Nonreciprocal entanglement in cavity magnomechanics exploiting chiral cavity-magnon coupling

TL;DR

This paper introduces a method to generate nonreciprocal quantum entanglement in a cavity magnomechanical system using chiral cavity-magnon coupling, enabling robust quantum communication and processing.

Contribution

It demonstrates a novel mechanism for nonreciprocal entanglement leveraging chiral cavity-magnon interactions in a cavity magnomechanical system.

Findings

Achieves nonreciprocal microwave-magnon and phonon entanglement.

Demonstrates robustness against experimental imperfections.

Proposes application in quantum teleportation and chiral quantum networks.

Abstract

We propose a new mechanism to achieve nonreciprocal quantum entanglement in a cavity magnomechanical system by exploiting the chiral cavity-magnon coupling. The system consists of a magnon mode, a mechanical vibration mode, and two degenerate counter-propagating microwave cavity modes in a torus-shaped cavity. We show that nonreciprocal stationary microwave-magnon and -phonon bipartite entanglements and photon-magnon-phonon tripartite entanglement can be achieved by respectively driving different circulating cavity modes that hold a chiral coupling to the magnon mode. The nonreciprocal entanglements are shown to be robust against various experimental imperfections. We specifically show how such nonreciprocal entanglement can realize the channel multiplexing quantum teleportation from a microwave field to a solid-state magnon mode. The work may find promising applications of the cavity magnomechanical systems in noise-tolerant quantum processing, channel multiplexing quantum teleportation, and chiral magnonic quantum networks.