Theory of Spin-Acoustic Resonance for Spin-3/2 Si Vacancy with C3[math] Site Symmetry in Silicon Carbide

IF 1.5 4区物理与天体物理 Q2 PHYSICS, MULTIDISCIPLINARY

Journal of the Physical Society of Japan Pub Date : 2023-12-12 DOI:10.7566/jpsj.93.014703

Mikito Koga, Masashige Matsumoto

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Abstract

Motivated by the recent acoustically driven spin resonance studies applied to silicon vacancy centers in silicon carbide, we theoretically investigate the spin–strain interaction characterized by the defect spin-3/2 quadrupole components coupled to strain fields. Considering the C₃_v symmetry of the vacancy site beyond the spherical approximation, we clarify the effect of a deviation from the spherical symmetry on spin resonance transition rate, which can be changed by rotating a static magnetic field. The ratios of spin–strain coupling parameters can be evaluated from the anisotropic field-direction dependence of the transition rate using a standing or traveling surface acoustic wave. We also discuss the effect of the propagation direction of the acoustic wave tilted from the crystallographic mirror plane reflecting the C₃_v symmetry. The results presented here reveal the quadrupole properties inherent in spin-3/2 states and will promote the realization of the acoustically driven strain control of spin.

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碳化硅中具有 C3[math] 位点对称性的自旋-3/2 硅空位的自旋-声共振理论

受最近应用于碳化硅中硅空位中心的声学驱动自旋共振研究的启发，我们从理论上研究了以与应变场耦合的缺陷自旋-3/2 四极分量为特征的自旋-应变相互作用。考虑到空位的 C3v 对称性超出了球形近似，我们阐明了偏离球形对称性对自旋共振转换率的影响，这种影响可以通过旋转静态磁场来改变。自旋应变耦合参数的比率可以利用驻留或行进表面声波从过渡率的各向异性场方向依赖性中进行评估。我们还讨论了声波传播方向从反映 C3v 对称性的晶体学镜面倾斜的影响。本文介绍的结果揭示了自旋-3/2 态固有的四极特性，并将促进实现自旋的声驱动应变控制。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of the Physical Society of Japan 物理-物理：综合

CiteScore

3.40

自引率

17.60%

发文量

325

审稿时长

3 months

期刊介绍： The papers published in JPSJ should treat fundamental and novel problems of physics scientifically and logically, and contribute to the development in the understanding of physics. The concrete objects are listed below. Subjects Covered JPSJ covers all the fields of physics including (but not restricted to) Elementary particles and fields Nuclear physics Atomic and Molecular Physics Fluid Dynamics Plasma physics Physics of Condensed Matter Metal, Superconductor, Semiconductor, Magnetic Materials, Dielectric Materials Physics of Nanoscale Materials Optics and Quantum Electronics Physics of Complex Systems Mathematical Physics Chemical physics Biophysics Geophysics Astrophysics.