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国际配位及固态化学界牛人及其group简介
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为了方便对国际(不包括国内的,因为已经有帖子涉及国内的情况)配位及固态化学科研实力研究与学习,请虫子们把自己熟悉的配位及固态化学方向的牛人做一简介跟贴,非常感谢。鼓励介绍新人新组,把大家不太熟悉而又在自己所研究领域有相当实力的科学家和研究组介绍一下! 格式为: Name: University or institute: Research: Highlight or major contribute: web address: Mercouri G Kanatzidis; Northwestern University; Inorganic chemistry, solid state and coordination chemistry of chalcogenide compounds. Design of new materials, exploratory synthesis, thermoelectric materials, nanostructured materials, intermetallics, mesoporous semiconductors, phase-change materials, conducting polymers, intercalation chemistry. Presidential Young Investigator Award. National Science Foundation, 1989-1994 ACS Inorganic Chemistry Division Award: EXXON Faculty Fellowship in Solid State Chemistry, 1990 Beckman Young Investigator, 1992-1994 Alfred P. Sloan Fellow 1991-1993 Camille and Henry Dreyfus Teacher Scholar 1993-1998 Michigan State University Distinguished Faculty Award 1998 Sigma Xi 2000 Senior Meritorious Faculty Award University Distinguished Professor MSU 2001 John Simon Guggenheim Foundation Fellow 2002 Alexander von Humboldt Prize, 2003 Morley Medal, American Chemical Society, Cleveland Section, 2003. http://chemgroups.northwestern.edu/kanatzidis/ [ Last edited by jpzou on 2007-7-5 at 08:30 ] |
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再顶一个
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陈小明,男,1961年10月生于广东揭阳,1983年获中山大学理学学士学位,1986年获中山大学理学硕士学位,1992年获香港中文大学哲学博士(PhD)学位。曾在圣迭戈加州大学作访问学者,曾赴香港中文大学开展合作研究。 主要工作简历: 1986年至1989年在中山医科大学生物化学教研室工作,历任助教、讲师。 1992年7月起在中山大学化学与化学工程学院工作。 1993年12月晋升副教授,1994年12月破格晋升教授。 2000年至2004年,长江学者特聘教授。 现任化学与化学工程学院院长。 主要学术兼职: 现任中国化学会理事,中国晶体学会常务理事,中国稀土学会理事。《无机化学学报》副主编,《欧洲无机化学杂志》(Eur. J. Inorg. Chem.)国际顾委。 科研方向: 功能金属配合物和聚合金属配合物超分子体系的分子设计、合成和结构与性能研究,重点在聚合金属配合物的合成化学与晶体工程、功能金属配合物的合成化学与性能研究。 主要教学: 主要讲授《现代无机化学》和《单晶结构分析》等本科生、研究生课程。指导博士后、博士生、硕士生以及国内访问学者的科研工作。 编写教材:《单晶结构分析原理与实践》(陈小明和蔡继文合作),科学出版社,2003.9第一次印刷,2004年4月第二次印刷。 学术成绩: 1993年以来,主持国家杰出青年科学基金、国家基金委员会重点项目等国家和省部级等20余项科学基金课题。作为通讯联系人在包括美国J. Am. Chem. Soc.,Inorg. Chem.,Organometallics,Cryst. Growth & Design,德国Angew. Chem.、Chem. Eur. J.、Eur. J. Inorg. Chem.,英国Chem.Commun.,Dalton Trans.,J. Mater. Chem.,New J. Chem.和CrystEngComm等国内外杂志发表200多篇论文;应邀为Coord. Chem. Rev.撰写综述两篇,为Chem. Commun.撰写Feature Article一篇,为John Wiley出版的专著Frontiers in Crystal Engineering撰写一章。 曾作为第一完成人获广东省自然科学奖一等奖和中国高校科学技术奖二等奖,并先后获得是科技基金会“杰出青年学者奖”、第五届“中国青年科技奖”、首届“广东省优秀青年科学家奖”,以及教育部“全国优秀教师”等个人奖励。 这可是今年化学部院士的热门候选人哟,也算是配位化学界的大牛了。 |
4楼2007-07-29 08:29:39
another
★
小红豆(金币+1):感谢参与!
小红豆(金币+1):感谢参与!
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Kenneth R. Poeppelmeier; Department of Chemistry, Northwestern University; BS, University of Missouri PhD, Iowa State University Associate Editor, Inorganic Chemistry Associate Director, Northwestern University Science and Technology Center for Superconductivity Editorial Boards, Journal of Alloys and Compounds, CHEMtracks, Chemistry of Materials, Solid State Sciences Lecturer, National Science Council of Taiwan Fellow, Japan Society for the Promotion of Science Fellow, American Association for the Advancement of Science Chair, American Chemical Society Division of Inorganic Chemistry– Solid-State Chemistry Lecturer, Natural Science Foundation of China Email: krp@northwestern.edu |
2楼2007-07-05 08:42:11
自己再顶一个
★
小红豆(金币+1):thank u!
小红豆(金币+1):thank u!
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Pingyun Feng Department of Chemistry of the University of California, Riverside Research Overview: Our research interest centers on the development of synthetic methodologies to prepare novel catalytic, electronic, and optical materials. These materials integrate uniform porosity, high surface area, semiconductivity, optical property, photocatalytic, acid- or base-catalytic properties and can have a variety of possible applications. Synthesis and Characterization of Porous Materials with Controllable Morphology and Composition Microporous materials are typically crystalline oxides with uniform pore sizes from 3 to 20Å and mesoporous materials cover the pore size range from 20 to 500 Å. Our research in this area is aimed at developing new synthetic methodologies to generate nanoporous materials with unprecedented framework compositions, pore geometry and controllable morphology. The purpose is to find efficient heterogeneous catalysts for industrial chemical reactions or for energy related applications. Porous chalcogenides possess structural properties characteristic of traditional porous materials such as zeolites, but they generally have better electrical and optical properties. The integration between unform microporosity and electrical/optical properties promises new opportunities in many applications. One interesting property that was recently found is the fast ionic conductivity in a series of hydrated sulfides and selenides. They may also serve as photocatalysts for the production of hydrogen from water (see below). Synthesis and Organization of Semiconducting Clusters Quantum confinement in size and dimension can lead to chemical, electrical, and optical properties that are substantially different from those observed for the bulk material. These new properties can lead to numerous technological applications. My research group is interested in exploring new synthetic methodologies to prepare nanoclusters with simultaneous control in size, surface features, and spatial arrangements from zero to three dimensions. We are particularly interested in crystalline nanoclusters with precisely defined compositions and sizes and in their superlattices with various connectivity. One of our recent successes in this area is the synthesis of the largest Cd-S cluster (by single crystal diffraction) containing as many as 54 metal sites. Porous Semiconductors as Visible-Light Driven Photocatalyst One important application of porous semiconductors is photocatalysis for the generation of hydrogen fuel from water using visible light. Such photocatalytic process can take advantage of the unique integration of crystalline microporosity and semiconductivity in porous semiconductors. The photocatalytic reduction of water to produce hydrogen fuel has been widely studied during the past several decades, however, nearly all these studies have been confined to condensed semiconductors. So far, efficient catalysts, particular those in visible-light region are rare. We have demonstrated that porous semiconducting chalcogenides can be highly efficient photocatalysts, particularly compared with traditional condensed semiconductors. Impressively, the high activity of these porous photocatalysts does not require the use of any co-catalyst such as Pt. Ph.D., 1998, University of California, Santa Barbara Postdoctoral Fellow, 1998-2000, University of California, Santa Barbara Alfred P. Sloan Fellow, 2003-2005 Beckman Young Investigator, 2003-2006 NSF Career Award, 2004-2009 Camille Dreyfus Teacher-Scholar Award, 2004-2009 University Scholar, 2006-2009 Email: pingyun.feng@ucr.edu |
3楼2007-07-05 10:09:58