.] that, for the supercritical evoSI process on the configuration model, there exists a quantity depending on the first three moments of the degree distribution such that the sign of governs the continuity of the phase transition of the final epidemic size near the critical infection rate λc. In this paper, we consider the critical evoSI model on the configuration model, i.e., λ=λc. We show that, if >0, then the probability of a major outbreak starting from a single infected individual is Cn-1/3(1+o(1)) for some explicit constant C>0, where n is the size of the graph. On the contrary, if <0, then this probability is o(n-1/3). The case <0 is reminiscent of the critical graphs, where the probability for the size of the largest component to be of order n decays exponentially in n.
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