Donghua University, China
Biography:
Ye Chen has completed his PhD from Donghua University in China at 2011 and postdoctoral studies from King Abdullah University of Science and Technology (KAUST) in Saudi Arabia. Now he joined into College of Material Science and Engineering in Donghua University as an Associate Professor. His research is about biomaterials science, the preparation of advanced Nano composites and its application. Now as a subject head, he participated in a National key R & D Program of Ministry of Science and Technology of China. He has got more than 10 patents including US patents, and has published more than 30 papers in ACS Appl.Mater.Interfaces, Adv. Mater. Interfaces, Polymer etc. This work was supported by the National Natural Science Foundation of China and Shanghai Pujiang Program.
Graphene has received extensive attention and wide application in electrical device, energy materials, and biomaterials, due to its large surface area and excellent performance in mechanical, thermal conductive, electrical and optical properties. All the properties depend on the distinct structure of graphene, such as layers, scale, surface defects. However, the difficulty of fast and efficient preparing high-quality graphene limits its industrial applicati on. In this study, a conjugated IL named 1-methyl-3-pyrenemethylimidazolium hexafluorophosphate ([MPIM][PF6]) was synthesized and used to exfoliate graphite into grapheme with the assistance of microwave irradiation. Owing to the cation-π interaction and additional strong π-π interaction between [MPIM][PF6] and graphite, large-scale, defect free and few-layer high-quality graphene (GNPIL) was efficiently prepared. And the results show that a relatively high yield of 40% is obtained. Moreover, the GNPIL has good dispersability and conductivity due to the presence of ionic liquids in the interlayer. The high-quality GNPIL could be dispersed in organic solvent homogeneously and stably with a high content, which is beneficial for its further applications. The AFM results show that the ionic liquid-functionalized graphene has a thickness of 4 to 6 nm and 5 to 10 layers. FTIR curves further prove ionic liquids exist in the graphene sheets. UV-Vis is used to characterize the dispersibility of the graphene in the organic solvent. Furthermore, this GNPIL is used to improve the conductivity and mechanical property of polymer. Compared with the resistivity of pure polymer, the resistivity of the composites decreases by eleven orders of magnitude, when 0.75 wt% graphene is added. With the increase of graphene content, the tensile strength of the composites increases gradually and when the content is 0.75 wt%, the tensile strength reaches the maximum, after that, it decreases. However, the thermal properties of composites do not change too much after the addition of graphene, so the composite still maintains good thermal properties.