材料科学
发光
固溶体
荧光粉
兴奋剂
调制(音乐)
光电子学
热稳定性
焊剂(冶金)
Crystal(编程语言)
强度(物理)
发射强度
热的
蓝移
辐射通量
分析化学(期刊)
光致发光
领域(数学)
工作(物理)
晶体生长
化学工程
纳米技术
光学
理论(学习稳定性)
晶体结构
衍射
作者
Chenchen Rong,Shuai Wei,Sida Shen,Zeyu Lyu,Xiaowei Zhang,Tinghui Cai,Yuze Lu,Mengjie Zhou,Hongpeng You
标识
DOI:10.1002/adom.202503612
摘要
Abstract During the development process of near‐infrared pc‐LEDs, Cr 3+ ‐doped near‐infrared phosphors have demonstrated an instrumental role. This work proposes a new approach in which the combined effects of Bi 3+ ‐La 3+ solid solution engineering and flux modulator regulation greatly increase the luminescence intensity and thermal stability of Cr 3+ . The solid solution Bi 2+y La 1‐y GaSb 2 O 11 :Cr 3+ has a tunable crystal structure, where the Bi/La ratio directly affects the luminescence intensity and thermal stability of Cr 3+ . Increased Bi 3+ substitution weakens crystal field splitting, inducing a systematic blueshift of emission peaks from 855 to 840 nm. Furthermore, optimized flux doping types and concentrations provide secondary enhancement of near‐infrared emission intensity. Finally, the near‐infrared phosphor‐converted LED (pc‐LED) device, fabricated by integrating Bi 2.8 La 0.2 GaSb 2 O 11 :Cr 3+ with a 460 nm blue LED chip, exhibits stable near‐infrared output and demonstrates outstanding performance in applications such as biological tissue imaging, organic compound analysis, and information encryption. This study not only provides a series of novel Cr 3+ ‐activated near‐infrared phosphors but also offers enhanced strategies and application paradigms for tunable Cr 3+ emission.
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