Time crystal and chaos in the hybrid atom-optomechanics system

TL;DR

This paper explores how a hybrid atom-optomechanics system can exhibit stable, periodic, or chaotic dynamics, including the formation of time crystal phases, by tuning coupling strengths, with potential experimental observations.

Contribution

It introduces a novel phase diagram for a hybrid atom-optomechanics system showing stable, time crystal, and chaotic phases controlled by coupling parameters.

Findings

Identification of stable, oscillating, and chaotic regimes.

Definition and characterization of time crystal phases.

Phase diagram illustrating phase transitions with tunable parameters.

Abstract

We consider atoms in two different periodic potentials induced by different lasers, one of which is coupled to a mechanical membrane via radiation pressure force. The atoms are intrinsically two-level systems that can absorb or emit photons, but the dynamics of their position and momentum are treated classically. On the other hand, the membrane, the cavity field, and the intrinsic two-level atoms are treated quantum mechanically. We show that the mean excitation of the three systems can be stable, periodically oscillating, or in a chaotic state depending on the strength of the coupling between them. We define regular, time crystal, and chaotic phases, and present a phase diagram where the three phases can be achieved by manipulating the field-membrane and field-atom coupling strengths. The first and second-order correlation functions in different phases are also calculated, which can be observed in experiments. Our proposal offers a new way to generate and tune time crystal and chaotic phases in a well-established atom-optomechanics system.