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Anisotropic Spin-Acoustic Resonance in Silicon Carbide at Room Temperature

A. Hernández‐Mínguez, A. V. Poshakinskiy, M. Hollenbach, P. V. Santos, G. V. Astakhov

2020Physical Review Letters31 citationsDOIOpen Access PDF

Abstract

We report on acoustically driven spin resonances in atomic-scale centers in silicon carbide at room temperature. Specifically, we use a surface acoustic wave cavity to selectively address spin transitions with magnetic quantum number differences of ±1 and ±2 in the absence of external microwave electromagnetic fields. These spin-acoustic resonances reveal a nontrivial dependence on the static magnetic field orientation, which is attributed to the intrinsic symmetry of the acoustic fields combined with the peculiar properties of a half-integer spin system. We develop a microscopic model of the spin-acoustic interaction, which describes our experimental data without fitting parameters. Furthermore, we predict that traveling surface waves lead to a chiral spin-acoustic resonance that changes upon magnetic field inversion. These results establish silicon carbide as a highly promising hybrid platform for on-chip spin-optomechanical quantum control enabling engineered interactions at room temperature.

Topics & Concepts

Condensed matter physicsSilicon carbideMagnetic fieldAnisotropySpin (aerodynamics)Acoustic waveMaterials scienceSpin waveAcoustic resonanceMicrowaveSiliconResonance (particle physics)PhysicsOptoelectronicsAtomic physicsOpticsQuantum mechanicsMetallurgyThermodynamicsFerromagnetismMechanical and Optical ResonatorsQuantum and electron transport phenomenaDiamond and Carbon-based Materials Research
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