Quantum Phase Transitions in Optomechanical Systems
Abstract
In this letter, we investigate the ground state properties of an optomechanical system consisting of a coupled cavity and mechanical modes. An exact solution is given when the ratio between the cavity and mechanical frequencies tends to infinity. This solution reveals a coherent photon occupation in the ground state by breaking continuous or discrete symmetries, exhibiting an equilibrium quantum phase transition (QPT). In the -broken phase, an unstable Goldstone mode can be excited. In the model featuring symmetry, we discover the mutually (in the finite ) or unidirectionally (in ) dependent relation between the squeezed vacuum of the cavity and mechanical modes. In particular, when the cavity is driven by a squeezed field along the required squeezing parameter, it enables modifying the region of -broken phase and significantly reducing the coupling strength to reach QPTs. Furthermore, by coupling atoms to the cavity mode, the hybrid system can undergo a QPT at a hybrid critical point, which is cooperatively determined by the optomechanical and light-atom systems. These results suggest that this optomechanical system complements other phase transition models for exploring novel critical phenomena.
Cite
@article{arxiv.2308.15278,
title = {Quantum Phase Transitions in Optomechanical Systems},
author = {Bo Wang and Franco Nori and Ze-Liang Xiang},
journal= {arXiv preprint arXiv:2308.15278},
year = {2024}
}
Comments
7 pages, 3 figures + Supplemental Material(7 pages, 2 figures)