Anderson polymer in a fractional Brownian environment: asymptotic behavior of the partition function

Abstract

We consider the Anderson polymer partition function u(t):=EX[e∫0t dBX(s)s]\,, where \Bxt\,;\, t≥0\x∈Zd is a family of independent fractional Brownian motions all with Hurst parameter H∈(0,1), and \X(t)\t∈ R≥ 0 is a continuous-time simple symmetric random walk on Zd with jump rate and started from the origin. EX is the expectation with respect to this random walk. We prove that when H≤ 1/2, the function u(t) almost surely grows asymptotically like el t, where l>0 is a deterministic number. More precisely, we show that as t approaches +∞, the expression \1t u(t)\t∈ R>0 converges both almost surely and in the L1 sense to some deterministic number l>0. For H>1/2, we first show that t→ ∞ 1t u(t) exists both almost surely and in the L1 sense, and equals a strictly positive deterministic number (possibly +∞); hence almost surely u(t) grows asymptotically at least like ea t for some deterministic constant a>0. On the other hand, we also show that almost surely and in the L1 sense, t→ ∞ 1t t u(t) is a deterministic finite real number (possibly zero), hence proving that almost surely u(t) grows asymptotically at most like eb t t for some deterministic positive constant b. Finally, for H>1/2 when Zd is replaced by a circle endowed with a H\"older continuous covariance function, we show that t→ ∞ 1t u(t) is a finite deterministic positive number, hence proving that almost surely u(t) grows asymptotically at most like ec t for some deterministic positive constant c.