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Copper(I) Iodide–Hexamethylenetetramine Complex as Stable Scintillator for Free-Standing Flexible and High-Resolution X-ray Imaging Screens

Sergey A. Fateev, Anna D. Riabova, Daria E. Belikova, Anastasia V. Orlova, Eugene A. Goodilin, Alexey B. Tarasov

2025ACS Materials Letters8 citationsDOI

Abstract

The organo–inorganic coordination polymer Cu 6 I 6 (HMTA) 2 (HMTA – hexamethylenetetramine) has been explored as a scintillator for X-ray imaging applications. This material, synthesized from readily available precursors via a scalable solution-based method, exhibits high photoluminescence quantum yield (>95%) and exceptional thermal and radiation stability. Composite scintillation screens (CSS) were fabricated by embedding Cu 6 I 6 (HMTA) 2 nanoparticles into an ethylene-vinyl acetate (EVA) matrix, achieving high phosphor loading (up to 75 wt %) while maintaining mechanical flexibility. These CSS exhibited a maximum light yield of 63,500 photons/MeV and spatial resolution up to 18 lp/mm (line pairs/mm). Thin-film scintillators, produced by depositing Cu 6 I 6 (HMTA) 2 on porous membranes, achieved an even higher spatial resolution of 24.5 lp/mm but showed reduced mechanical robustness. Remarkably, Cu 6 I 6 (HMTA) 2 -based screens demonstrated superior radiation stability, retaining 95% of their initial radioluminescence intensity after exposure to high X-ray doses (∼100 Gy). These results highlight the potential of Cu 6 I 6 (HMTA) 2 as a high-performance scintillator for X-ray imaging applications.

Topics & Concepts

HexamethylenetetramineScintillatorCopperIodideX-rayMaterials scienceResolution (logic)ChemistryNanotechnologyOpticsMetallurgyPhysicsInorganic chemistryComputer scienceDetectorOrganic chemistryArtificial intelligenceMedical Imaging Techniques and ApplicationsRadiation Detection and Scintillator TechnologiesAtomic and Subatomic Physics Research