Random walk with barycentric self-interaction

Abstract

We study the asymptotic behaviour of a d-dimensional self-interacting random walk Xn (n = 1,2,...) which is repelled or attracted by the centre of mass Gn = n-1 Σi=1n Xi of its previous trajectory. The walk's trajectory (X1,...,Xn) models a random polymer chain in either poor or good solvent. In addition to some natural regularity conditions, we assume that the walk has one-step mean drift directed either towards or away from its current centre of mass Gn and of magnitude \| Xn - Gn \|-β for β ≥ 0. When β <1 and the radial drift is outwards, we show that Xn is transient with a limiting (random) direction and satisfies a super-diffusive law of large numbers: n-1/(1+β) Xn converges almost surely to some random vector. When β ∈ (0,1) there is sub-ballistic rate of escape. For β ≥ 0 we give almost-sure bounds on the norms \|Xn\|, which in the context of the polymer model reveal extended and collapsed phases. Analysis of the random walk, and in particular of Xn - Gn, leads to the study of real-valued time-inhomogeneous non-Markov processes Zn on [0,∞) with mean drifts at x given approximately by x-β - (x/n), where β ≥ 0 and ∈ . The study of such processes is a time-dependent variation on a classical problem of Lamperti; moreover, they arise naturally in the context of the distance of simple random walk on d from its centre of mass, for which we also give an apparently new result. We give a recurrence classification and asymptotic theory for processes Zn just described, which enables us to deduce the complete recurrence classification (for any β ≥ 0) of Xn - Gn for our self-interacting walk.