Evolution and fabrication of carbon dot-based room temperature phosphorescence materials

Traditional room temperature phosphorescence (RTP) materials usually include organometallic composites and pure organic compounds, which generally possess the disadvantages of high toxicity, high cost and complicated preparation. Carbon dots (CDs) are a new kind of luminescent material and have attracted widespread attention due to their benefits of excellent tunable emission, nice biocompatibility, cost-effectiveness, facile preparation and environmental friendliness. Since photoluminescence is an important luminescent property of carbon-based fluorescent nanomaterials, CD-based RTP materials have sparked a new research wave due to the properties of extremely long phosphorescence lifetime, large Stokes shift and high environmental sensitivity. In order to construct excellent CD-based RTP materials, many attempts have been made, and the corresponding progress has been achieved. Herein, we summarize the progress in CD-based RTP materials in recent years, mainly focusing on the outstanding contributions over the years, phosphorescence emission, phosphorescence lifetime, preparation and application of CD-based RTP materials. In particular, this review provides a comprehensive summary and analyze the outstanding contributions in the fields of the phosphorescence emission and phosphorescence lifetime of CD-based RTP materials over the years. Finally, several existing challenges and the future outlook of RTP materials based on CDs have been put forward.

Automated summary

Traditional room temperature phosphorescence (RTP) materials often have drawbacks such as high toxicity, high cost, and complicated preparation. Carbon dots (CDs) have emerged as a promising alternative due to their tunable emission, biocompatibility, cost-effectiveness, and environmental friendliness. This review highlights the progress in CD-based RTP materials, specifically focusing on their phosphorescence emission and lifetime, preparation methods, and applications. Challenges and future directions for RTP materials based on CDs are also discussed.