放射发光
材料科学
闪烁体
无定形固体
分子间力
水下
光电子学
荧光
卤化物
光学
光子
纳米技术
Crystal(编程语言)
分子动力学
纳米金刚石
荧光寿命成像显微镜
理论(学习稳定性)
光致发光
准分子
作者
Siqi Yuan,qiangwen Qiu,Guanghuan Shao,Lingqiang Meng,Jingyan Liu,Yuanji Ye,Hao Yan,Meili Xu,Hongming Chen,Hong Meng,Mei‐Jin Lin
摘要
ABSTRACT Thermally activated delayed fluorescence (TADF) metal‐organic complexes offer near‐unity exciton utilization and strong X‐ray absorption, yet achieving transparent glassy TADF materials that simultaneously maintain high radioluminescence efficiency and structural stability remains challenging. Herein, we introduce an “intramolecular‐rigidity intermolecular‐flexibility” design strategy that enables glass formation while preserving TADF characteristics in Copper(I) halide complexes. A rigid diphenyl‐2‐pyridylphosphine (dppy) anchors the [Cu 2 I 2 ] core, suppressing geometrical distortion in the amorphous state, whereas functionalized triphenylphosphine ligands (R‐PPh 3 , R = H, F, Me, OMe) tune intermolecular interactions and promote vitrification, yielding a family of Cu(I)‐based TADF glasses (CuR‐G). The coordination‐stabilized molecular framework sustains efficient TADF in the glassy state, affording relative light yields exceeding 50 000 photons MeV −1 . Among them, CuOMe‐G exhibits weakened intermolecular coupling, enabling low‐temperature vitrification, high optical transparency, and high‐resolution static X‐ray imaging up to 28.5 lp mm −1 . Notably, the exceptional aqueous stability of CuOMe‐G—retaining nearly constant radioluminescence after 10 days of immersion—allows real‐time underwater X‐ray imaging of living organisms under low‐dose conditions, establishing a rare scintillator platform that integrates glass‐state TADF, environmental resilience, and dynamic imaging capability. This work provides a generalizable molecular‐locking approach for developing high‐performance amorphous scintillators.
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