The role of excitation vector fields and all-polarisation state control in cavity magnonics

npj Spintronics Pub Date : 2024-12-04 DOI:10.1038/s44306-024-00062-z

Alban Joseph, Jayakrishnan M. P. Nair, Mawgan A. Smith, Rory Holland, Luke J. McLellan, Isabella Boventer, Tim Wolz, Dmytro A. Bozhko, Benedetta Flebus, Martin P. Weides, Rair Macêdo

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Abstract

Recently the field of cavity magnonics, a field focused on controlling the interaction between magnons and photons confined within microwave resonators, has drawn significant attention as it offers a platform for enabling advancements in quantum- and spin-based technologies. Here, we introduce excitation vector fields, whose polarisation and profile can be easily tuned in a two-port cavity setup, thus acting as an effective experimental dial to explore the coupled dynamics of cavity magnon-polaritons. Moreover, we develop theoretical models that accurately predict and reproduce the experimental results for any polarisation state and field profile within the cavity resonator. This versatile experimental platform offers a new avenue for controlling spin-photon interactions by manipulating the polarisation of excitation fields. By introducing real-time tunable parameters that control the polarisation state, our experiment delivers a mechanism to readily control the exchange of information between hybrid systems.

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激励矢量场和全极化状态控制在腔磁力学中的作用

最近，腔磁振学领域，一个专注于控制微波谐振器中磁振子和光子之间相互作用的领域，已经引起了极大的关注，因为它为量子和自旋技术的进步提供了一个平台。在这里，我们引入了激励矢量场，它的极化和轮廓可以很容易地在双端口腔设置中调谐，从而作为一个有效的实验刻度来探索腔磁非极化子的耦合动力学。此外，我们还建立了理论模型，可以准确地预测和重现腔腔谐振器内任何极化状态和场分布的实验结果。这个多功能实验平台为通过操纵激发场的极化来控制自旋光子相互作用提供了新的途径。通过引入控制极化状态的实时可调参数，我们的实验提供了一种容易控制混合系统之间信息交换的机制。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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npj Spintronics

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