Generating three transparency windows, Fano-resononce and slow/fast light in magnomechanical system through an auxiliary microwave cavity

• URL: http://arxiv.org/abs/2504.11535v1
• Date: Tue, 15 Apr 2025 18:09:37 GMT
• Title: Generating three transparency windows, Fano-resononce and slow/fast light in magnomechanical system through an auxiliary microwave cavity
• Authors: M'bark Amghar, Noura Chabar, Mohamed Amazioug, Amjad Sohail Shah,
• Abstract summary: We investigate the magnomechanically induced transparency (MMIT) phenomenon, Fano resonances, and slow/fast light effects in a hybrid cavity magnomechanical system.<n>We provide an explanation of the mechanism behind the Fano resonance phenomenon.<n>We show that the slow light profile is decreased by adjusting the atom-photon coupling strength.
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• License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
• Abstract: In this paper, we propose a theoretical scheme to investigate the magnomechanically induced transparency (MMIT) phenomenon, Fano resonances, and slow/fast light effects in a hybrid cavity magnomechanical system. The magnomechanical system consists of two cavities: the principal cavity contains two ferromagnetic yttrium iron garnet (YIG) spheres, and the auxiliary cavity contains an atomic assembly. These two cavities are connected via photon tunneling, with the principal cavity being driven by two electromagnetic fields. The photon-magnon and phonon-magnon couplings are responsible for the magnon-induced transparency (MIT) and MMIT observed in the probe output spectrum. Furthermore, we examine the impacts of tunneling coupling, atom-photon coupling, and the magnetic field on the absorption, dispersion, and transmission spectra. We provide an explanation of the mechanism behind the Fano resonance phenomenon. Additionally, we address the phenomenon of slow and light propagation. Moreover, we demonstrate that group delay of the probe field can be improved by increasing photon tunneling strength. We also show that the slow light profile is decreased by adjusting the atom-photon coupling strength. This model is experimentally feasible. We hope these findings have the potential to be applied to the processing of quantum information and communication.

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