A random matrix model towards the quantum chaos transition conjecture

Abstract

Consider D random systems that are modeled by independent N× N complex Hermitian Wigner matrices. Suppose they are lying on a circle and the neighboring systems interact with each other through a deterministic matrix A. We prove that in the asymptotic limit N ∞, the whole system exhibits a quantum chaos transition when the interaction strength \|A\|HS varies. Specifically, when \|A\|HS N, we prove that the bulk eigenvalue statistics match those of a DN× DN GUE asymptotically and each bulk eigenvector is approximately equally distributed among the D subsystems with probability 1-o(1). These phenomena indicate quantum chaos of the whole system. In contrast, when \|A\|HS N-, we show that the system is integrable: the bulk eigenvalue statistics behave like D independent copies of GUE statistics asymptotically and each bulk eigenvector is localized on only one subsystem. In particular, if we take D ∞ after the N ∞ limit, the bulk statistics converge to a Poisson point process under the DN scaling.

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