报 告 内 容 简 介 |
报告人简介:Yasin Orooji is a Clarivate Analytics Highly Cited Researcher (Web of Science) and a top 1% author in Environmental Science & Ecology, Chemistry, and Engineering. He is also a doctoral mentor, post-doctoral tutor, and Distinguished Professor at Zhejiang Normal University and has been listed among the Stanford-Elsevier top 2% scientists since 2021. Since 2017, he has published more than 200 SCI papers with a cumulative impact factor of about 1800 in Science, Progress in Materials Science, Nano-Micro Letters, Materials Science and Engineering R, Materials Today, Advanced Composites&Hybrid Materials, Energy Storage Materials, etc. of which about 150 were published as the first author and corresponding author, with an H index of 62 (Cited for 13936 times by about 8000 documents (7,573 Journal articles, 193 Books, 91 Conference Proceeding, 54 Book Series, 16 Theses, 5 Patents; 39 ESI top papers, including 10 hot papers). Moreover, 10 patents, one of which is the best national patent award. He has the editor, guest editor, and editorial board member record for more than 10 SCI journals such as The Innovation; Chemical Engineering Journal; EcoMat; Biofuel Research Journal; Composites Communications; International Journal of Antimicrobial Agents; Scientific Reports, etc. and reviewer of 150 SCI journals such as: Nature Communications, Science Advances, JACS, etc. Since 2012, he has had industrial experiences with DHP Engineering, A.O. Smith and Alfa Laval. He cumulatively participated in more than 69.3 million yuan of research and industrial projects, making him a unique researcher to expand top research work to industrial products. 报告内容简介:Owing to the selective chemical etching of MBenes and MXenes precursors as well as their unique intrinsic characteristics, their surface properties can be further classified as highly chemically active compounds, leading to the formation of different surface functional groups (e.g., oxygen, fluorine, or hydroxyl groups). However, the role of surface functional groups not only has a significant impact on their electrochemical and hydrophilic properties (such as ion adsorption/diffusion) but also exerts a noteworthy effect on their conductivity, work function, electronic structure, and other properties. Thus, these inherent chemical properties, robust electrochemistry, and high hydrophilicity ultimately enhance the potential applications of MBenes as a highly promising material for environmental remediation, electrocatalytic sensors, as well as energy conversion and storage. Moreover, it is well-established that the role of MBenes and MXenes in various research fields is still under development for further improvement, as sufficiently documented by my research group in the literature. This presentation aims to critically discuss the various chemical properties and versatility of MBenes/MXenes and their derivatives (e.g., hybrid composites) in all the aforementioned applications, with special emphasis on the improvement of their surface characteristics for multifunctional applications. Additionally, this presentation will highlight MBenes/MXenes and their derivative-based hybrid configurations, focusing on emerging applications such as environmental decontamination, electrochemical applications, pollutant detection (via electrocatalytic sensors and photocatalysis), as well as membrane distillation and adsorption processes. Finally, it is expected that this oral presentation will open new avenues for the effective use of MBenes in a wide range of environmental remediation, energy conversion, and storage applications as novel, robust, multifunctional, and highly efficient materials.Our group has synthesized over 200 MBene precursors, and this lecture will serve as a bridge between researchers to further advance MBenes in this field. |
