General Synthesis of Carbon Dot-Based Composites with Triple-Mode Luminescence Properties and High Stability

Carbon dot (CD)-based luminescent materials have attracted great attention in optical anti-counterfeiting due to their excellent photophysical properties in response to ultraviolet-to-visible excitation. Hence, there is an urgent need for the general synthesis of CD-based materials with multimode luminescence properties and high stability; however, their synthesis remains a formidable challenge. Herein, CDs were incorporated into a Yb,Tm-doped YF3 matrix to prepare CDs@YF3:Yb,Tm composites. The YF3 plays a dual role, not only serving as a host for fixing rare earth luminescent centers but also functioning as a rigid matrix to stabilize the triplet state of the CDs. Under the excitation of 365 nm ultraviolet light and 980 nm near-infrared light, CDs@YF3:Yb,Tm exhibited blue fluorescence and green room-temperature phosphorescence of CDs and upconversion luminescence of Tm3+, respectively. Due to the strong protection of the rigid matrix, the stability of CDs@YF3:Yb,Tm is greatly improved. This work provides a general synthesis strategy for achieving multimode luminescence and high stability of CD-based luminescent materials and offers opportunities for their applications in advanced anti-counterfeiting and information encryption.

Automated summary

In this study, a new kind of carbon dot-based luminescent material was successfully synthesized and combined with a YF3 substrate to achieve multimode luminescence and high stability. This material exhibited blue fluorescence, green room-temperature phosphorescence, and upconversion luminescence under excitation of ultraviolet and near-infrared light. The stability of the material was greatly improved due to the strong protection of the YF3 substrate. This research provides a general synthesis strategy for achieving multimode luminescence and high stability of CD-based luminescent materials and opens up new opportunities for their applications in advanced anti-counterfeiting and information encryption.