Ultrafast and high-resolution X-ray imaging based on zero-dimensional organic silver halides

Supersensitive and fast X-ray imaging is of great importance in medical diagnosis, industrial flaw detection, security and safety inspection, and frontier science exploration. As the core of detection devices, new generation scintillators require small self-absorption capacity, short fluorescence li...

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Published inMaterials chemistry frontiers Vol. 8; no. 18; pp. 3004 - 3016
Main Authors Zhou, Yongqiang, Wang, Zixian, Guo, linfeng, Huang, Lei, Liu, Yichen, Wu, Mengyue, Zhang, Qian, An, Kang, He, Peng, Wang, Fei, Du, Juan, Liu, Zhengzheng, Hu, Zhiping, Leng, Yuxin, Pu, Yayun, Lai, Jun’an, Tang, Xiaosheng
Format Journal Article
LanguageEnglish
Published London Royal Society of Chemistry 09.09.2024
Subjects
Diagnosis
Excitons
Flaw detection
Halides
Image resolution
Lead free
Medical imaging
Perovskites
Photoluminescence
Scintillation counters
Service life assessment
Silver halides
Temperature dependence
X ray imagery
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Summary:Supersensitive and fast X-ray imaging is of great importance in medical diagnosis, industrial flaw detection, security and safety inspection, and frontier science exploration. As the core of detection devices, new generation scintillators require small self-absorption capacity, short fluorescence lifetime, simple film-making protocol, excellent stability and non-toxicity. Herein, a new type of lead-free organic silver halide TPPAgX 2 (TPP = C 24 H 20 P and X = I, Br, and Cl) is rationally developed with a large Stokes shift (176 nm) and ultralow photoluminescence decay (3.8 ns lifetime). It achieves an ultrafast fluorescent response that is the best among all the Pb-free perovskite scintillators. Temperature-dependent PL and DFT calculations together confirm that TPPAgCl 2 follows an emission mechanism in which a triplet exciton can be rapidly upconverted via thermal activation. A series of TPPAgX 2 -based flexible scintillator films were fabricated and tested. A detection limit of 0.447 μGy air s −1 was obtained for TPPAgCl 2 , which is one order of magnitude lower than the medical X-ray diagnosis requirement. In addition, it exhibits a superior X-ray imaging resolution of 11.87 lp mm −1 . The excellent performance and simple preparation methodology are expected to be potentially applicable for large-scale manufacturing.
ISSN:2052-1537
2052-1537
DOI:10.1039/D4QM00362D