基于蒽的高性能深蓝“热激子”材料

发光学报 Pub Date : 2023-01-01 DOI:10.37188/cjl.20230137
Lei Xu, Yue Yu, Yuyu Pan, Bohan Wang, Lei Ying, Yuguang Ma
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引用次数: 0

摘要

蓝色OLED材料在电致发光领域起着至关重要的作用。基于高能被引态跃迁,“热激子”材料显示出优异的蓝光发射潜力。以蒽为核心构建单元,三苯基苯乙烯为弱给体,苯基氰为受体,通过调节电子的推拉能力,设计合成了新型的D - π - a结构分子TACN。扭曲的三苯基苯提供了一个高度扭曲的分子构象,有效地减弱了聚集态的猝灭效应。因此,TACN具有较高的荧光量子产率(聚集态为47%)。实验结果和理论分析表明,TACN具有“热激子”特性,且具有较大的t2 - t1间隙(1。45 eV)有效地阻碍了从t2到t1的内部转换(IC)过程,而其较小的t2 - s1能量差(0。18 eV, T 2 > S 1)便于反向系统间交叉(RISC)过程。基于TACN的非掺杂器件呈现出深蓝色发射(λ max)
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High-performance Deep Blue “Hot Exciton” Materials Based on Anthracene
: The blue OLED material plays a vital role in the field of electroluminescence. Based on high - energy ex⁃ cited state transition , the “ hot exciton ” materials show the potential of excellent blue light emitting. We designed and synthesized a novel D - π - A structure molecule TACN using anthracene as the core building unit , triphenylben⁃ zene as the weak donor and phenylcyanogen as the acceptor by adjusting the ability of pushing and pulling electrons. Distorted triphenylbenzene provides a highly distorted molecular conformation , which effectively attenuates the quenching effect in the aggregated state. Therefore , TACN exhibits a high fluorescence quantum yield ( 47% in the aggregated state ) . The experimental results and theoretical analysis show that TACN has the “ hot exciton ” character⁃ istic , and its large T 2 - T 1 gap ( 1. 45 eV ) effectively hinders the internal conversion ( IC ) process from T 2 to T 1 , while its small T 2 - S 1 energy difference ( 0. 18 eV , T 2 > S 1 ) facilitates the reverse intersystem crossing ( RISC ) process. Non - doped devices based on TACN exhibit dark blue emission ( λ max
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来源期刊
发光学报
发光学报 Physics and Astronomy-Radiation
CiteScore
1.90
自引率
0.00%
发文量
7477
期刊介绍: Chinese Journal of Luminescence (CJL), supervised by Chinese Academy of Sciences (CAS), Sponsored by Committee on luminescence of Chinese Physical Society and Changchun Institute of Optics, Fine mechanics and Physics(CIOMP)of Chinese Academy of Sciences, is an authoritatively scientific and technical periodical of China in the field of luminescence, which is read widely in providing original papers and reviews that describe recent developments on basic theory and experimental studies of excited state processes and green lighting projects. The journal was established at 1980, and named after LUMINESCENCE AND DISPLAY, then renamed as CJL in 1986.
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