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Spin-Acoustic Control of Silicon Vacancies in 4H Silicon Carbide

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arxiv 2205.15488 v1 pith:VUBI5DL3 submitted 2022-05-31 physics.app-ph cond-mat.mes-hallquant-ph

Spin-Acoustic Control of Silicon Vacancies in 4H Silicon Carbide

classification physics.app-ph cond-mat.mes-hallquant-ph
keywords acousticresonanceresonatorsiliconspinbulkhighcarbide
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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We demonstrate direct, acoustically mediated spin control of naturally occurring negatively charged silicon monovacancies (V$_{Si}^-$) in a high quality factor Lateral Overtone Bulk Acoustic Resonator fabricated out of high purity semi-insulating 4H-Silicon Carbide. We compare the frequency response of silicon monovacancies to a radio-frequency magnetic drive via optically-detected magnetic resonance and the resonator's own radio-frequency acoustic drive via optically-detected spin acoustic resonance and observe a narrowing of the spin transition to nearly the linewidth of the driving acoustic resonance. We show that acoustic driving can be used at room temperature to induce coherent population oscillations. Spin acoustic resonance is then leveraged to perform stress metrology of the lateral overtone bulk acoustic resonator, showing for the first time the stress distribution inside a bulk acoustic wave resonator. Our work can be applied to the characterization of high quality-factor micro-electro-mechanical systems and has the potential to be extended to a mechanically addressable quantum memory.

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