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Brightening heavily doped upconversion nanoparticles by tuning characteristics of core-shell structures

光子上转换 材料科学 兴奋剂 芯(光纤) 壳体(结构) 纳米颗粒 纳米技术 光电子学 复合材料
作者
Yangyang Niu,Zhihao Bao,Yuqin Gao,Mengchao Guo,Jing‐yao Liu,Jinjun Shao,Min Lü,Ze Yuan,Xiaoji Xie
出处
期刊:Journal of Rare Earths [Elsevier BV]
卷期号:42 (5): 947-954 被引量:33
标识
DOI:10.1016/j.jre.2023.02.022
摘要

Heavily doped upconversion nanoparticles (UCNPs) potentially have exceptional photon upconversion abilities that are promising for diverse applications, such as lasing and super-resolution microscopy. However, heavily doped UCNPs typically can only offer mediocre upconversion luminescence intensity, and there still lacks general guidelines for the design and synthesis of heavily doped UCNPs. Herein, in order to boost the upconversion luminescence of heavily doped UCNPs, we studied the influence of characteristics of the core–shell structure on heavily doped UCNPs’ upconversion luminescence. We find that some empirical guidelines derived from conventional UCNPs are not suitable for heavily doped UCNPs. Using NaYbF4:[email protected]4 core–shell UCNPs with a high concentration of Yb3+ as a representative, our studies reveal that a rather thick inert NaYF4 shell is needed to protect the UCNPs from surface quenching, and the upconversion luminescence may undergo the cooperative sensitization process, which should be due to the highly concentrated Yb3+ dopant. In addition, the upconversion luminescence of heavily doped NaYbF4:Tm UCNPs exhibits no obvious dependence on the type of inert shell. Furthermore, our results show that confining both Yb3+ and Tm3+ dopants in a thin layer (known as the δ-doping strategy) does not work well in the heavily doped UCNPs. Accordingly, we propose a NaYbF4:[email protected]4@NaYF4 core-shell-shell structure to enhance the luminescence of heavily doped UCNPs, by weakening the dissipation of excitation energy and strengthening the absorption. These findings should be helpful to establish general design principles for developing the brightest possible UCNPs that can meet the requirements of various applications.
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