题 目:Recent Advances of 2D Metal-Complex Nanosheets
报告人:黄维扬 教授
单 位:香港理工大学
时 间:2023/12/20 10:00
地 点:嘉锡楼三层大会议室(305)
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附简介:
黄维扬,现为香港理工大学理学院院长、应用生物及化学科技学系讲座教授和欧雪明能源教授。1992年获香港大学化学专业一级荣誉学士学位;1995年获香港大学博士学位;1996至1997于国外从事博士后研究。现为香港化学会主席;长期担任多种国际期刊的编委和国际编委顾问成员:曾任Journal of Materials Chemistry C副主编(2013-2022),现任Topics in Current Chemistry主编和Journal of Organometallic Chemistry编辑。长期专注于无机化学中金属有机聚合物/配合物的设计、合成及其光电应用等领域的基础与应用研究。2014-2020年连续七年入选为汤森路透/科睿唯安高被引科学家,H-索引指数为89,获英国皇家化学会会士、香港裘槎基金会优秀科研者奖、英国皇家化学会过渡金属化学奖(首位华人)、国家教育部高校自然科学奖一等奖(排名第一)、亚洲化学会联合会杰出年青化学家奖、何梁何利基金科学与技术创新奖、国家自然科学奖二等奖(排名第一)、日本光化学学会亚洲及泛洋洲光化学科学家讲学奖、香港研资局高级研究学者奖、国家教育部长江学者讲座教授和香港青年科学院创院院士称号等奖项或称号。
报告摘要: Recent Advances of 2D Metal-Complex Nanosheets Nanosheet materials have attracted significant attention because of their unique electronic and physical properties, which derive from their two-dimensional (2D) nature. Graphene and other 2D inorganic sheet assemblies of metal chalcogenides are prominent nanosheet materials which are widely exploited in electronics, photonics, and spintronics technologies, because 2D materials possess close affinity with those used in the silicon-based electronics. Most of these nanosheets have been synthesized via exfoliation of bulk layered materials, which is a top-down method. In contrast, “bottom-up” nanosheets are generally synthesized directly from organic compounds, ligands, and/or metal ion connectors, and their composition, structure, and properties can be tuned at will by tailoring the constituent components used. This is a strong point of using bottom-up nanosheet against the top-down congener. However, application studies of the bottom-up 2D metal-complex nanosheets are still very rare. In this lecture, the bottom-up synthesis of some functional 2D metal complex nanosheets from molecular precursors will be presented which can be monometallic or bimetallic in nature. Both single-layer and multilayer 2D nanosheets will be developed depending on the fabrication method (i.e. gas-liquid or liquid-liquid interfacial synthesis). The ligand structure can be easily altered in terms of the spacer group and the number of arms. The metal complexes can be modified to show significant -conjugation and intense absorptions in the visible and near-infrared region, which will be useful for the construction of photoresponsive and semiconductive nanosheets. The resulting nanosheets are shown to find wide applications in optoelectronics and catalysis.
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报告网页链接如下:黄维扬教授学术报告链接