The critical fugacity for surface adsorption of self-avoiding walks on the honeycomb lattice is $1+\sqrt{2}$

TL;DR

This paper proves the conjectured critical surface fugacity for self-avoiding walks on the honeycomb lattice by extending Smirnov's identity to include boundary interactions, confirming a long-standing theoretical prediction.

Contribution

It generalizes Smirnov's identity to a half-plane model with surface fugacity and proves the conjectured critical value for SAWs interacting with a surface.

Findings

Confirmed the conjectured critical surface fugacity y_c=1+√2 for SAWs.

Extended Smirnov's identity to models with boundary interactions.

Demonstrated the generating function of self-avoiding bridges tends to zero at criticality.

Abstract

In 2010, Duminil-Copin and Smirnov proved a long-standing conjecture of Nienhuis, made in 1982, that the growth constant of self-avoiding walks on the hexagonal (a.k.a. honeycomb) lattice is $\mu=\sqrt{2+\sqrt{2}}.$ A key identity used in that proof was later generalised by Smirnov so as to apply to a general O(n) loop model with $n\in [-2,2]$ (the case $n=0$ corresponding to SAWs). We modify this model by restricting to a half-plane and introducing a surface fugacity $y$ associated with boundary sites (also called surface sites), and obtain a generalisation of Smirnov's identity. The critical value of the surface fugacity was conjectured by Batchelor and Yung in 1995 to be $y_{\rm c}=1+2/\sqrt{2-n}.$ This value plays a crucial role in our generalized identity, just as the value of growth constant did in Smirnov's identity. For the case $n=0$, corresponding to \saws\ interacting with a surface, we prove the conjectured value of the critical surface fugacity. A crucial part of the proof involves demonstrating that the generating function of self-avoiding bridges of height $T$, taken at its critical point $1/\mu$, tends to 0 as $T$ increases, as predicted from SLE theory.