English

Two-dimensional SIR epidemics with long range infection

Statistical Mechanics 2015-06-16 v1

Abstract

We extend a recent study of susceptible-infected-removed epidemic processes with long range infection (referred to as I in the following) from 1-dimensional lattices to lattices in two dimensions. As in I we use hashing to simulate very large lattices for which finite size effects can be neglected, in spite of the assumed power law p(x)xσ2p({\bf x})\sim |{\bf x}|^{-\sigma-2} for the probability that a site can infect another site a distance vector x{\bf x} apart. As in I we present detailed results for the critical case, for the supercritical case with σ=2\sigma = 2, and for the supercritical case with 0<σ<20< \sigma < 2. For the latter we verify the stretched exponential growth of the infected cluster with time predicted by M. Biskup. For σ=2\sigma=2 we find generic power laws with σ\sigma-dependent exponents in the supercritical phase, but no Kosterlitz-Thouless (KT) like critical point as in 1-d. Instead of diverging exponentially with the distance from the critical point, the correlation length increases with an inverse power, as in an ordinary critical point. Finally we study the dependence of the critical exponents on σ\sigma in the regime 0<σ<20<\sigma <2, and compare with field theoretic predictions. In particular we discuss in detail whether the critical behavior for σ\sigma slightly less than 2 is in the short range universality class, as conjectured recently by F. Linder {\it et al.}. As in I we also consider a modified version of the model where only some of the contacts are long range, the others being between nearest neighbors. If the number of the latter reaches the percolation threshold, the critical behavior is changed but the supercritical behavior stays qualitatively the same.

Keywords

Cite

@article{arxiv.1305.5940,
  title  = {Two-dimensional SIR epidemics with long range infection},
  author = {Peter Grassberger},
  journal= {arXiv preprint arXiv:1305.5940},
  year   = {2015}
}

Comments

14 pages, including 29 figures

R2 v1 2026-06-22T00:22:30.523Z