放射发光
闪烁体
材料科学
闪烁
光致发光
卤化物
光电子学
量子产额
产量(工程)
锰
光子
制作
复合数
光学
金属卤化物
金属
光子学
Crystal(编程语言)
发光
聚合物
作者
X. Chen,Xue Zhao,Liping Feng,Jie Su,Hui Peng,Fei Chen,Zhou Yang,Xing Guo,Zhenhua Lin,Jingjing Chang,JinCheng Zhang,Yue Hao
标识
DOI:10.1002/adom.202503834
摘要
Abstract Hybrid manganese metal halides have emerged as promising candidates for next‐generation X‐ray scintillators due to their intense radioluminescence and environmental friendliness. However, challenges in cation engineering and scalable fabrication hinder the development of high‐resolution, large‐area, and flexible scintillator screens. Herein, a novel zero‐dimensional organic‐inorganic manganese (II) halide, denoted as (C 25 H 30 P) 2 MnBr 4 , is designed featuring sterically bulky triphenylphosphonium cations that synergistically enhance the photoluminescence quantum yield (PLQY = 99.2%) and radioluminescence efficiency. The (C 25 H 30 P) 2 MnBr 4 single crystal exhibits outstanding scintillation properties, exhibiting a record‐high light yield of 85 000 photons MeV −1 , an excellent linear response to X‐ray dose rate (5.52 µGy air s −1 to 1.13 mGy air s −1 ), and an ultra‐low detection limit of 25 nGy air s −1 . Furthermore, a flexible free‐standing (C 25 H 30 P) 2 MnBr 4 ‐thermoplastic polyurethane (TPU) composite film is demonstrated, fabricated via a room‐temperature in situ strategy. This film achieves an ultra‐large active area (>9000 mm 2 ), uniform transparency, and exceptional mechanical flexibility. The (C 25 H 30 P) 2 MnBr 4 ‐TPU yielded a high spatial resolution of 13.4 lp mm −1 while achieving high‐quality imaging of complex 3D objects under low‐dose X‐ray irradiation. This work establishes a generalizable framework for designing large‐area and high‐resolution scintillators through cation engineering and polymer matrix integration, opening new avenues for next‐generation flexible X‐ray imaging technologies.
科研通智能强力驱动
Strongly Powered by AbleSci AI