| 报告题目 | Superstructures from Nanocrystals |
| 报告人 | Prof. Alexander Eychmüller |
| 报告人单位 | Physical Chemistry, TU Dresden, Bergstrasse 66b, 01062 Dresden, Germany |
| 报告时间 | 2013-10-31 |
| 报告地点 | 合肥微尺度物质科学国家实验室一楼科技展厅 |
| 主办单位 | 合肥微尺度物质科学国家实验室、中国科学技术大学化学与材料科学学院 |
| 报告介绍 | 报告摘要:
Gels and aerogels manufactured from a variety of nanoparticles available in colloidal solutions have recently proven to provide an opportunity to marry the nanoscale world with that of materials of macro dimensions which can be easily manipulated and processed, whilst maintaining most of the nanoscale properties. The materials carry an enormous potential for applications. This is largely related to their extremely low density and high porosity providing access to the capacious inner surface of the interconnected nanoobjects they consist of. We will report on latest developments in this field in our group with respect to a) enzyme encapsulated QD hydrogels as a multi-functional platform in the development of optical biosensors) the electrocatalytical activity towards the oxidation of ethanol of a freestanding palladium nanoparticle aerogel with extremely high electrocatalytic current density and good durability colloidal nanocrystals embedded in macrocrystals and their application in a colour conversion LEDs with good robustness, photostability, and color purity.
报告人简介:
A. Eychmüller教授是半导体物理化学领域的著名科学家,主要致力于亚微米至原子尺寸半导体材料的合成、结构及性质研究,在光电转换、传感电化学及生物技术等领域的应用,取得了许多优秀成果。现已在Nature Medicine, Nature Nanotechnology, Chemical Society Reviews, Angewandte Chemie-International Edition, Nano Letters, Journal of the American Chemical Society, ACS Nano, Advanced Materials等国际高水平杂志上发表论文250余篇,被120多个国际会议邀请做邀请报告。Eychmüller自1994年在汉堡大学即担任课题组长,迄今,已培养了25名博士研究生和15名硕士研究生,其中有中国学生(含“洪堡”博士后)就有10余人,目前这些中国学生大部分已经回国,在高校、科研院所、企业等单位担任教学、科研一线工作。Eychmüller现为德累斯顿工业大学(TU Dresden)教授,他为德国统一后的原东德教育体系的重建做出了卓越贡献。他于2005年创立了德累斯顿工业大学光电化学研究中心,自2009起年担任物理化学与电化学系主任,并连续五年担任TU Dresden基础科学评审委员会的顾问及TU Dresden参议院委员。他半导体物理化学及光电化学领域的研究引起了国际上的广泛关注,他的课题组发现的水相合成量子点方法及高温油相Hot-bubbling方法,因其能够大量合成高结晶度、单分散的II-VI、II-V、III-V族量子点,从进而推动量子点的广泛运用于光电器件、生物传感及LED纳米器件,吸引了世界范围的兴趣和关注。 |
