题 目: Novel Electrode Systems for Enhanced Sensing and Analysis
报告人: Andrew Mount
英国爱丁堡大学 科学与工程学院 研究院长
时 间: 2014年10月27日(星期一) 上午10:00
地 点: 卢嘉锡楼202报告厅
Prof. Andrew Mount
Professor Mount is Professor of Physical Electrochemistry and Dean of Research in the College of Science andEngineering at the University of Edinburgh, which is ranked 17th in the World in the 2013/14 QS rankings. Heis a Fellow of the Royal Society of Chemistry, a member of RSC Faraday Division Council and Chair of theFaraday Standing Committee on Conferences, which determines the Faraday Discussion programme. Amongmany multidisciplinary research activities, Prof Mount currently leads REFINE, which is a 6-partner UK-fundedco-ordinatedprogramme to develop sustainable nuclear fuel reprocessing technologies. He won the RSCMolten Salts Discussion Group Invited Speaker award in 2012.
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能源材料化学协同创新中心
biwn必赢
2014年10月23日
附 - 报告摘要:
Novel Electrode Systems for Enhanced Sensing and Analysis
Professor Andrew Mount
Dean of Research
College of Science and Engineering
The University of Edinburgh
There is a pressing need for the development of enhanced electrochemical sensor systems of high fidelity,particularly for healthcare and energy applications. This talk will outline two aspects of enhancement; thedevelopment and characterisation of novel enhanced microelectrode and nanoelectrode systems and the designand functionalisation of electrodes with selected materials for specific sensing and analysis. Novel singleelectrode and multielectrode devices will be presented which have been designed and produced throughmicrofabrication, showing both their predicted theoretical and established experimental response.Developments in two application areas will then be presented, where specific materials functionalisation hasbeen carried out to produce electrodes tailored to selective sensing. In the first application, progress towardsenhanced biosensors which detect disease-relevant markers from real-world biological matrices with enhancedrapidity and sensitivity will be outlined. The second application area addressed will be the development ofsensing and analysis systems suited to measurement in the hostile environment of molten salts. Molten salts arean attractive medium for chemical and electrochemical processing with potential applications in pyrochemicalnuclear fuel reprocessing, metal refining, molten salt batteries and electric power cells and as a result there isdemand for molten salt-compatible sensing technologies. Work to develop suitable sensing technologies willbe presented and discussed.
