Sodium Assists Controlled Synthesis of Cubic Rare-Earth Oxyfluorides Nanocrystals for Information Encryption and Near-Infrared-IIb Bioimaging
Qinglai Wang, Jie Hu, Yunfei Ying, Peiyuan Wang, Fulin Lin, Yongwei Guo, Yingping Huang, Kaixin Ji, Xing Sheng Yang, Siyaqi Li, Xiaolong Liu, Haomiao Zhu
Abstract
Rare-earth oxyfluoride (REOF) colloidal nanocrystals (NCs) suffer from a low photoluminescence efficiency due to their small size with poor crystallinity and a detrimental surface quenching effect. Herein, we introduce an innovative approach that involves doping sodium ions into REOF NCs to produce monodisperse, size-controllable, well-crystallized, and highly luminescent colloidal REOF core/shell NCs. The Na + doping allows for successfully synthesizing the cubic REOF NCs with a tunable size from 6 to 30 nm. Further fabrication of the core/shell NCs doped with Na + results in enhancements up to 1062 (Ho 3+ ), 1140 (Er 3+ ), and 2212 (Tm 3+ ) folds in upconversion luminescence and 17.7 folds (Er 3+ ) in downconversion luminescence compared to that of core/shell NCs without doping Na + ions. These NCs were subsequently developed into multicolor luminescent inks, demonstrating significant potential application for information security, and used for near-infrared-IIb (NIR-IIb) (1500–1700 nm) in vivo imaging, which exhibits a high-resolution in vivo dynamic imaging capability with a signal-to-noise ratio of 5.28. These results present the way to the controlled synthesis of efficient luminescent cubic LuOF: RE 3+ /LuOF core/shell NCs, expanding the toolkit of rare-earth doped NCs in diverse applications such as advanced encoding encryption, varied fluorescence imaging, and biomedicine.