| INORGANIC MATERIALS AND CERAMIC MATRIX COMPOSITES |
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| A Review of Preparation and Application of Boron Nitride Quantum Dots |
| YANG Lu, WANG Zefang
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| School of Life Science, Tianjin University, Tianjin 300072, China |
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Abstract Boron nitride quantum dots area novel type of zero-dimensional nanomaterials, which have outstanding physical and chemical properties such as unique fluorescence, high thermal conductivity, chemical stability, and good biocompatibility. Boron nitride quantum dots have shown extremely broad application prospects in the fields of optoelectronics, electronic components, sensing and catalysis, biosensors, bioimaging, but their efficient preparation is still challenges. Therefore, exploring new methods for the efficient preparation of boron nitride quantum dots and further expanding their application are new research focuses in the field of nanomaterial engineering.
At present, researchers have developed two methods for preparing boron nitride quantum dots, the“top-down” and “bottom-up”. Among them, the “top-down” is currently the primary method to prepare boron nitride quantum dots. There are various types of this method, including hydrothermal method, solvothermal method, ultrasonic method, and alkali metal intercalation method. Although the “top-down” method achieves large-scale preparation of boron nitride quantum dots, most of these methods face the problems of using organic solvents, strong bases, and high temperature conditions. The “bottom-up” method uses precursor molecules containing nitrogen and boron to synthesize boron nitride quantum dots, which can achieve precise control of the structure of quantum dots, but this method is not suitable for large-scale preparation of boron quantum dots. Although the large-scale and efficient preparation of boron nitride quantum dots is still in the early stages, the existing research have laid the foundation for their efficient and large-scale controllable preparation in the future. Based on the preparation of quantum dots, many applications of boron nitride quantum dots are also in full swing, including cell imaging, fiber staining, metal ion detection, chemiluminescence sensors, fingerprint fluorescence imaging, and vitamin detection. These applied studies in turn have further stimulated the preparation of quantum dot.
This review systematically summarizes the preparation of boron nitride quantum dots in recent years, and also comprehensively summarizes and analyzes their application. Finally, we put forward ideas and prospects to promote the preparation and application of boron nitride quantum dots, with a view to provide a reference for subsequent research.
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Published: 19 January 2021
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| Fund:This work was financially supported by the National Natural Science Foundation of China (31970048,81601593). |
About author:: Lu Yang received his B.S. degree in biotechnology from Northeast Agricultural University in 2017. He is currently pursuing his master's degree at School of Life Science, Tianjin Unversity under the supervision of Prof. Zefang Wang. His research has focused on protein engineering and biological nanomaterials.
Zefang Wang received his Ph.D. degree in microbiology from the School of Life Sciences of Nankai University in 2010. During his Ph.D., he received a national scholarship to conduct a Sino-Finnish doctoral research at the VTT Finland National Technical Research Center. After he carried out postdoctoral research at the School of Medicine of New York University in 2014, he returned to China to form a research group. His research interests include protein engineering and bioactive materials. |
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2021, Vol. 35 
