Exact form of the exponential correlation function in the glassy super-rough phase

Abstract

We consider the random-phase sine-Gordon model in two dimensions. It describes two-dimensional elastic systems with random periodic disorder, such as pinned flux-line arrays, random field XY models, and surfaces of disordered crystals. The model exhibits a super-rough glass phase at low temperature T<Tc with relative displacements growing with distance r as [θ(r)-θ(0)]2 A(τ) 2 (r/a), where A(τ) = 2 τ2- 2 τ3 +O(τ4) near the transition and τ=1-T/Tc. We calculate all higher cumulants and show that they grow as [θ(r)-θ(0)]2nc [2 (-1)n+1 (2n)! ζ(2n-1) τ2 + O(τ3) ] (r/a), n ≥ 2, where ζ is the Riemann zeta function. By summation, we obtain the decay of the exponential correlation function as eiq[θ(r)-θ(0)] (a/r)η(q) (-12A(q)2(r/a)) where η(q) and A(q) are obtained for arbitrary q ≤ 1 to leading order in τ. The anomalous exponent is η(q) = c q2 - τ2 q2 [2γE+(q)+(-q)] in terms of the digamma function , where c is non-universal and γE is the Euler constant. The correlation function shows a faster decay at q=1, corresponding to fermion operators in the dual picture, which should be visible in Bragg scattering experiments.