物理
马格农
钇铁石榴石
光子
束缚态
散射
联轴节(管道)
凝聚态物理
波导管
激发
量子
磁场
微波食品加热
量子力学
反平行(数学)
角动量
感应耦合
领域(数学)
腔量子电动力学
自旋(空气动力学)
量子电动力学
量子光学
电磁场
连贯性(哲学赌博策略)
波包
Atom(片上系统)
上下界
自旋波
原子光学
激发态
作者
Shi-Qi Gan,Guoqing Tian,Zihao Li,Xin‐You Lü
出处
期刊:Physical review
[American Physical Society]
日期:2025-11-11
卷期号:112 (6)
被引量:1
摘要
We study the single-photon scattering process and the single-excitation bound states in a waveguide QED system where a giant atom (GA) couples simultaneously to a one\penalty1000-\hskip0ptdimensional coupled-resonator waveguide and an yttrium iron garnet (YIG) sphere. For a stationary YIG sphere, we demonstrate that the magnon-atom coupling strength provides flexible control over the transmission spectrum, enabling magnon\penalty1000-\hskip0ptdriven single\penalty1000-\hskip0ptphoton transport and bound states. When the YIG sphere spins, the resulting Barnett effect induces tunable photon routing: Incident photons are fully transmitted (reflected) when the bias magnetic field is parallel to the YIG sphere's angular velocity, whereas they are entirely reflected (transmitted) when the bias magnetic field is antiparallel to the YIG sphere's angular velocity. By increasing the separation between the GA's coupling points, we further realize a single\penalty1000-\hskip0ptphoton switch with either broad operational bandwidth or multiple operational frequencies. We also show that large detuning between the GA and the magnon mode suppresses the effect of the magnetically controlled single-photon switch via effective dispersive coupling, and we identify magnon\penalty1000-\hskip0ptcontrolled bound states that facilitate directional quantum storage. Finally, we simulate the dynamics of single-photon scattering, analyze the time evolution of magnon excitation and the atomic population, and discuss the dependence of magnon excitation on the magnon-atom coupling strength, Barnett frequency shift, and wave vector of the single-photon wave packet. Our work opens a way for realizing a magnon-modulated quantum single-photon switch and has potential applications in quantum engineering and scalable quantum networks.
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