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Main Authors: Imara, Ziyad, Castillo, Isaac Pérez, Anouz, Khadija El, Allati, Abderahim El
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2504.13117
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author Imara, Ziyad
Castillo, Isaac Pérez
Anouz, Khadija El
Allati, Abderahim El
author_facet Imara, Ziyad
Castillo, Isaac Pérez
Anouz, Khadija El
Allati, Abderahim El
contents Recently, magnomechanical systems have emerged as promising platforms for quantum technologies, exploiting magnon-photon-phonon interactions to store high-fidelity quantum information. In this paper, we propose a scheme to entangle two spatially separated ferrimagnetic YIG crystals by injecting a microwave field into an optomagnonic ring cavity. The proposed optomagnomechanical configuration utilizes the coupling between magnetostriction-induced mechanical displacements and the optical cavity via radiation pressure. Magnons - collective spin excitations in macroscopic ferromagnets - are directly driven by an electromagnetic field. We demonstrate the generation of macroscopic magnon entanglement by exciting the optical cavity with a red detuned microwave field and the YIG crystals with a blue detuned field. Our analysis reveals that magnon entanglement vanishes for identical magnomechanical couplings but remains robust against thermal fluctuations. The magnon modes entangled in two ferrimagnetic crystals represent genuine macroscopic quantum states with potential applications in the study of macroscopic quantum mechanics and quantum information processing based on magnonics. The configuration is based on experimentally accessible parameters, providing a feasible route of quantum technologies.
format Preprint
id arxiv_https___arxiv_org_abs_2504_13117
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Tunable Entangling and Steering of Ferrimagnetic Magnons via an OptoMagnoMechanical Ring
Imara, Ziyad
Castillo, Isaac Pérez
Anouz, Khadija El
Allati, Abderahim El
Quantum Physics
Recently, magnomechanical systems have emerged as promising platforms for quantum technologies, exploiting magnon-photon-phonon interactions to store high-fidelity quantum information. In this paper, we propose a scheme to entangle two spatially separated ferrimagnetic YIG crystals by injecting a microwave field into an optomagnonic ring cavity. The proposed optomagnomechanical configuration utilizes the coupling between magnetostriction-induced mechanical displacements and the optical cavity via radiation pressure. Magnons - collective spin excitations in macroscopic ferromagnets - are directly driven by an electromagnetic field. We demonstrate the generation of macroscopic magnon entanglement by exciting the optical cavity with a red detuned microwave field and the YIG crystals with a blue detuned field. Our analysis reveals that magnon entanglement vanishes for identical magnomechanical couplings but remains robust against thermal fluctuations. The magnon modes entangled in two ferrimagnetic crystals represent genuine macroscopic quantum states with potential applications in the study of macroscopic quantum mechanics and quantum information processing based on magnonics. The configuration is based on experimentally accessible parameters, providing a feasible route of quantum technologies.
title Tunable Entangling and Steering of Ferrimagnetic Magnons via an OptoMagnoMechanical Ring
topic Quantum Physics
url https://arxiv.org/abs/2504.13117