Litcius/Paper detail

Stationary optomagnonic entanglement and magnon-to-optics quantum state transfer via opto-magnomechanics

Zhiyuan Fan, Hang Qian, Jie Li

2022Quantum Science and Technology63 citationsDOIOpen Access PDF

Abstract

Abstract We show how to prepare a steady-state entangled state between magnons and optical photons in an opto-magnomechanical configuration, where a mechanical vibration mode couples to a magnon mode in a ferrimagnet by the dispersive magnetostrictive interaction, and to an optical cavity by the radiation pressure. We find that, by appropriately driving the magnon mode and the cavity to simultaneously activate the magnomechanical Stokes and the optomechanical anti-Stokes scattering, a stationary optomagnonic entangled state can be created. We further show that, by activating the magnomechanical state–swap interaction and subsequently sending a weak red-detuned optical pulse to drive the cavity, the magnonic state can be read out in the cavity output field of the pulse via the mechanical transduction. The demonstrated entanglement and state-readout protocols in such a novel opto-magnomechanical configuration allow us to optically control, prepare, and read out quantum states of collective spin excitations in solids, and provide promising opportunities for the study of quantum magnonics, macroscopic quantum states, and magnonic quantum information processing.

Topics & Concepts

PhysicsQuantum entanglementMagnonNonclassical lightQuantum mechanicsPhotonQuantum stateQuantum opticsOptical cavityQuantumLaserFerromagnetismMechanical and Optical ResonatorsQuantum Information and CryptographyPhotonic and Optical Devices