The self-avoiding walk in a strip

Ben Dyhr, Michael Gilbert, Tom Kennedy, Gregory F. Lawler, Shane Passon

Published 2010-08-25, updated 2011-06-17Version 2

We review the existence of the infinite length self-avoiding walk in the half plane and its relationship to bridges. We prove that this probability measure is also given by the limit as $\beta \rightarrow \beta_c-$ of the probability measure on all finite length walks $\omega$ with the probability of $\omega$ proportional to $\beta_c^{|\omega|}$ where $|\omega|$ is the number of steps in $\omega$. The self-avoiding walk in a strip $\{z : 0<\Im(z)<y\}$ is defined by considering all self-avoiding walks $\omega$ in the strip which start at the origin and end somewhere on the top boundary with probability proportional to $\beta_c^{|\omega|}$ We prove that this probability measure may be obtained by conditioning the SAW in the half plane to have a bridge at height $y$. This observation is the basis for simulations to test conjectures on the distribution of the endpoint of the SAW in a strip and the relationship between the distribution of this strip SAW and SLE$_{8/3}$.