Nonreciprocal Transmission and Entanglement in a cavity-magnomechanical system

TL;DR

This paper demonstrates how a cavity-magnomechanical system can generate nonreciprocal photon transmission and entanglement, offering new approaches for noise-tolerant quantum computing and chiral quantum networks.

Contribution

It introduces a novel cavity-magnomechanical setup that achieves nonreciprocal transmission and entanglement by breaking symmetry, with potential applications in quantum information processing.

Findings

Realized nonreciprocal photon transmission.

Generated one-way bipartite quantum entanglement.

Simulations suggest feasibility with current experimental parameters.

Abstract

Quantum entanglement, a key element for quantum information is generated with a cavity-magnomechanical system. It comprises of two microwave cavities, a magnon mode and a vibrational mode, and the last two elements come from a YIG sphere trapped in the second cavity. The two microwave cavities are connected by a superconducting transmission line, resulting in a linear coupling between them. The magnon mode is driven by a strong microwave field and coupled to cavity photons via magnetic dipole interaction, and at the same time interacts with phonons via magnetostrictive interaction. By breaking symmetry of the configuration, we realize nonreciprocal photon transmission and one-way bipartite quantum entanglement. By using current experimental parameters for numerical simulation, it is hoped that our results may reveal a new strategy to built quantum resources for the realization of noise-tolerant quantum processors, chiral networks, and so on.