6H-SiC中子辐照肿胀高温回复及光学特性研究

doi:10.15541/jim20220609

无机材料学报 ›› 2023, Vol. 38 ›› Issue (6): 678-686.DOI: 10.15541/jim20220609

6H-SiC中子辐照肿胀高温回复及光学特性研究

张守超¹(), 陈洪雨¹, 刘洪飞¹, 杨羽¹, 李欣², 刘德峰²

1.天津城建大学理学院, 天津 300384
2.北京长城航空测控技术研究所状态监测特种传感技术航空科技重点实验室, 北京 101111

收稿日期:2022-10-17 修回日期:2022-12-26 出版日期:2023-02-07 网络出版日期:2023-02-07
作者简介:张守超(1982-), 副教授. E-mail: zhshch@tcu.edu.cn
基金资助:
天津市自然科学基金(20YDTPJC01540);天津市研究生科研创新项目(2021YJSO2S20);国防项目(KJ-2021-01)

High Temperature Recovery of Neutron Irradiation-induced Swelling and Optical Property of 6H-SiC

ZHANG Shouchao¹(), CHEN Hongyu¹, LIU Hongfei¹, YANG Yu¹, LI Xin², LIU Defeng²

1. School of Science, Tianjin Chengjian University, Tianjin 300384, China
2. Aviation Key Laboratory of Science and Technology on Special Condition Monitoring Sensor Technology, Beijing Changcheng Aeronautic Measurement and Control Technology Research Institute, Beijing 101111, China

Received:2022-10-17 Revised:2022-12-26 Published:2023-02-07 Online:2023-02-07
About author:ZHANG Shouchao (1982-), associate professor. E-mail: zhshch@tcu.edu.cn
Supported by:
Natural Science Foundation of Tianjin(20YDTPJC01540);Postgraduate Innovation Project of Tianjin(2021YJSO2S20);National Defence Project(KJ-2021-01)

摘要/Abstract

摘要：

高能粒子轰击不可避免地会造成SiC材料内部缺陷的产生、积累, 晶格紊乱等, 导致其物理性能的显著变化, 继而影响基于SiC材料的半导体器件使用寿命。因此, 有必要对SiC在不同的辐射环境下的损伤行为进行系统研究。本工作对6H-SiC中子辐照肿胀高温回复及光学特性开展研究, 辐照剂量范围5.74×10¹⁸~1.27×10²¹ n/cm², 退火温度在500~1650 ℃。利用X射线单晶衍射技术分析测试样品的晶体结构及晶胞参数, 结果表明: SiC仍为六方结构, 晶体未发生非晶化, 晶格肿胀及高温回复行为具有各向同性特征, 表明辐照缺陷以点缺陷为主。本征缺陷及辐照缺陷均可引入缺陷能级, 空位型缺陷是缺陷能级引入的主要因素。缺陷能级导致SiC吸收带边红移, 带隙宽度降低, 光吸收增强。利用吸收光谱、光致发光谱和拉曼光谱, 并结合第一性原理计算对缺陷能级分布开展研究, 结果表明硅空位在价带顶上方引入了新的缺陷能级, 而碳空位则是在导带底下方引入了新的缺陷能级。未辐照晶体在1382和1685 nm红外波段光吸收以及550 nm光发射主要源于本征碳空位及其相关缺陷构型; 辐照SiC晶体在415、440和470 nm处的发光主要源于辐照产生的硅空位及其相关缺陷构型。研究还利用电荷态和缺陷能级分布对SiC晶体发光机理行了讨论。

关键词: X射线单晶衍射, 拉曼光谱, 第一性原理, 退火, 带隙调控, 缺陷

Abstract:

High energy particle bombardment of silicon carbide can lead to the accumulation of defects and lattice disorder, which can negatively affect physical property and reduce lifetime of SiC devices. Thus, it is essential to systematically study the damage of SiC in different radiation environment. Herein, 6H-SiC was irradiated by neutrons at the fluence of 5.74×10¹⁸, 1.74×10¹⁹, 2.58×10²⁰ and 1.27×10²¹ n/cm², and then annealed. Changes in lattice parameters from post-irradiation isochronal annealing for 30 min in the range of 500-1650 ℃ were measured using X-ray single crystal diffraction. The results showed that the lattice swelling and recovery behavior were isotropic. Based on the swelling data, it was concluded that the neutron irradiation-induced defects in 6H-SiC were primarity point defects. Both intrinsic and irradiation defects can introduce defect energy levels, which were mainly caused by vacancies and led to the absorption band edge redshift and band gap narrowing of SiC. The defect energy levels of these vacancies and vacancy-associated defects were determined by absorption spectra, luminescence spectra and Raman spectra. Experiments and first principles calculation showed that the silicon vacancies introduced defect levels above the valence band, while the carbon vacancies introduced levels below the conduction band. The infrared absorption at 1382 nm and 1685 nm and the emission at 550 nm of unirradiated 6H-SiC were mainly due to the intrinsic carbon vacancies. The luminescence of post-irradiated SiC at 415, 440 and 470 nm was mainly due to the silicon vacancy produced by irradiation and its related defect configuration. All above data revealed the luminescence mechanism of SiC based on the charge state and the defect energy level distribution.

Key words: X-ray single crystal diffraction, Raman spectra, first principle, annealing, band gap tuning, defect

中图分类号:

O734

张守超, 陈洪雨, 刘洪飞, 杨羽, 李欣, 刘德峰. 6H-SiC中子辐照肿胀高温回复及光学特性研究[J]. 无机材料学报, 2023, 38(6): 678-686.

ZHANG Shouchao, CHEN Hongyu, LIU Hongfei, YANG Yu, LI Xin, LIU Defeng. High Temperature Recovery of Neutron Irradiation-induced Swelling and Optical Property of 6H-SiC[J]. Journal of Inorganic Materials, 2023, 38(6): 678-686.

图/表 9

图1 晶胞参数随中子辐照剂量变化

Fig. 1 Change of lattice parameter as a function of neutron fluence

图2 单晶衍射图案和晶胞参数随退火温度变化

Fig. 2 Diffraction pattern of crystal and lattice parameters recovery by isochronal annealing at different temperatures (a) 6H-SiC crystal; (b) a-axis change; (c) c-axis change; (d) Lattice volume change

图3 SiC晶体吸收光谱随退火温度变化(a)及625 nm吸收峰的电子跃迁路径分布(b)

Fig. 3 Absorption spectra of SiC changed with annealing temperature (a) and mechanism of absorption at 625 nm and electron transition path (b) Colorful figures are available on website

图4 不同温度退火的SiC晶体透光变化

Fig. 4 Variation of SiC transparency after being annealed at different temperature

图5 6H-SiC晶体禁带随退火温度的变化

Fig. 5 Plot for change of bandgap of 6H-SiC as a function of annealing temperature

图6 理想晶体和不同本征缺陷6H-SiC的总态密度和分波态密度分布

Fig. 6 Distribution of the density states of the ideal and 6H-SiC with different intrinsic defects (a) Total density of states; (b) Partial density of states

图7 不同温度退火的6H-SiC的光致发光谱

Fig. 7 Photoluminescence spectra of 6H-SiC after being annealed at different temperatures (a) Emission spectra; (b) Excitation spectra. λex=340 nm, λem=550 nm

图8 6H-SiC的拉曼光谱

Fig. 8 Raman spectra of 6H-SiC (a) Unirradiated; (b) Irradiated; (c) Annealed at 600 ℃; (d) Annealed at 1650 ℃. ×1, ×50 and ×100 represents Raman spectral intensity amplification of 1, 50, and 100 times, respectively. Colorful figures are available on website

图9 6H-SiC的光致发光机理

Fig. 9 Photoluminescence mechanism of 6H-SiC

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6H-SiC中子辐照肿胀高温回复及光学特性研究

High Temperature Recovery of Neutron Irradiation-induced Swelling and Optical Property of 6H-SiC

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