Moment asymptotics for branching random walks in random environment

Abstract

We consider the long-time behaviour of a branching random walk in random environment on the lattice d. The migration of particles proceeds according to simple random walk in continuous time, while the medium is given as a random potential of spatially dependent killing/branching rates. The main objects of our interest are the annealed moments < mnp > , i.e., the p-th moments over the medium of the n-th moment over the migration and killing/branching, of the local and global population sizes. For n=1, this is well-understood GM98, as m1 is closely connected with the parabolic Anderson model. For some special distributions, A00 extended this to n≥2, but only as to the first term of the asymptotics, using (a recursive version of) a Feynman-Kac formula for mn. In this work we derive also the second term of the asymptotics, for a much larger class of distributions. In particular, we show that < mnp > and < m1np > are asymptotically equal, up to an error o(t). The cornerstone of our method is a direct Feynman-Kac-type formula for mn, which we establish using the spine techniques developed in HR11.