Localization-delocalization transition for a random block matrix model at the edge (2504.00512v1)

Abstract: Consider a random block matrix model consisting of $D$ random systems arranged along a circle, where each system is modeled by an independent $N\times N$ complex Hermitian Wigner matrix. The neighboring systems interact through an arbitrary deterministic $N\times N$ matrix $A$. In this paper, we extend the localization-delocalization transition of this model, established in arxiv:2312.07297 for the bulk eigenvalue spectrum, to the entire spectrum, including spectral edges. More precisely, let $[E^-,E^+]$ denote the support of the limiting spectrum, and define $\kappa_E:=|E-E^+|\wedge |E-E^-|$ as the distance of an energy $E\in[E^-,E^+]$ from the spectral edges. We prove that for eigenvalues near $E$, a localization-delocalization transition of the corresponding eigenvectors occurs when $|A|{\mathrm{HS}}$ crosses the critical threshold $(\kappa_E+N^{-2/3})^{-1/2}$. Moreover, in the delocalized phase, we show that the extreme eigenvalues asymptotically follow the Tracy-Widom law, while in the localized phase, the edge eigenvalue statistics asymptotically behave like $D$ independent copies of GUE statistics, up to a deterministic shift. Our result recovers the findings of arxiv:2312.07297 in the bulk with $\kappa_E\asymp 1$, and also implies the existence of mobility edges at $E^{\pm}$ when $1\ll |A|{\mathrm{HS}} \ll N^{1/3}$: bulk eigenvectors corresponding to eigenvalues within $[E^{-}+\varepsilon,E^{+}-\varepsilon]$ are delocalized, whereas edge eigenvectors near $E^{\pm}$ are localized.