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Organic Cation Design of Manganese Halide Hybrids Glass toward Low‐Temperature Integrated Efficient, Scaling, and Reproducible X‐Ray Detector

Youkui Xu, Zhenhua Li, Guoqiang Peng, Fu Qiu, Zhizai Li, Yutian Lei, Yujie Deng, Haoxu Wang, Zitong Liu, Zhiwen Jin

2023Advanced Optical Materials98 citationsDOIOpen Access PDF

Abstract

Abstract Zero‐dimensional (0D) structure‐based manganese metal halides (MHs) are believed to be the most promising candidates for the next‐generation X‐ray scintillators due to their intense radioluminescence and environmental friendliness. However, low‐temperature (<180 °C), large‐area integration with more efficient X‐ray detection remains a tremendous challenge. Herein, from the perspective of cation (ionic liquids) structure design, the basic physical parameters of 0D MHs are regulated. And the calculations and experimental results demonstrate larger‐size cations that induce lower melting temperatures, larger exciton‐binding energies, larger ion migration energy, and tunable hardness, which are most desirable for MHscintillators. As a result, the champion materialHTP 2 MnBr 4 is achieved as glassy transparency wafer by low‐temperature (165 °C) melt‐quenching. Its application to X‐ray imaging features high spatial resolution (17.28 lp mm −1 ), scalability (>30 × 30 cm 2 ), and integration with strong coupling force. Furthermore, HTP 2 MnBr 4 glass with reproducible properties demonstrates a high light yield (38 000 photon MeV −1 ), excellent irradiation stability, and low detection limit (0.13 µGy s −1 ). The authors believe this work will provide guidance for MHscintillators to further commercial applications.

Topics & Concepts

Materials scienceHalideScintillatorManganeseOptoelectronicsIonRadioluminescenceYield (engineering)DetectorOpticsInorganic chemistryComposite materialMetallurgyPhysicsChemistryQuantum mechanicsPerovskite Materials and ApplicationsLuminescence Properties of Advanced MaterialsRadiation Detection and Scintillator Technologies