Coherent and dissipative cavity magnonics

Strong interactions between magnetic materials and electrodynamic cavities mix together spin and photon properties, producing unique hybridized behavior. The study of such coupled spin-photon systems, known as cavity magnonics, is motivated by the flexibility and controllability of these hybridized states for spintronic and quantum information technologies. In this Tutorial, we examine and compare both coherent and dissipative interactions in cavity magnonics. We begin with a familiar case study, the coupled harmonic oscillator, which provides insight into the unique characteristics of coherent and dissipative coupling. We then examine several canonical cavity-magnonic systems, highlighting the requirements for different coupling mechanisms, and conclude with recent applications of spin-photon hybridization, for example, the development of quantum transducers, memory architectures, isolators, and enhanced sensing.

Automated summary

Cavity magnonics explores the strong interactions between magnetic materials and electrodynamic cavities, blending spin and photon properties for spintronic and quantum information technologies. Investigating coherent and dissipative interactions, the study emphasizes the diverse coupling mechanisms required for different systems and showcases recent applications like quantum transducers and enhanced sensing.