Weakly self-avoiding walk on a high-dimensional torus

Abstract

How long does a self-avoiding walk on a discrete d-dimensional torus have to be before it begins to behave differently from a self-avoiding walk on Zd? We consider a version of this question for weakly self-avoiding walk on a torus in dimensions d>4. On Zd for d>4, the partition function for n-step weakly self-avoiding walk is known to be asymptotically purely exponential, of the form Aμn, where μ is the growth constant for weakly self-avoiding walk on Zd. We prove the identical asymptotic behaviour Aμn on the torus (with the same A and μ as on Zd) until n reaches order V1/2, where V is the number of vertices in the torus. This shows that the walk must have length of order at least V1/2 before it "feels" the torus in its leading asymptotics. Our results support the conjecture that the behaviour of the partition function does change once n reaches V1/2, and we relate this to a conjectural critical scaling window which separates the dilute phase n V1/2 from the dense phase n V1/2. To prove the conjecture and to establish the existence of the scaling window remains a challenging open problem. The proof uses a novel lace expansion analysis based on the "plateau" for the torus two-point function obtained in previous work.