Localization-delocalization transition for a random block matrix model at the edge
Abstract
Consider a random block matrix model consisting of D random systems arranged along a circle, where each system is modeled by an independent N× N complex Hermitian Wigner matrix. Neighboring systems interact via an arbitrary deterministic N× N matrix A. In this paper, we extend the localization-delocalization transition previously established in arxiv:2312.07297 for the bulk eigenvalue spectrum to the entire spectrum, including the spectral edges. Let [E-,E+] denote the support of the limiting spectral density, and define E:=|E-E+| |E-E-| as the distance from a given energy E ∈ [E-, E+] to the spectral edges. We show that for eigenvalues near E, the corresponding eigenvectors undergo a localization-delocalization transition when \|A\|HS crosses the critical threshold (E + N-2/3)-1/2. In the delocalized phase, the extreme eigenvalues asymptotically follow the Tracy-Widom distribution, while in the localized phase, the edge eigenvalue statistics asymptotically match those of D independent GUE ensembles, up to a deterministic shift. Our results recover those of arxiv:2312.07297 in the bulk regime, where E 1, and further reveal the presence of mobility edges near E when 1 \|A\|HS N1/3. Specifically, bulk eigenvectors corresponding to energies E with E \|A\|HS-2 are delocalized, while those with E \|A\|HS-2 are localized.
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