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Hauptverfasser: Liu, Wenzhang, Abbas, Muqaddar, Asadpour, Seyyed Hossein, Hamedi, Hamid R., Zhang, Pei, Sanders, Barry C.
Format: Preprint
Veröffentlicht: 2024
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Online-Zugang:https://arxiv.org/abs/2408.17327
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author Liu, Wenzhang
Abbas, Muqaddar
Asadpour, Seyyed Hossein
Hamedi, Hamid R.
Zhang, Pei
Sanders, Barry C.
author_facet Liu, Wenzhang
Abbas, Muqaddar
Asadpour, Seyyed Hossein
Hamedi, Hamid R.
Zhang, Pei
Sanders, Barry C.
contents We investigate the phenomenon of magnomechanically induced grating (MMIG) within a cavity magnomechanical system, comprising magnons (spins in a ferromagnet, such as yttrium iron garnet), cavity microwave photons, and phonons [\textit{J. Li, S.-Y. Zhu, and G. S. Agarwal, Phys. Rev. Lett. \textbf{121}, 203601 (2018)}]. By applying an external standing wave control, we observe modifications in the transmission profile of a probe light beam, signifying the presence of MMIG. Through numerical analysis, we explore the diffraction intensities of the probe field, examining the impact of interactions between cavity magnons, magnon-phonon interactions, standing wave field strength, and interaction length. MMIG systems leverage the unique properties of magnons, and collective spin excitations with attributes like long coherence times and spin-wave propagation. These distinctive features can be harnessed in MMIG systems for innovative applications in information storage, retrieval, and quantum memories, offering various orders of diffraction grating.
format Preprint
id arxiv_https___arxiv_org_abs_2408_17327
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Generating Grating in Cavity Magnomechanics
Liu, Wenzhang
Abbas, Muqaddar
Asadpour, Seyyed Hossein
Hamedi, Hamid R.
Zhang, Pei
Sanders, Barry C.
Optics
We investigate the phenomenon of magnomechanically induced grating (MMIG) within a cavity magnomechanical system, comprising magnons (spins in a ferromagnet, such as yttrium iron garnet), cavity microwave photons, and phonons [\textit{J. Li, S.-Y. Zhu, and G. S. Agarwal, Phys. Rev. Lett. \textbf{121}, 203601 (2018)}]. By applying an external standing wave control, we observe modifications in the transmission profile of a probe light beam, signifying the presence of MMIG. Through numerical analysis, we explore the diffraction intensities of the probe field, examining the impact of interactions between cavity magnons, magnon-phonon interactions, standing wave field strength, and interaction length. MMIG systems leverage the unique properties of magnons, and collective spin excitations with attributes like long coherence times and spin-wave propagation. These distinctive features can be harnessed in MMIG systems for innovative applications in information storage, retrieval, and quantum memories, offering various orders of diffraction grating.
title Generating Grating in Cavity Magnomechanics
topic Optics
url https://arxiv.org/abs/2408.17327