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Phase Control via Composite Encapsulation for Ultra‐Stable, High‐Resolution Organic Manganese Halide Scintillator Array

Yuanfan Wen, Yafeng Xu, Xi Zhang, Tengyue He, Murilo Calil Faleiros, Xudong Hu, Jianxin Wang, Wentao Wu, Issatay Nadinov, Qingsong Hu, Shumei Wang, Youyou Yuan, Bashir E. Hasanov, Simil Thomas, Osman M. Bakr, Husam N. Alshareef, Omar F. Mohammed

2025Advanced Materials7 citationsDOI

Abstract

Abstract Organic‐inorganic metal halide glasses (OIMHGs) are promising materials for high‐resolution X‐ray imaging due to their transparency and tunable properties. However, their practical applications are severely limited by a transition from the glassy state to a polycrystalline phase under ambient conditions, leading to significant optical and performance degradation. Herein, the underlying mechanism of the rapid glass‐to‐crystal transition in methyltriphenylphosphonium‐based hybrid materials (MTP) 2 MnBr 4 is systematically investigated through X‐ray absorption fine structure (XAFS) measurements, X‐ray scattering analysis, and ab initio molecular dynamics simulations. For the first time, it is demonstrated that this transition is driven by the water molecules, which significantly influence the spatial arrangement of the organic (MTP + ) and inorganic ([MnBr 4 ] 2− ) components within the materials framework. To address the severe instability of this X‐ray imaging glass in air, a novel composite encapsulation strategy is developed that integrates quartz glass layers with a waterproof parylene polymer coating. Consequently, the glass‐to‐crystal transition is substantially suppressed, enhancing the stability of the synthesized glass by over 100 times. This improvement enabled the material to maintain a spatial resolution of 26.3 lp mm −1 for more than twelve months. These findings underscore the critical role of environmental stability strategies in enhancing OIMHG‐based scintillators for next‐generation X‐ray imaging applications.

Topics & Concepts

Materials scienceHalideComposite numberHybrid materialScintillatorPhase transitionGlass transitionPolymerCrystalliteNanotechnologyChemical engineeringOptoelectronicsTransition metalScatteringNanoscopic scaleLight scatteringNanoparticleAmorphous solidManganeseAbsorption (acoustics)Direct imagingChemical stabilityDynamic light scatteringPhase (matter)Molecular dynamicsAtomic and Subatomic Physics ResearchRadiation Detection and Scintillator TechnologiesLuminescence Properties of Advanced Materials
Phase Control via Composite Encapsulation for Ultra‐Stable, High‐Resolution Organic Manganese Halide Scintillator Array | Litcius