Random walk in a birth-and-death dynamical environment
Abstract
We consider a particle moving in continuous time as a Markov jump process; its discrete chain is given by an ordinary random walk on Zd , and its jump rate at ( x,t) is given by a fixed function of the state of a birth-and-death (BD) process at \ x on time t; BD processes at different sites are independent and identically distributed, and is assumed non increasing and vanishing at infinity. We derive a LLN and a CLT for the particle position when the environment is 'strongly ergodic'. In the absence of a viable uniform lower bound for the jump rate, we resort instead to stochastic domination, as well as to a subadditive argument to control the time spent by the particle to give n jumps; and we also impose conditions on the initial (product) environmental initial distribution. We also present results on the asymptotics of the environment seen by the particle (under different conditions on ).
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