Thermal-noise-resistant optomechanical entanglement via general dark-mode control

TL;DR

This paper proposes a method to enhance and protect optomechanical entanglement from thermal noise by breaking the dark-mode effect using an auxiliary cavity mode, advancing quantum information applications.

Contribution

Introduction of an auxiliary-cavity-mode technique to break dark modes, significantly improving entanglement generation and thermal noise immunity in multimode optomechanical systems.

Findings

Auxiliary cavity mode enhances optomechanical entanglement.

Breaking dark modes increases thermal noise resistance by about three orders of magnitude.

Entanglement is significantly improved when dark modes are suppressed.

Abstract

Quantum entanglement not only plays an important role in the study of the fundamentals of quantum theory, but also is considered as a crucial resource in quantum information science. The generation of macroscopic entanglement involving multiple optical and mechanical modes is a desired task in cavity optomechanics. However, the dark-mode effect is a critical obstacle against the generation of quantum entanglement in multimode optomechanical systems consisting of multiple degenerate or near-degenerate mechanical modes coupled to a common cavity mode. Here we propose an auxiliary-cavity-mode method to enhance optomechanical entanglement in a multimode optomechanical system by breaking the dark-mode effect. We find that the introduction of the auxiliary cavity mode not only assists the entanglement creation between the cavity mode and the mechanical modes, but also improves the immunity of the optomechanical entanglement to the thermal excitations by about three orders of magnitude. We also study the optomechanical entanglement in the network-coupled optomechanical system consisting of two mechanical modes and two cavity modes. By analyzing the correspondence between the optomechanical entanglement and the dark-mode effect, we find that optomechanical entanglement can be largely enhanced once the dark mode is broken. In addition, we study the mechanical entanglement and find that it is negligibly small. We also present some discussions on the experimental implementation with a microwave optomechanical setup, on the relationship between the dark-mode-breaking mechanism and the center-of-mass and relative coordinates, and on the explanation of the important role of the dark-mode breaking in the enhancement of optomechanical entanglement. Our results pave the way towards the preparation of entangled optomechanical networks and noise-resistant quantum resources.