Abstract
We study the supercritical contact process on Galton-Watson trees and periodic trees. We prove that if the contact process survives weakly then it dominates a supercritical Crump-Mode-Jagers branching process. Hence the number of infected sites grows exponentially fast. As a consequence we conclude that the contact process dies out at the critical value $\lambda_1$ for weak survival, and the survival probability $p(\lambda)$ is continuous with respect to the infection rate $\lambda$. Applying this fact, we show the contact process on a general periodic tree experiences two phase transitions in the sense that $\lambda_1<\lambda_2$, which confirms a conjecture of Stacey's \cite{Stacey}. We also prove that if the contact process survives strongly at $\lambda$ then it survives strongly at a $\lambda'<\lambda$, which implies that the process does not survive strongly at the critical value $\lambda_2$ for strong survival.
Highlights
Harris [6] introduced the contact process on Zd in 1974, which has been extensively studied since
The contact process can be defined on any graph as follows: infected sites become healthy at rate 1, while healthy sites become infected at rate λ times the number of infected neighbors
Exponential growth and continuous phase transitions for the contact process on trees where ξt0 denotes the contact process on the tree starting from only the root infected
Summary
Harris [6] introduced the contact process on Zd in 1974, which has been extensively studied since . The contact process on a graph is usually viewed as a model that describes the spread of an infection. The contact process is said to survive weakly if the process survives but the root 0 is infected for finitely many times almost surely, and survive strongly if the root 0 is infected for infinitely many times with positive probability. It is natural to guess that the contact process dies out at λ1 and does not survive strongly at λ2. This is true for the contact process on a d-regular tree Td where each vertex has degree d + 1. Properties of φ(ρ) help us obtain a lot of detailed information about the behavior of the contact process on regular trees
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