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Nonreciprocal magnon laser.

Ye-Jun Xu, Jun Song

    Optics Letters
    |October 15, 2021
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    Summary
    This summary is machine-generated.

    This study proposes a nonreciprocal magnon laser using a spinning resonator and yttrium iron garnet. The device achieves tunable lasing by manipulating spin-wave excitations through light-dragging effects.

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    Area of Science:

    • Optomagnonics
    • Spintronics
    • Nonreciprocal Optics

    Background:

    • Magnon lasing is typically achieved via magnon-induced Brillouin scattering.
    • Controlling spin-wave excitations is crucial for advanced spintronic devices.
    • Nonreciprocal optical devices are essential for signal isolation and manipulation.

    Purpose of the Study:

    • To propose a novel nonreciprocal magnon laser.
    • To investigate the influence of a spinning resonator on magnon lasing.
    • To demonstrate tunability of the nonreciprocal magnon laser.

    Main Methods:

    • Utilizing a compound cavity optomagnonical system with an yttrium iron garnet sphere and a spinning resonator.
    • Leveraging magnon-induced Brillouin scattering for magnon lasing.
    • Exploiting the Fizeau light-dragging effect caused by resonator spinning to modify magnon gain and threshold power.

    Main Results:

    • A nonreciprocal magnon laser was successfully realized.
    • The spinning resonator significantly modified magnon gain and lasing threshold power.
    • The nonreciprocal magnon laser demonstrated high tunability with spinning speed and driving direction.

    Conclusions:

    • The proposed system offers an experimentally feasible method for manipulating spin-wave excitations.
    • This work bridges spintronics and nonreciprocal optics, opening avenues for novel device applications.
    • The tunable nonreciprocal magnon laser has potential applications in advanced optical and spintronic systems.