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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