荧光粉
奥斯特瓦尔德成熟
材料科学
价(化学)
发光
水溶液
离子
胶体
纳米技术
制作
光电子学
水介质
化学工程
发射强度
化学物理
理想(伦理)
纳米颗粒
工作(物理)
化学稳定性
纳米-
作者
Yunlong LEI,Xinxin Zhang,Liangliang Zhang,Liangliang Zhang,Dengkui Wang,He Shen,Guohui Pan,Hao Wu,Huajun Wu,Zhendong Hao,Ligong Zhang,Ligong Zhang,Jing Li,Longhai Shen,Jiahua Zhang
标识
DOI:10.1021/acs.chemmater.6c00255
摘要
While microlight sources are set to revolutionize the display and lighting industries, their progress is hampered by the persistent “red micro-LED gap”. Submicron K 2 SiF 6:Mn 4+ (KSFM) phosphors have emerged as ideal candidates to fill this gap. However, the rapid valence changes of Mn 4+ ions make it exceedingly difficult to synthesize these submicrometer phosphors without compromising their luminescent performance. Herein, a minimal-water aqueous system (<40 vol % water) is proposed to effectively suppress Mn 4+ valence changes for over 2 h and inhibit Ostwald ripening for more than 5 h. Concurrently, the method functionalizes KSFM with Si–O–Si polymers, yielding a hybrid material (hf-KSFM) with a unique, controllable transition between powder and colloidal states, thereby imparting solution-processability. Compared to commercial KSFM, hf-KSFM exhibits remarkable improvements: a 4-fold enhancement in Mn 4+ stability within the reaction system and vastly superior water resistance, retaining 99% of its initial emission intensity after 96 h of water immersion. Our work provides a one-pot method and a viable structural design for advancing solution-processable micro-LED technology.
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