Universality of Critical Behaviour in a Class of Recurrent Random Walks
Abstract
Let X0=0, X1, X2, ..., be an aperiodic random walk generated by a sequence xi1, xi2, ..., of i.i.d. integer-valued random variables with common distribution p(.) having zero mean and finite variance. For an N-step trajectory X=(X0,X1,...,XN) and a monotone convex function V: R+ -> R+ with V(0)=0, define V(X)= sumj=1N-1 V(|Xj|). Further, let IN,+a,b be the set of all non-negative paths X compatible with the boundary conditions X0=a, XN=b. We discuss asymptotic properties of X in IN,+a,b w.r.t. the probability distribution PNa,b(X)= (ZNa,b)-1 exp-lambda V(X) prodi=0N-1 p(Xi+1-Xi) as N -> infinity and lambda -> 0, ZNa,b being the corresponding normalization. If V(.) grows not faster than polynomially at infinity, define H(lambda) to be the unique solution to the equation lambda H2 V(H) =1. Our main result reads that as lambda -> 0, the typical height of X[alpha N] scales as H(lambda) and the correlations along X decay exponentially on the scale H(lambda)2. Using a suitable blocking argument, we show that the distribution tails of the rescaled height decay exponentially with critical exponent 3/2. In the particular case of linear potential V(.), the characteristic length H(lambda) is proportional to lambda-1/3 as lambda -> 0.
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