# Self-avoiding walks and connective constants

**Authors:** Geoffrey R. Grimmett, Zhongyang Li

arXiv: 1704.05884 · 2019-07-15

## TL;DR

This paper surveys the properties and bounds of the connective constant for self-avoiding walks on various graphs, exploring its relationship with graph structure, transformations, and group presentations.

## Contribution

It introduces new inequalities, discusses the impact of graph modifications on the connective constant, and examines the existence of graph height functions and their implications.

## Key findings

- Bounds for rom vertex-degree and girth
- Strict inequalities for or graph variations
- Connectivity of rom group relators and generators

## Abstract

The connective constant $\mu(G)$ of a quasi-transitive graph $G$ is the asymptotic growth rate of the number of self-avoiding walks (SAWs) on $G$ from a given starting vertex. We survey several aspects of the relationship between the connective constant and the underlying graph $G$.   $\bullet$ We present upper and lower bounds for $\mu$ in terms of the vertex-degree and girth of a transitive graph.   $\bullet$ We discuss the question of whether $\mu\ge\phi$ for transitive cubic graphs (where $\phi$ denotes the golden mean), and we introduce the Fisher transformation for SAWs (that is, the replacement of vertices by triangles).   $\bullet$ We present strict inequalities for the connective constants $\mu(G)$ of transitive graphs $G$, as $G$ varies.   $\bullet$ As a consequence of the last, the connective constant of a Cayley graph of a finitely generated group decreases strictly when a new relator is added, and increases strictly when a non-trivial group element is declared to be a further generator.   $\bullet$ We describe so-called graph height functions within an account of "bridges" for quasi-transitive graphs, and indicate that the bridge constant equals the connective constant when the graph has a unimodular graph height function.   $\bullet$ A partial answer is given to the question of the locality of connective constants, based around the existence of unimodular graph height functions.   $\bullet$ Examples are presented of Cayley graphs of finitely presented groups that possess graph height functions (that are, in addition, harmonic and unimodular), and that do not.   $\bullet$ The review closes with a brief account of the "speed" of SAW.

## Full text

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## Figures

4 figures with captions in the complete paper: https://tomesphere.com/paper/1704.05884/full.md

## References

74 references — full list in the complete paper: https://tomesphere.com/paper/1704.05884/full.md

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Source: https://tomesphere.com/paper/1704.05884