NaCl, NaCl:Al与NaCl:Ca热释光峰值温度偏移特性

杨俊; 赵修良; 陈瑞达; 侯佳斌; 侯玉苗; 贺三军; 周超; 刘丽艳

doi:10.7498/aps.73.20240231

摘要

为深入地了解纯NaCl本身及其Al和Ca掺杂变体的热释光峰值温度偏移特性, 通过第一性原理计算与热释光实验的结合方法, 探讨了掺杂如何影响晶体的电子结构, 并进一步分析热释光峰值温度的偏移机制. 计算结果显示掺杂Al后NaCl的带隙略有增加至5.20 eV, 掺杂Ca则导致带隙显著减小至0 eV, 这些掺杂不仅改变了带隙宽度, 还引入了不同的缺陷形成能, 这可能导致热释光峰值温度在较低温度出现, 且会随实验条件的变化而偏移. 通过热释光实验对理论预测结果进行了验证, 结果显示在加热速率增加时, 所有样品的热释光峰值温度均有所增加, 且NaCl:Al的变化最为显著, 从276 K增至340 K; 而在1—25 mGy剂量范围内随着辐照剂量的增加, 热释光峰值温度的增长变化较小, 尤其是NaCl:Ca仅从195 K增至202 K. 基于第一性原理的计算及热释光峰值温度偏移特性的实验研究对于不同掺杂材料的应用具有重要参考意义.

关键词:

Abstract

To gain a more in-depth understanding of the thermoluminescence peak temperature shift characteristics of pure NaCl itself and its Al and Ca doped variants, a combination of the first-principles calculations and thermoluminescence experiments is used to explore how doping affects the electronic structure of the crystal and further analyze the mechanism of peak temperature shift in thermoluminescence. The calculations indicate that doping NaCl with Al slightly increases its band gap to 5.20 eV, whereas doping with Ca reduces it dramatically to 0 eV. These changes can modify the band gap width but introduce distinct defect formation energy values. Such changes may cause the thermoluminescence peak temperature to occur at lower temperatures and shift with the change of experimental conditions. The theoretical predictions are validated through thermoluminescence experiments, showing that the thermoluminescence peak temperatures of all samples rise with heating rate increasing. Notably, the change is most significant for NaCl:Al, where the peak temperature rises from 276 to 340 K. Meanwhile, as the irradiation dose increases in a range of 1–25 mGy, the growth of the thermoluminescence peak temperature turns relatively small, especially for NaCl:Ca, the peak temperature rises only from 195 to 202 K. This comprehensive analysis of the electronic structures and defect formation energy provides an insight into the thermoluminescence behavior of NaCl crystal. Doping with Al and Ca introduces mid-gap states that act as traps for charge carriers. These traps play a crucial role in the thermoluminescence process, capturing electrons during irradiation and releasing them upon heating, which leads to the observed luminescence. The presence of these traps and their specific energy levels relative to the conduction and valence bands directly influences the temperature at which the peak luminescence occurs. In addition, this study explores how the changes of electronic structure, caused by doping, affects the recombination process of charge carriers, which is very important for the thermoluminescence phenomenon. It also investigates the influence of external factors, such as the rate of heating and the dose of irradiation, on the stability and shift of thermoluminescence peak temperature. These findings emphasize the complex interactions between material composition, structural defects, and experimental conditions in determining the thermoluminescence characteristics of doped NaCl crystals. The results of this research are of great significance for the application of doped materials in various fields, including radiation dosimetry and solid-state lighting. The ability to manipulate the thermoluminescence peak temperatures through doping opens up new ways for designing materials with tailored luminescence properties for specific applications. This study not only deepens our understanding of the fundamental mechanisms of thermoluminescence but also highlights the potential of first-principles calculations combined with experimental analysis in the development of new materials with desired optical and electronic characteristics.

Keywords:

作者及机构信息

1.
南华大学核科学技术学院, 衡阳　421001

2.
南华大学, 先进核能技术设计与安全教育部重点实验室, 衡阳　421001

通信作者: 赵修良, zhaoxiul@usc.edu.cn

基金项目: 国家自然科学基金(批准号: 12005098)和湖南省教育厅科学研究项目(批准号: 19A431)资助的课题.

Authors and contacts

1.
School of Nuclear Science and Technology, University of South China, Hengyang 4211001, China

2.
Key Laboratory of Advanced Nuclear Energy Design and Safety, Ministry of Education, University of South China, Hengyang 421001, China

Corresponding author: Zhao Xiu-Liang, zhaoxiul@usc.edu.cn

Funds: Project supported by the National Natural Science Foundation of China (Grant No. 12005098) and the Scientific Research Project of Education Bureau of Hunan Province, China (Grant No. 19A431).

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参考文献

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[15]	Ye L, Liang Y 2024 Phys. B: Condens. Matter 674 415579 Google Scholar
[16]	马天慧, 雷作涛, 张晓萌, 付秋月, 布和巴特尔, 朱崇强, 杨春晖 2022 物理学报 71 227101 Google Scholar Ma T H, Lei Z T, Zhang X M, Fu Q Y, Bu H B T E, Zhu C Q, Yang C H 2022 Acta Phys. Sin. 71 227101 Google Scholar
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施引文献

图 1 超胞64原子模型　(a) NaCl; (b) NaCl:Al; (c) NaCl:Ca

Fig. 1. Supercell 64-atom models: (a) NaCl; (b) NaCl:Al; (c) NaCl:Ca.

下载: 全尺寸图片幻灯片

图 2 能带及总态密度分布　(a) NaCl; (b) NaCl:Al; (c) NaCl:Ca

Fig. 2. Band structure and total density of states distribution: (a) NaCl; (b) NaCl:Al; (c) NaCl:Ca.

下载: 全尺寸图片幻灯片

图 3 不同加热速率下T_max变化曲线

Fig. 3. T_max variation curves at different heating rates.

下载: 全尺寸图片幻灯片

图 4 不同辐照剂量下T_max变化曲线

Fig. 4. T_max variation curves at different radiation doses.

下载: 全尺寸图片幻灯片

表 1 Al和Ca掺杂引入的缺陷类型及形成能

Table 1. Types of defects and their formation energies introduced by Al and Ca doping.

缺陷类型形成能/eV

V_Na 2.81

Al_Na –78.25

Al_i –104.34

Ca_Na –60.55

Ca_i –85.45

下载: 导出CSV

[1]	吴丽, 王倩, 李国栋, 窦巧娅, 吉旭 2016 物理学报 65 037802 Google Scholar Wu L, Wang Q, Li G D, Dou Q Y, Ji X 2016 Acta Phys. Sin. 65 037802 Google Scholar
[2]	张欣熠, 王猛, 谷懿, 王勇, 葛良全, 张庆贤, 李潇潇 2023 原子能科学技术 58 471 Google Scholar Zhang X Y, Wang M, Gu Y, Wang Y, Ge L Q, Zhang Q X, Li X X 2023 At. Energy Sci. Technol. 58 471 Google Scholar
[3]	Rahimzadeh N, Zhang J, Tsukamoto S, Long H 2023 Radiat. Meas. 161 106899 Google Scholar
[4]	Rezazadeh F, Negarestani A, Sina S, Farajzadeh E, Karari B 2023 Radiat. Prot. Dosim. 199 116 Google Scholar
[5]	Sekar N 2022 Opt. Mater. 134 113073 Google Scholar
[6]	Toktamış H, Hatib M, Kılıç H İ, Çanakçı H 2022 Appl. Radiat. Isot. 190 110462 Google Scholar
[7]	Furetta C, Kitis G 2004 J. Mater. Sci. 39 2277 Google Scholar
[8]	Bos A J J 2017 Materials 10 1357 Google Scholar
[9]	Brovetto P, Delunas A, Maxia V, Salis M, Spano G 1991 Nuovo Cimento Soc. Ital. Fis. , D 13 1293 Google Scholar
[10]	李永涛, 孟凡萍, 徐硕, 刘卉昇, 张学建, 刘景和, 李春, 曾繁明 2021 硅酸盐学报 49 743 Google Scholar Li Y T, Meng F P, Xu S, Liu H S, Zhang X J, Liu J H, Li C, Zeng F M 2021 J. Chin. Ceram. Soc. 49 743 Google Scholar
[11]	Hernandez-Medina A, Negron-Mendoza A, Ramos-Bernal S, Colin-Garcia M 2013 Radiat. Meas. 56 369 Google Scholar
[12]	Bernal R, Cruz-Vázquez C, Brown F, Tostado-García W, Pérez-Salas R, Castaño V M 2014 Electron. Mater. Lett. 10 863 Google Scholar
[13]	李哲旭, 李新换, 贺三军, 周芷千, 刘丽艳, 于万瑭, 赵修良 2022 物理学报 71 137801 Google Scholar Li Z X, Li X H, He S J, Zhou Z Q, Liu L Y, Yu W T, Zhao X L 2022 Acta Phys. Sin. 71 137801 Google Scholar
[14]	谢东, 冷永祥, 黄楠 2013 物理学报 62 198103 Google Scholar Xie D, Leng Y X, Huang N 2013 Acta Phys. Sin. 62 198103 Google Scholar
[15]	Ye L, Liang Y 2024 Phys. B: Condens. Matter 674 415579 Google Scholar
[16]	马天慧, 雷作涛, 张晓萌, 付秋月, 布和巴特尔, 朱崇强, 杨春晖 2022 物理学报 71 227101 Google Scholar Ma T H, Lei Z T, Zhang X M, Fu Q Y, Bu H B T E, Zhu C Q, Yang C H 2022 Acta Phys. Sin. 71 227101 Google Scholar
[17]	Gillani S S A, Ashraf U, Zeba I, Shakil M, Rafique M, Ahmad R, Maqsood A 2021 Eur. Phys. J. Plus 136 1065 Google Scholar
[18]	Bekker T B, Yelisseyev A P, Solntsev V P, Davydov A V, Inerbaev T M, Rashchenko S V, Kostyukov A I 2021 Cryst. Eng. Comm 23 6599 Google Scholar
[19]	Cruz-Zaragoza E, Ortiz A, Furetta C, Flores J C, Hernández A J, Murrieta S H 2011 Appl. Radiat. Isot. 69 334 Google Scholar
[20]	Bailey R M 2001 Radiat. Meas. 33 17 Google Scholar

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NaCl, NaCl:Al与NaCl:Ca热释光峰值温度偏移特性