Photoluminescence studies of the charge states of nitrogen vacancy centers in diamond after arsenic ion implantation and subsequent annealing

Journal of Applied Physics Pub Date : 2024-05-17 DOI:10.1063/5.0189911

Chenyang Huangfu, Yufei Zhang, Jinchen Hao, G. Jia, Haitao Wu, Xujie Wang, Wei Wang, Kaiyue Wang

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Abstract

In this work, nitrogen vacancy (NV) centers of high nitrogen diamond implanted with arsenic ions were investigated by photoluminescence spectroscopy. The transition of the NV center charge state was discussed by the regularly changing laser excitation power and measurement temperature following high-temperature annealing. After high-temperature annealing, the amorphous layer generated by arsenic ion implantation is transformed into a graphitization layer, resulting in a decrease in the NV yield. The electric neutral NV (NV0) center and negatively charged NV (NV−) center are affected by both radiation recombination and Auger recombination with increasing laser power. Accompanied by the increasing measurement temperature, the intensities of NV centers gradually decreased and eventually quenched. In addition, the charge states of NV− and NV0 centers were undergoing a transition. The zero phonon line positions of NV centers were also red shift, it was attributed to the dominant role of electron–phonon interaction in the temperature-dependent displacement of diamond energy gaps. The full width at half maxima of NV center were broadened significantly at higher temperatures.

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砷离子植入并随后退火后金刚石中氮空位中心电荷状态的光致发光研究

这项研究利用光致发光光谱对砷离子植入高氮金刚石的氮空位（NV）中心进行了研究。通过有规律地改变高温退火后的激光激发功率和测量温度，探讨了氮空位中心电荷状态的转变。高温退火后，砷离子注入产生的非晶层转变为石墨化层，导致 NV 产率下降。随着激光功率的增加，电中性 NV (NV0) 中心和带负电的 NV (NV-) 中心都会受到辐射重组和欧杰重组的影响。随着测量温度的升高，NV 中心的强度逐渐降低并最终熄灭。此外，NV- 和 NV0 中心的电荷态也在发生转变。NV 中心的零声子线位置也发生了红移，这是因为电子-声子相互作用在金刚石能隙随温度变化的位移中起主导作用。在较高温度下，NV 中心的半最大全宽明显变宽。

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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Journal of Applied Physics

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