Dynamical Detection of Level Repulsion in the One-Particle Aubry-André Model.

Date

2020-01-20

Authors

Torres-Herrera, E. Jonathan
Santos, Lea F.

Journal Title

Journal ISSN

Volume Title

Publisher

MDPI : Multidisciplinary Digital Publishing Institute

Abstract

Abstract: The analysis of level statistics provides a primary method to detect signatures of chaos in the quantum domain. However, for experiments with ion traps and cold atoms, the energy levels are not as easily accessible as the dynamics. In this work, we discuss how properties of the spectrum that are usually associated with chaos can be directly detected from the evolution of the number operator in the one-dimensional, noninteracting Aubry-André model. Both the quantity and the model are studied in experiments with cold atoms. We consider a single-particle and system sizes experimentally reachable. By varying the disorder strength within values below the critical point of the model, level statistics similar to those found in random matrix theory are obtained. Dynamically, these properties of the spectrum are manifested in the form of a dip below the equilibration point of the number operator. This feature emerges at times that are experimentally accessible. This work is a contribution to a special issue dedicated to Shmuel Fishman.

Description

Research article, peer-reviewed. Open Access.

Keywords

quantum chaos, Aubry-André model, correlation hole

Citation

Santos, Lea F. and E.Jonathan Torres-Herrera. (2020). Dynamical Detection of Level Repulsion in the One-Particle Aubry-André Model. Condensed Matter 5.7: