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Rare-earth-doped glasses have been demonstrated as highly promising scintillator materials, particularly for X-ray imaging applications. However, challenges such as high defect density, low luminescence efficiency, and poor spatial resolution remain, primarily attributed to high phonon energy, inefficient energy transfer (ET), and light scattering in glass materials. Herein, we report a successfully designed dual-sensitized codoped Gd-based oxyfluoride glass scintillator that can achieve high internal quantum efficiency (IQE, 97.5%), excellent X-ray luminescence (XEL) intensity (216% Bi4Ge3O12), high optical transparency (approximately 90% at 550 nm), and good radiation stability by using Tb3+ as the luminescent center, synergistically incorporating Gd3+ and Ce3+. Specifically, the optimized glass scintillator can achieve a spatial resolution of up to 32.6 lp·mm−1 for X-ray imaging, coupled with an exceptionally low detection limit of 1.03 μGy·s−1. Additionally, the developed glass scintillator enables irregular-shaped and large-scale fabrication (diameter: 5 cm) that is difficult to accomplish with conventional scintillator materials. The developed material offers a new option for developing low-cost, high-performance glass scintillators for high-resolution X-ray imaging.

This is an open access article under the terms of the Creative Commons Attribution 4.0 International License (CC BY 4.0, http://creativecommons.org/licenses/by/4.0/).
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