Quantum Diffusion and Delocalization for Band Matrices with General Distribution

Abstract

We consider Hermitian and symmetric random band matrices H in d ≥ 1 dimensions. The matrix elements Hxy, indexed by x,y ∈ ⊂ d, are independent and their variances satisfy σxy2:= Hxy2 = W-d f((x - y)/W) for some probability density f. We assume that the law of each matrix element Hxy is symmetric and exhibits subexponential decay. We prove that the time evolution of a quantum particle subject to the Hamiltonian H is diffusive on time scales t Wd/3. We also show that the localization length of the eigenvectors of H is larger than a factor Wd/6 times the band width W. All results are uniform in the size of the matrix. This extends our recent result erdosknowles to general band matrices. As another consequence of our proof we show that, for a larger class of random matrices satisfying Σxσxy2=1 for all y, the largest eigenvalue of H is bounded with high probability by 2 + M-2/3 + ε for any ε > 0, where M 1 / (x,y σxy2).