Self-avoiding walks crossing a square
Abstract
We study a restricted class of self-avoiding walks (SAW) which start at the origin (0, 0), end at (L, L), and are entirely contained in the square [0, L] × [0, L] on the square lattice Z2. The number of distinct walks is known to grow as λL2+o(L2). We estimate λ = 1.744550 0.000005 as well as obtaining strict upper and lower bounds, 1.628 < λ < 1.782. We give exact results for the number of SAW of length 2L + 2K for K = 0, 1, 2 and asymptotic results for K = o(L1/3). We also consider the model in which a weight or fugacity x is associated with each step of the walk. This gives rise to a canonical model of a phase transition. For x < 1/μ the average length of a SAW grows as L, while for x > 1/μ it grows as L2. Here μ is the growth constant of unconstrained SAW in Z2. For x = 1/μ we provide numerical evidence, but no proof, that the average walk length grows as L4/3. We also consider Hamiltonian walks under the same restriction. They are known to grow as τL2+o(L2) on the same L × L lattice. We give precise estimates for τ as well as upper and lower bounds, and prove that τ < λ.
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