The Contact Process on Random Graphs and Galton-Watson Trees

Abstract

The key to our investigation is an improved (and in a sense sharp) understanding of the survival time of the contact process on star graphs. Using these results, we show that for the contact process on Galton-Watson trees, when the offspring distribution (i) is subexponential the critical value for local survival λ2=0 and (ii) when it is geometric(p) we have λ2 Cp, where the Cp are much smaller than previous estimates. We also study the critical value λc(n) for "prolonged persistence" on graphs with n vertices generated by the configuration model. In the case of power law and stretched exponential distributions where it is known λc(n) 0 we give estimates on the rate of convergence. Physicists tell us that λc(n) 1/(n) where (n) is the maximum eigenvalue of the adjacency matrix. Our results show that this is not correct.