荧光粉
材料科学
发光
光致发光
光电子学
猝灭(荧光)
光谱学
量子效率
声子
发射光谱
电子
发射强度
热释光
兴奋剂
分析化学(期刊)
电子顺磁共振
自发辐射
载流子
分子物理学
发光二极管
镧系元素
作者
Dilare Halmurat,Xinyu Zhang,Litipu Aihaiti,Rong-Jun Xie
标识
DOI:10.1016/j.jmat.2026.101185
摘要
This work breaks the long-standing confinement of uranium (VI) luminescence to octahedral oxides by demonstrating efficient narrowband green emission at 530 nm (FWHM = 25.7 nm) in eight-coordinate CaF 2 . This breakthrough is achieved through dynamic fluorine-oxygen coordination and defect synergy. Oxygen incorporation reconstructs [UO a F 8–a ] complexes via defect-mediated charge compensation, thereby resolving the fundamental mismatch between U 6+ and Ca 2+ sites. The optimally doped phosphor (0.1% (in mole) U 6+ ) achieves a high internal quantum efficiency of 71.1% (EQE = 28.9%). Furthermore, spectral evolution reveals three Gaussian sub-bands, which are attributed to distinct Jahn-Teller distortions correlated with U–O bond contraction. Crucially, we establish a dual-channel oxygen-delivery mechanism via CaO co-addition, which synergistically enhances the emission intensity by 150% at 15% CaO loading while preserving a narrow bandwidth of 25–27 nm. Electron paramagnetic resonance spectroscopy confirms fluorine vacancies as the key charge compensators, validating the proposed enhancement mechanism from optimized [UO a F 8–a ] coordination and suppressed nonradiative pathways. Despite the extreme thermal quenching (only 7% intensity retention at 125 °C) linked to F-vacancy phonon scattering, the ultra-narrow emission enables unique thermometric applications with a relative sensitivity of 0.4% K –1 . This work ultimately establishes a paradigm of defect-mediated coordination engineering for activating multifunctional luminescence from lanthanides and actinides in non-traditional hosts. • Breaks 100-year U 6+ emission limit via oxygen-fluorine synergy and defect-driven [UO a F 8− a ] reconstruction. • Achieves record-narrow green emission (530 nm, 25.7 nm FWHM) with 71.1% IQE via local symmetry control. • CaO-alloying strategy boosts emission by 150%, preserves narrow bandwidth, and universally suppresses quenching.
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