Localization Lengths of Power-Law Random Band Matrices

Abstract

We study large N× N power-law random band matrices H=(Hij) with centered complex Gaussian entries, where the variances satisfy a power-law decay E|Hij|2 (|i-j|/W+1)-1-α, for some exponent α>-1 and bandwidth W 1. We establish the following lower bounds, with high probability, on the localization length of bulk eigenvectors in the different regimes of α: (1) =N if -1<α<0; (2) WC for any large constant C>0 if 0 < α <1; (3) Wα/(α-1) if 1 < α <2; (4) W2 if α > 2. These results verify the physical conjecture of arXiv:cond-mat/9604163 on the delocalized side. The main difficulty in the proof lies in handling the interplay between the non-mean-field nature of the model and the slow decay of the variance profile. To address this issue, a key technical ingredient is a new dynamical analysis of T-variables formed from pairs of resolvent entries of H. In contrast to the fundamental works on regular random band matrices with fast-decaying variances in arXiv:2501.01718 and arXiv:2506.06441, this approach does not rely on higher-order resolvent loops.