SIR Epidemics on Evolving Erdos-R\'enyi Graphs

Abstract

In the standard SIR model, infected vertices infect their neighbors at rate λ independently across each edge. They also recover at rate γ. In this work we consider the SIR-ω model where the graph structure itself co-evolves with the SIR dynamics. Specifically, S-I connections are broken at rate ω. Then, with probability α, S rewires this edge to another uniformly chosen vertex; and with probability 1-α, this edge is simply dropped. When α=1 the SIR-ω model becomes the evoSIR model. Jiang et al. proved in DOMath that the probability of an outbreak in the evoSIR model converges to 0 as λ approaches the critical infection rate λc. On the other hand, numerical experiments in DOMath revealed that, as λ λc, (conditionally on an outbreak) the fraction of infected vertices may not converge to 0, which is referred to as a discontinuous phase transition. In BB Ball and Britton give two (non-matching) conditions for continuous and discontinuous phase transitions for the fraction of infected vertices in the SIR-ω model. In this work, we obtain a necessary and sufficient condition for the emergence of a discontinuous phase transition of the final epidemic size of the SIR-ω model on \, graphs, thus closing the gap between these two conditions.