Delocalization of Non-Mean-Field Random Matrices in Dimensions d 3

Abstract

We study N × N random band matrices H = (Hxy) with mean-zero complex Gaussian entries, where x,y lie on the discrete torus (Z / [d]N Z)d in dimensions d 3. The variance profile satisfies E|Hxy|2 = Sxy, with Sxy = 0 whenever the distance between x and y exceeds a bandwidth parameter W. We prove that if W ≥ Nc for some constant c > 0, then in the large-N limit, bulk eigenvectors are delocalized, quantum unique ergodicity (QUE) holds, and the local bulk eigenvalue statistics are universal. Our proof is based on the tree approximation of the loop hierarchy (arXiv:2501.01718) and diagrammatic techniques developed in earlier works (arXiv:1807.02447, arXiv:2104.12048, arXiv:2107.05795, arXiv:2412.15207, arXiv:2503.07606). Besides random band matrices, we also study two classical non-mean-field random matrix models: the Wegner orbital and the block Anderson models. Specifically, we consider Hermitian matrices H = V + g on the same discrete torus (Z / [d]N Z)d, where V is a random block potential consisting of i.i.d. complex Gaussian diagonal blocks of size Wd × Wd, and encodes the interactions between neighboring blocks--random in the Wegner orbital model and deterministic in the block Anderson model. The parameter g > 0 represents the coupling strength between blocks. Assuming again that W ≥ Nc, we establish delocalization of bulk eigenvectors, QUE, and bulk universality under the condition W-d/2+ g -1 for any small constant >0. Combined with the localization results of arXiv:1608.02922 for g W-d/2, this identifies a localization--delocalization transition at the scale g=W-d/2 in dimensions d 3.