Controlling magnon-photon coupling in a planar geometry

Dinesh Wagle, Anish Rai, M. T. Kaffash, M. Jungfleisch
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Abstract

The tunability of magnons enables their interaction with various other quantum excitations, including photons, paving the route for novel hybrid quantum systems. Here, we study magnon-photon coupling using a high-quality factor split-ring resonator and single-crystal yttrium iron garnet (YIG) spheres at room temperature. We investigate the dependence of the coupling strength on the size of the sphere and find that the coupling is stronger for spheres with a larger diameter as predicted by theory. Furthermore, we demonstrate strong magnon-photon coupling by varying the position of the YIG sphere within the resonator. Our experimental results reveal a theoretically-expected correlation between the coupling strength and the rf magnetic field. These findings demonstrate the control of coherent magnon-photon coupling through the theoretically predicted square-root dependence on the spin density in the ferromagnetic medium and the magnetic dipolar interaction in a planar resonator.
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控制平面几何中的磁子光子耦合
磁子的可调谐性使其能够与包括光子在内的各种其他量子激发相互作用,为新型混合量子系统铺平了道路。在这里,我们使用高质量因子分环谐振器和单晶钇铁石榴石(YIG)球研究了室温下的磁子-光子耦合。我们研究了耦合强度与球体大小的关系,发现正如理论预测的那样,直径越大的球体耦合越强。此外,通过改变 YIG 球在谐振器中的位置,我们证明了磁子-光子的强耦合。我们的实验结果表明,耦合强度与射频磁场之间存在理论预期的相关性。这些发现证明了相干磁子-光子耦合的控制是通过理论上预测的铁磁介质中自旋密度的平方根依赖性和平面谐振器中的磁偶极相互作用来实现的。
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