Delocalization and quantum diffusion of random band matrices in high dimensions I: Self-energy renormalization

Abstract

We consider Hermitian random band matrices H=(hxy) on the d-dimensional lattice ( Z/L Z)d. The entries hxy are independent (up to Hermitian conditions) centered complex Gaussian random variables with variances sxy= E|hxy|2. The variance matrix S=(sxy) has a banded structure so that sxy is negligible if |x-y| exceeds the band width W. In dimensions d 8, we prove that, as long as W Lε for a small constant ε>0, with high probability most bulk eigenvectors of H are delocalized in the sense that their localization lengths are comparable to L. Denote by G(z)=(H-z)-1 the Green's function of the band matrix. For Im\, z W2/L2, we also prove a widely used criterion in physics for quantum diffusion of this model, namely, the leading term in the Fourier transform of E|Gxy(z)|2 with respect to x-y is of the form ( Im\, z + a(p))-1 for some a(p) quadratic in p, where p is the Fourier variable. Our method is based on an expansion of Txy=|m|2 Σαsxα|Gα y|2 and it requires a self-energy renormalization up to error W-K for any large constant K independent of W and L. We expect that this method can be extended to non-Gaussian band matrices.