Single-Particle Universality of the Many-Body Spectral Form Factor

• URL: http://arxiv.org/abs/2410.07306v1
• Date: Wed, 9 Oct 2024 18:00:00 GMT
• Title: Single-Particle Universality of the Many-Body Spectral Form Factor
• Authors: Michael O. Flynn, Lev Vidmar, Tatsuhiko N. Ikeda,
• Abstract summary: We consider systems of fermions evolved by non-interacting unitary circuits with correlated on-site potentials. When these potentials are drawn from the eigenvalue distribution of a circular random matrix ensemble, the spectral form factor (SFF) of the resulting circuit ensemble can be computed exactly without numerical sampling.
• Score: 0.0
• License: http://creativecommons.org/licenses/by/4.0/
• Abstract: We consider systems of fermions evolved by non-interacting unitary circuits with correlated on-site potentials. When these potentials are drawn from the eigenvalue distribution of a circular random matrix ensemble, the spectral form factor (SFF) of the resulting circuit ensemble can be computed exactly without numerical sampling. In the case of the circular unitary ensemble (CUE) we report an exact closed form for the SFF, valid for arbitrary system sizes, and show that it grows through a sequence of exponential ramps. Using exact numerical methods, we find that the circular orthogonal and symplectic ensembles (COE and CSE, respectively) also lead to exponential growth of the SFF. This exponential growth is characteristic of non-interacting systems with random matrix statistics at the $\textit{single-particle}$ level and, upon introducing interactions, crosses over to a linear ramp consistent with many-body random matrix universality. Our exact results for the SFF provide a baseline for future studies of the crossover between single-particle and many-body random matrix behavior.

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