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Unidirectional microwave transduction with chirality selected short-wavelength magnon excitations

Yi Li, Tzu-Hsiang Lo, Jinho Lim, John E. Pearson, Ralu Divan, Wei Zhang, U. Welp, W. K. Kwok, Axel Hoffmann, V. Novosad

2023Applied Physics Letters14 citationsDOIOpen Access PDF

Abstract

Nonreciprocal magnon propagation has recently become a highly potential approach of developing chip-embedded microwave isolators for advanced information processing. However, it is challenging to achieve large nonreciprocity in miniaturized magnetic thin-film devices because of the difficulty of distinguishing propagating surface spin waves along the opposite directions when the film thickness is small. In this work, we experimentally realize unidirectional microwave transduction with sub-micrometer-wavelength propagating magnons in a yttrium iron garnet (YIG) thin-film delay line. We achieve a non-decaying isolation of 30 dB with a broad field-tunable bandpass frequency range up to 14 GHz. The large isolation is due to the selection of chiral magnetostatic surface spin waves with the Oersted field generated from the coplanar waveguide antenna. Increasing the geometry ratio between the antenna width and YIG thickness drastically reduces the nonreciprocity and introduces additional magnon transmission bands. Our results pave the way for on-chip microwave isolation and tunable delay line with short-wavelength magnonic excitations.

Topics & Concepts

MagnonYttrium iron garnetMicrowaveSpin waveWavelengthCoplanar waveguideWaveguideMagnonicsOptoelectronicsMaterials scienceAntenna (radio)OpticsParabolic antennaPhysicsCondensed matter physicsSpin Hall effectElectrical engineeringElectronEngineeringSpin polarizationFerromagnetismQuantum mechanicsMagneto-Optical Properties and ApplicationsMagnetic properties of thin filmsQuantum and electron transport phenomena
Unidirectional microwave transduction with chirality selected short-wavelength magnon excitations | Litcius