Critical parameters of germ-monotone families of branching random walks

Abstract

We introduce a broad class of families of branching random walks on a countable set X, which we refer to as germ-monotone branching random walks (GMBRWs). The processes in each family are parametrized by a positive parameter λ>0, which controls the overall reproductive speed, and they are monotonically increasing in λ with respect to the germ order, a notion that extends classical stochastic domination. This framework encompasses a wide range of models, including classical continuous-time branching random walks, as well as discrete-time counterparts of certain non-Markovian processes such as ageing branching random walks. We define a general notion of critical parameter λ(A) associated with each subset A ⊂eq X, which serves as a threshold separating almost sure extinction in A from positive probability of survival in A. This unifies and extends the classical global and local critical parameters λw and λs, which can be recovered as special cases. We then investigate how modifications of the reproduction laws, either on a finite set or on a more general subset of X, affect these critical parameters. Our results extend earlier contributions in the literature.