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Spherical optomagnonic microresonators: Triple-resonant photon transitions between Zeeman-split Mie modes

Evangelos Almpanis, Grigorios P. Zouros, Petros Andreas Pantazopoulos, Kosmas L. Tsakmakidis, N. Papanikolaou, N. Stéfanou

2020Physical review. B./Physical review. B32 citationsDOI

Abstract

We report a thorough theoretical investigation of magnon-assisted photon transitions in magnetic garnet micron-sized spheres, which operate as optomagnonic resonators. In this case, matching the intraband splitting of optical Mie modes, induced by particle magnetization, to the eigenfrequency of the uniform-precession spin wave, high-efficiency triply resonant optical transitions between these modes, through respective emission or absorption of a cavity magnon, are enabled. By means of rigorous full electrodynamic computations, supported by corresponding approximate analytical calculations, we provide compelling evidence of greatly increased optomagnonic interaction, compared to that in similar processes between whispering gallery modes of corresponding submillimeter spheres, due to the reduced magnon mode volume. We explain the underlying mechanisms to a degree that goes beyond existing interpretation, invoking group theory to derive general selection rules and highlighting the role of the photon spin as the key property for maximizing the respective coupling strength.

Topics & Concepts

PhysicsZeeman effectPhotonMagnonResonatorCondensed matter physicsWhispering-gallery waveSpin (aerodynamics)MagnetizationScatteringCoupling (piping)SPHERESQuantum mechanicsOpticsMagnetic fieldFerromagnetismMaterials scienceThermodynamicsAstronomyMetallurgyMechanical and Optical ResonatorsPhotonic and Optical DevicesQuantum optics and atomic interactions
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