碳化硅中应力控制的零场自旋分裂

arXiv: Materials Science Pub Date : 2020-12-08 DOI:10.1063/5.0040936

I. Breev, A. Poshakinskiy, V. Yakovleva, S. Nagalyuk, E. N. Mokhov, R. Hübner, G. Astakhov, P. Baranov, A. Anisimov

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引用次数: 7

摘要

本文报道了室温下静态机械变形对碳化硅中硅空位零场分裂的影响。我们使用生长条件下变形的AlN/6H-SiC异质结构，利用空间分辨共聚焦拉曼光谱监测应力分布与异质界面距离的关系。通过光探测磁共振测量6H-SiC中V1/V3和V2中心的零场分裂，发现异质界面与体值相比发生了显著变化。这种方法可以明确地确定自旋变形相互作用常数，V1/V3中心为$0.75 \，\mathrm{GHz}$， V2中心为$0.5 \，\mathrm{GHz}$。考虑到AlN的压电性，我们的研究结果提供了一种通过变形实现SiC中自旋跃迁能按需微调的策略。

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Stress-controlled zero-field spin splitting in silicon carbide

We report the influence of static mechanical deformation on the zero-field splitting of silicon vacancies in silicon carbide at room temperature. We use AlN/6H-SiC heterostructures deformed by growth conditions and monitor the stress distribution as a function of distance from the heterointerface with spatially-resolved confocal Raman spectroscopy. The zero-field splitting of the V1/V3 and V2 centers in 6H-SiC, measured by optically-detected magnetic resonance, reveal significant changes at the heterointerface compared to the bulk value. This approach allows unambiguous determination of the spin-deformation interaction constant, which turns out to be $0.75 \, \mathrm{GHz}$ for the V1/V3 centers and $0.5 \, \mathrm{GHz}$ for the V2 centers. Provided piezoelectricity of AlN, our results offer a strategy to realize the on-demand fine tuning of spin transition energies in SiC by deformation.

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arXiv: Materials Science

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