Relaxation Fluctuations of Correlation Functions: Spin and Random Matrix Models
- URL: http://arxiv.org/abs/2407.21644v2
- Date: Thu, 26 Sep 2024 06:11:37 GMT
- Title: Relaxation Fluctuations of Correlation Functions: Spin and Random Matrix Models
- Authors: Tanay Pathak,
- Abstract summary: We study the fluctuation average and variance of certain correlation functions as a diagnostic measure of quantum chaos.
We identify the three distinct phases of the models: the ergodic, the fractal, and the localized phases.
- Score: 0.0
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Spectral statistics and correlations are the usual way to study the presence or absence of quantum chaos in quantum systems. We present our investigation on the study of the fluctuation average and variance of certain correlation functions as a diagnostic measure of quantum chaos and to possibly characterize quantum systems based on it. These quantities are related to eigenvector distribution and eigenvector correlation. Using the Random Matrix Theory certain analytical expressions of these quantities, for the Gaussian orthogonal ensemble case, were calculated before. So as a first step, we study these quantities for the Gaussian unitary ensemble case numerically, and deduce certain analytical results for the same. We then carry out our investigations in physical system, such as the mixed-field Ising model. For this model, we find that although the eigenvalue statistics follow the behaviour of corresponding random matrices, the fluctuation average and variance of these correlation functions deviate from the expected random matrix theory behaviour. We then turn our focus on the Rosenzweig-Porter model of the Gaussian Orthogonal Ensemble and Gaussian Unitary Ensemble types. By using the fluctuation average and variance of these correlations, we identify the three distinct phases of these models: the ergodic, the fractal, and the localized phases. We provide an alternative way to study and distinguish the three phases and firmly establish the use of these correlation fluctuations as an alternative way to characterize quantum chaos.
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