Self-avoiding walk on the hypercube
Abstract
We study the number of -step self-avoiding walks on the -dimensional hypercube, and identify an -dependent \emph{connective constant} and amplitude such that is for all and , and is asymptotically as long as for any fixed . We refer to the regime as the \emph{dilute phase}. We discuss conjectures concerning different behaviours of when reaches and exceeds , corresponding to a critical window and a dense phase. In addition, we prove that the connective constant has an asymptotic expansion to all orders in , with integer coefficients, and we compute the first five coefficients . The proofs are based on generating function and Tauberian methods implemented via the lace expansion, for which an introductory account is provided.
Keywords
Cite
@article{arxiv.2108.03682,
title = {Self-avoiding walk on the hypercube},
author = {Gordon Slade},
journal= {arXiv preprint arXiv:2108.03682},
year = {2022}
}
Comments
45 pages. Minor changes. Final version. To appear in Random Structures and Algorithms