Bounding the number of self-avoiding walks: Hammersley-Welsh with polygon insertion

Abstract

Let cn = cn(d) denote the number of self-avoiding walks of length n starting at the origin in the Euclidean nearest-neighbour lattice Zd. Let μ = n cn1/n denote the connective constant of Zd. In 1962, Hammersley and Welsh [HW62] proved that, for each d ≥ 2, there exists a constant C > 0 such that cn ≤ (C n1/2) μn for all n ∈ N. While it is anticipated that cn μ-n has a power-law growth in n, the best known upper bound in dimension two has remained of the form n1/2 inside the exponential. The natural first improvement to demand for a given planar lattice is a bound of the form cn ≤ (C n1/2 - ε)μn, where μ denotes the connective constant of the lattice in question. We derive a bound of this form for two such lattices, for an explicit choice of ε > 0 in each case. For the hexagonal lattice H, the bound is proved for all n ∈ N; while for the Euclidean lattice Z2, it is proved for a set of n ∈ N of limit supremum density equal to one. A power-law upper bound on cn μ-n for H is also proved, contingent on a non-quantitative assertion concerning this lattice's connective constant.