English

Quantum Diffusion and Delocalization for Band Matrices with General Distribution

Mathematical Physics 2015-05-18 v4 math.MP Probability

Abstract

We consider Hermitian and symmetric random band matrices HH in d1d \geq 1 dimensions. The matrix elements HxyH_{xy}, indexed by x,yΛZdx,y \in \Lambda \subset \Z^d, are independent and their variances satisfy σxy2:=\E\absHxy2=Wdf((xy)/W)\sigma_{xy}^2:=\E \abs{H_{xy}}^2 = W^{-d} f((x - y)/W) for some probability density ff. We assume that the law of each matrix element HxyH_{xy} is symmetric and exhibits subexponential decay. We prove that the time evolution of a quantum particle subject to the Hamiltonian HH is diffusive on time scales tWd/3t\ll W^{d/3}. We also show that the localization length of the eigenvectors of HH is larger than a factor Wd/6W^{d/6} times the band width WW. All results are uniform in the size \absΛ\abs{\Lambda} of the matrix. This extends our recent result \cite{erdosknowles} to general band matrices. As another consequence of our proof we show that, for a larger class of random matrices satisfying xσxy2=1\sum_x\sigma_{xy}^2=1 for all yy, the largest eigenvalue of HH is bounded with high probability by 2+M2/3+ϵ2 + M^{-2/3 + \epsilon} for any ϵ>0\epsilon > 0, where M\deq1/(maxx,yσxy2)M \deq 1 / (\max_{x,y} \sigma_{xy}^2).

Keywords

Cite

@article{arxiv.1005.1838,
  title  = {Quantum Diffusion and Delocalization for Band Matrices with General Distribution},
  author = {Laszlo Erdos and Antti Knowles},
  journal= {arXiv preprint arXiv:1005.1838},
  year   = {2015}
}

Comments

Corrected typos and some inaccuracies in appendix C

R2 v1 2026-06-21T15:21:14.096Z