Dynamic control of photon-magnon interactions via secondary magnon excitation

TL;DR

This paper demonstrates photon-mediated indirect magnon-magnon coupling between spatially separated magnetic films on a planar resonator, revealing new pathways for hybrid quantum device design and scalable magnonic systems.

Contribution

It introduces a theoretical and experimental framework for controlling magnon interactions via photon mediation in planar hybrid systems, highlighting indirect coupling mechanisms.

Findings

Coupling strength increases with YIG film thickness.

Magnon-magnon interaction occurs without direct dipolar coupling.

Theoretical model accurately reproduces experimental spectra.

Abstract

Photon-mediated magnon-magnon coupling between spatially separated Yttrium Iron Garnet (YIG) and permalloy (NiFe) thin films on a planar hexagonal ring resonator shows clear signatures of magnon-magnon interaction are observed without direct dipolar interaction between the magnetic films. The coupling strength between the hexagonal ring resonator and the permalloy film increases with the thickness of the YIG film, despite a fixed permalloy film thickness. This suggests the presence of an indirect interaction channel mediated by resonator photons. A theoretical model is presented that accurately reproduces the observed transmission spectra and reveals a nontrivial interdependence between the individual coupling strengths of YIG and permalloy to the resonator. These results highlight the importance of indirect interactions and potential crosstalk pathways in designing hybrid magnonic systems and scalable quantum architectures, while demonstrating the feasibility of cost-effective, planar configurations for experimental implementation. These insights are valuable for advancing low-loss, coherent information transfer in hybrid quantum devices.