CsPbI3钙钛矿量子点的精细纯化及其高效发光二极管的研究

doi:10.6023/A20080386

化学学报 ›› 2021, Vol. 79 ›› Issue (1): 126-132.DOI: 10.6023/A20080386 上一篇

研究论文

CsPbI₃钙钛矿量子点的精细纯化及其高效发光二极管的研究

李严^a, 李金航^a, 许蕾梦^b, 陈嘉伟^a, 宋继中^a^,^*()

a 南京理工大学材料科学与工程学院新型显示材料与器件工信部重点实验室南京 210094
b 郑州大学物理工程学院材料物理教育部重点实验室郑州 450001

投稿日期:2020-08-21 发布日期:2020-10-17
通讯作者: 宋继中
作者简介:
* E-mail: songjizhong@njust.edu.cn
基金资助:
国家自然科学基金(51922049); 国家重大研发计划(2016YFB0401701); 江苏省科技厅(BK20180020); 中央高校基本科研基金(30920032102); 江苏高校优势学科建设工程项目

CsPbI₃ Perovskite Quantum Dots: Fine Purification and Highly Efficient Light-emitting Diodes

Yan Li^a, Jinhang Li^a, Leimeng Xu^b, Jiawei Chen^a, Jizhong Song^a^,^*()

a School of Materials Science and Engineering, MIIT Key Laboratory of Advanced Display Materials and Devices, Nanjing University of Science and Technology, Nanjing 210094, China
b School of Physics and Engineering, Ministry of Education Key Laboratory of Materials Physcis, Zhengzhou University, Zhengzhou 450001, China

Received:2020-08-21 Published:2020-10-17
Contact: Jizhong Song
Supported by:
the National Natural Science Foundation of China(51922049); the National Key Research and Development Program of China(2016YFB0401701); the Natural Science Foundation of Jiangsu Province(BK20180020); the Fundamental Research Funds for the Central Universities(30920032102); the Priority Academic Program Development of Jiangsu Higher Education Institutions

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摘要/Abstract

钙钛矿量子点发光二极管(QLEDs)因其色纯度高、颜色控制精准、色域广以及溶液可加工等特点, 在显示和照明等领域有着极大的应用前景. 针对红光钙钛矿CsPbI₃量子点纯化过程中相变和表面配体损失造成的荧光退化问题, 本工作发展了一种甲苯和乙酸乙酯协同的混合溶剂纯化策略, 能够避免纯化过程中的相变问题, 获得了纯立方相的CsPbI₃量子点; 此外, 进一步提出了油胺碘(OAmI)调控量子点表面态的配体补偿工艺, 解决了配体损失导致的荧光淬灭问题, 发现在引入400 μL的OAmI时, 量子点兼具高的发光效率(PLQY为70%)和优异的电学性能, 电驱动下的激子复合几率显著增加, 最终实现了亮度为3090 cd/m ²和外量子效率为15.67%的QLED. 这种钙钛矿CsPbI₃量子点精细纯化的方案对开发高效量子点材料和实现高性能光电子器件具有重要的指导意义.

关键词: 无机钙钛矿量子点, 纯化, 配体补偿, 量子点发光二极管, CsPbI3

Perovskite quantum dot light-emitting diodes (QLEDs) possess the characteristics of high color purity, precise color control, wide gamut, and solution processibility, which shows great prospects in displays and lightings. However, red CsPbI₃ quantum dots (QDs) are prone to luminescence degradation due to the thermal non-equilibrium-induced phase transition and ligand loss during the purification process. The purification of CsPbI₃ QDs is more difficult than that of CsPbBr₃ QDs. Because the ligands on the surface of the quantum dots will be lost continuously during the purification process, resulting in aggregation and transformation toδ-CsPbI₃ phase. Aiming at this problem, We prepared the CsPbI₃ QDs through a hot-injection method at 180 ℃. The original solution of the perovskite QD also contains impurities such as octadecene solvent, oleic amine, and oleic acid ligand, which will seriously affect the photoelectric properties and destroy the film. So we used different flocculation solvents and dispersion solvents to collaboratively purify the QDs. At last, our work developed a mixed-solvent purification strategy with toluene and ethyl acetate, which can avoid the phase transition during the purification process and lead to pure cubic CsPbI₃ QDs. But when we do not add the additional ligands in purification process, the photoluminescence quantum yield (PLQY) of QDs will be far less than 100%. In order to enhance the PLQY, a ligand compensation strategy of using oleylammonium iodide (OAmI) to control the surface state of QDs was proposed, which reduced the surface defects and solved the problem of luminescence quenching caused by ligand loss. We found that 400 μL OAmI enabled quantum dots to have both high PLQY of 70% and excellent electrical properties. Under electrically driven, the exciton recombination probability was significantly increased, and the CsPbI₃- based QLED achieved a maximum luminance of 3090 cd/m² and a maximum external quantum efficiency (EQE) of 15.67%. The proposed fine purification strategy of CsPbI₃ QDs has an important guiding significance for the development of high-efficiency QD materials and high-performance optoelectronic devices.

Key words: inorganic perovskite quantum dot, purification, ligand compensation, quantum dot light-emitting diodes (QLEDs), CsPbI3

引用此文

李严, 李金航, 许蕾梦, 陈嘉伟, 宋继中. CsPbI₃钙钛矿量子点的精细纯化及其高效发光二极管的研究[J]. 化学学报, 2021, 79(1): 126-132.

Yan Li, Jinhang Li, Leimeng Xu, Jiawei Chen, Jizhong Song. CsPbI₃ Perovskite Quantum Dots: Fine Purification and Highly Efficient Light-emitting Diodes[J]. Acta Chimica Sinica, 2021, 79(1): 126-132.

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图/表 5

图1. (a) 阐述CsPbI3量子点纯化过程中溶剂的影响和表面配体损失及(b) CsPbI3量子点纯化过程示意图

Figure 1. (a) Schematic illustration of the effect of solvent on CsPbI3 QDs and the surface ligand loss during the purification process, and (b) schematic diagram of CsPbI3 quantum dot purification process

图2. 采用三种絮凝溶剂获得CsPbI3量子点的光学性能: (a) XRD图, (b) CsPbI3量子点墨水无(上)和有(下)紫外光激发的照片, (c)光致发光谱和(d)荧光寿命

Figure 2. Optical properties of CsPbI3 quantum dots after purifying with different flocculating solvents: (a) XRD patterns, (b) photographs of CsPbI3 QD inks without (upper) and with (below) UV light excitation, (c) photoluminescence spectra, and (d) photoluminescence lifetime curves

图3. 采用不同分散剂制备的CsPbI3量子点的性能: (a) CsPbI3量子点墨水在无(上)和有(下)紫外光激发的照片, (b) PL光谱, (c)电流密度和(d) AFM图

Figure 3. Performance of CsPbI3 quantum dots using different dispersible solvents: (a) photographs of CsPbI3 QD inks without (upper) and with (below) UV light excitation, (b) photoluminescence spectra, (c) current density curve, and (d) AFM image

图4. (a) QLED的能级结构图, (b)使用不同分散溶剂制备器件的外量子效率与亮度关系, (c)汇总的不同纯化方法下的器件性能

Figure 4. (a) Energy level diagram of the QLED, (b) the relationship between EQE and brightness of the device with different dispersible solvents, and (c) summarization of the device performance with different purification methods T—Toluene, I—Isopropanol, E—Ethyl acetate, B—Butyl acetate, H—Hexane, O—Octane

图5. 补偿配体对量子点及QLED性能的影响: (a)加入不同种类配体时量子点的光致发光谱, (b)不同油胺碘配体浓度下量子点的光致发光谱, (c) ln(α)-hν曲线, (d)电流密度-电压曲线, (e)亮度-电压曲线以及(f)外量子效率-电流密度曲线

Figure 5. The effects of compensation ligands on QD and QLED performances: (a) the photoluminescence spectra of QDs with different types of ligands, (b) the photoluminescence spectra of QDs with different concentrations of OAmI, (c) ln(α) as a function of hν, (d) current density as a function of votalge, (e) brightness as a function of voltage, and (f) EQE as a function of current density

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CsPbI₃钙钛矿量子点的精细纯化及其高效发光二极管的研究

CsPbI₃ Perovskite Quantum Dots: Fine Purification and Highly Efficient Light-emitting Diodes

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