Reservoir engineering strong quantum entanglement in cavity magnomechanical systems

TL;DR

This paper demonstrates a method to transfer and enhance quantum entanglement in a hybrid cavity magnomechanical system using reservoir engineering, achieving strong photon-phonon entanglement with robustness against temperature.

Contribution

It introduces a novel reservoir engineering approach to transfer and strengthen bipartite entanglement in a cavity magnomechanical system, enabling robust quantum entanglement.

Findings

Initial magnon-phonon entanglement can be transferred to photon-phonon subsystem.

Steady-state entanglement is robust against temperature variations.

Greater entanglement and cooling achieved with increased dissipation ratio.

Abstract

We construct a hybrid cavity magnomechanical system to transfer the bipartite entanglements and achieve the strong microwave photon-phonon entanglement based on the reservoir engineering approach. The magnon mode is coupled to the microwave cavity mode via magnetic dipole interaction, and to the phonon mode via magnetostrictive force (optomechanical-like). It is shown that the initial magnon-phonon entanglement can be transferred to the photon-phonon subspace in the case of these two interactions cooperating. In reservoir-engineering parameter regime, the initial entanglement is directionally transferred to the photon-phonon subsystem, so we obtain a strong bipartite entanglement in which the magnon mode acts as the cold reservoir to effectively cooling the Bogoliubov mode delocalized over the cavity and the mechanical deformation mode. Moreover, as the dissipation ratio between the cold reservoir mode and the target mode increases, we can achieve greater quantum entanglement and better cooling effect. Our results indicate that the steady-state entanglement is robust against temperature. The scheme may provides potential applications for quantum information processing, and is expected to be extended to other three-mode systems.