Long-range epidemic spreading in a random environment

Abstract

Modeling long-range epidemic spreading in a random environment, we consider a quenched disordered, d-dimensional contact process with infection rates decaying with the distance as 1/rd+σ. We study the dynamical behavior of the model at and below the epidemic threshold by a variant of the strong-disorder renormalization group method and by Monte Carlo simulations in one and two spatial dimensions. Starting from a single infected site, the average survival probability is found to decay as P(t) t-d/z up to multiplicative logarithmic corrections. Below the epidemic threshold, a Griffiths phase emerges, where the dynamical exponent z varies continuously with the control parameter and tends to zc=d+σ as the threshold is approached. At the threshold, the spatial extension of the infected cluster (in surviving trials) is found to grow as R(t) t1/zc with a multiplicative logarithmic correction, and the average number of infected sites in surviving trials is found to increase as Ns(t) ( t) with =2 in one dimension.