材料科学
发光
光电子学
透射率
发光二极管
显色指数
量子效率
光致发光
光学
无定形固体
荧光粉
青色
热稳定性
白光
二极管
光学玻璃
热的
色温
彩色凝胶
可见光谱
发光效率
带隙
光发射
电致发光
去玻璃化
发射强度
作者
Junyu Chen,Yuheng Mei,Huihui Lin,Lianjie Li,Hai Guo
标识
DOI:10.26599/jac.2026.9221286
摘要
Abstract Eu2+-doped glass has attracted considerable interest due to its dual functionality in X-ray imaging and white light-emitting diodes (LEDs). However, the amorphous nature of glass restricts the improvement of the luminescent efficiency of Eu2+-doped glass. Here, four strategies, including selecting oxyfluoride glass as the host, regulating optical basicity, introducing appropriate heavy elements, and adding carbon powders as reducing agents, were proposed to prepare Eu2+-doped glass with excellent X-ray excited luminescence (XEL) and efficient blue–cyan photoluminescence (PL). For scintillating performance, the optimal glass exhibits a record-breaking XEL intensity reaching 308% of that of commercial Bi4Ge3O12. Together with high transmittance (> 80% at 472 nm), linear response to X-ray dose, and low detection limit (6.0 μGyair/s), the imaging resolution based on optimal glass reaches 24 lp/mm. For PL performance, the intense blue–cyan light of the optimal glass possesses a high external quantum efficiency of 71.2% and excellent thermal stability (the PL intensity at 423 K is 57.7% of that at room temperature). When combined with the 400-nm chip, the optimal glass effectively fills the cyan gap and elevates the color rendering index of the white LED to 91.8. This work offers valuable guidelines and design principles for improving the XEL and PL performance of Eu2+-doped glass.
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