铜
发光
光致发光
量子产额
材料科学
闪烁
光电子学
卤化物
闪烁体
光子
离子
产量(工程)
荧光粉
激子
制作
量子点
联轴节(管道)
放射发光
纳米颗粒
光学
Crystal(编程语言)
半导体
纳米技术
水下
无机化学
限制
离子交换
分析化学(期刊)
化学
量子效率
作者
Xinjiang Zhan,Jie Cao,Le Dong,Ye Xun,Chen Ya,Yue Wang,Bing Chen,Shujuan Liu,Xiuwen Xu,Qiang Zhao
标识
DOI:10.1002/lpor.202503085
摘要
ABSTRACT Organic–inorganic hybrid copper halides, with exceptional optoelectronic properties encoded in their highly tunable crystal structure, are emerging as promising candidates for next‐generation scintillators. However, achieving both high light yield and fast luminescence decay in copper halides remains a significant challenge, limiting their application in real‐time X‐ray imaging. Here, a simple yet effective ion exchange approach is developed to enable rapid conversion of (MeEn) 2 Cu 4 Br 6 (MeEn = 3‐methylbut‐2‐enyl(triphenyl)phosphanium) to (MeEn) 2 Cu 4 I 6 , resulting in a near‐unity photoluminescence quantum yield (PLQY), a 1.7‐fold increase in light yield (39700 photons MeV −1 ), and a 15‐fold reduction in luminescence decay time (2.4 µs). Mechanistic investigations reveal that the enhanced scintillation properties arise from reduced lattice distortion, appropriately weakened electron‐phonon coupling, and strong spin–orbit coupling induced by the heavy iodine atom. Beyond (MeEn) 2 Cu 4 X 6 , this approach is applicable to a variety of copper halides, leading to consistent improvements in photophysical performance. Finally, by embedding (MeEn) 2 Cu 4 I 6 with a polymer matrix, the resulting scintillation film is further entailed with desired flexibility and water resistance, demonstrating its capability in static, dynamic, curved, and underwater X‐ray imaging.
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