A predator-prey SIR type dynamics on large complete graphs with three phase transitions

Abstract

We are interested in a variation of the SIR (Susceptible/Infected/Recovered) dynamics on the complete graph, in which infected individuals may only spread to neighboring susceptible individuals at fixed rate λ>0 while recovered individuals may only spread to neighboring infected individuals at fixed rate 1. This is also a variant of the so-called chase-escape process introduced by Kordzakhia and then Bordenave & Ganesan. Our work is the first study of this dynamics on complete graphs. Starting with one infected and one recovered individuals on the complete graph with N+2 vertices, and stopping the process when one type of individuals disappears, we study the asymptotic behavior of the probability that the infection spreads to the whole graph as N→∞ and show that for λ∈ (0,1) (resp. for λ>1), the infection dies out (resp. does not die out) with probability tending to one as N→∞, and that the probability that the infection dies out tends to 1/2 for λ=1. We also establish limit theorems concerning the asymptotic state of the system in all regimes and show that two additional phase transitions occur in the subcritical phase λ∈ (0,1): at λ=1/2 the behavior of the expected number of remaining infected individuals changes, while at λ=( 5-1)/2 the behavior of the expected number of remaining recovered individuals changes. We also study the outbreak sizes of the infection, and show that the outbreak sizes are small if λ ∈(0,1/2], exhibit a power-law behavior for 1/2<λ<1, and are pandemic for λ≥ 1. Our method relies on different couplings: we first couple the dynamics with two independent Yule processes by using an Athreya-Karlin embedding, and then we couple the Yule processes with Poisson processes thanks to Kendall's representation of Yule processes.