Weyl sums and the Lyapunov exponent for the skew-shift Schr\"odinger cocycle

Abstract

We study the one-dimensional discrete Schr\"odinger operator with the skew-shift potential 2λ(2π (j2 ω+jy+x)). This potential is long conjectured to behave like a random one, i.e., it is expected to produce Anderson localization for arbitrarily small coupling constants λ>0. In this paper, we introduce a novel perturbative approach for studying the zero-energy Lyapunov exponent L(λ) at small λ. Our main results establish that, to second order in perturbation theory, a natural upper bound on L(λ) is fully consistent with L(λ) being positive and satisfying the usual Figotin-Pastur type asymptotics L(λ) Cλ2 as λ 0. The analogous quantity behaves completely differently in the Almost-Mathieu model, whose zero-energy Lyapunov exponent vanishes for λ<1. The main technical work consists in establishing good lower bounds on the exponential sums (quadratic Weyl sums) that appear in our perturbation series.