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【交叉科学论坛】2019年第5期

发布日期: 2019-05-06

       时   间:2019年5日7日 9:30  

  地   点:求是楼426室

  主办单位:前沿交叉科学研究院

  

       报告题目1:

  

  用于清洁能源转换的电催化设计—— 一个理论观点

  Design Electrocatalysts for Clean Energy Conversions  – A Theoretical Point of View

  

       报告人:焦研

 

       报告人简介:

 

  

  

  焦研博士于2012年获得昆士兰大学化学工程博士学位。毕业后加入阿德莱德大学化学工程学院,担任博士后研究员,现任高级讲师。主要研究方向是利用计算技术研究各种材料表面的电催化反应,并致力于设计用于电化学清洁能量转换反应的高活性和高选择性催化剂,包括析氢反应、氧还原反应、析氧反应、CO2还原反应和氮还原反应。在研究领域发表了49篇研究论文,引用超过10000次,H因子为33(Google scholar)。焦研博士承担了多项研究项目,其中包括一个ARC Discovery项目,旨在设计用于电催化氮还原的催化剂材料。

  

  报告内容简介:

  Establish reliable, clean and sustainable energy supplies are of great importance, and using electrochemical methods to realize energy conversions hold a great promise. Among these reactions, hydrogen evolution reaction (HER), oxygen reduction reaction (ORR), oxygen evolution reaction (OER), and CO2 reduction reaction (CRR) are the moststudied. In this regard, we have evaluated and designed a series of carbon-based electrocatalysts for HER, ORR, OER and CRR by density functiona theory calculations. We successfully established the relationship between theapparent electrochemical performance and the intrinsic surface adsorption behaviour for carbon-based materials. Finally, we have summarized methods on three levels to improve carbon-based materials’ performance for these reactions.

  

       报告题目2:

  

  用于传感和光催化应用的光子纳米多孔材料的结构工程

  Structural engineering of Photonic Nanoporous Materials for Sensing and Photocatalysis Applications

  

       报告人:  Abel Santos

 

  报告人简介:

  

  

  

  Abel Santos博士于2006年获得西班牙Jaume I大学的化学工程(荣誉)学士学位,2007年和2011年分别获得了西班牙Rovira i Virgili大学的电子工程硕士和博士学位。2011年在德国汉堡大学应用物理研究所工作,并于2012年进入澳大利亚阿德莱德大学的化学工程学院任教。Abel Santos是阿德莱德大学光子学与高级传感研究所(IPAS)成员、ARC纳米级生物光子学卓越中心(CNBP)副研究员,主要从事光学传感与生物传感用光子和等离子体材料的结构工程和光催化应用研究。并在该领域取得多项成果,出版了5本书籍,发表了87篇研究论文,平均每年发表约12篇论文,平均影响因子6.2,总引用超过2315次,H因子为30(Google scholar)。

 

  报告内容简介:

  The fundamental understanding and rational engineering of light–matter interactions at the nanoscale will generate new opportunities for future breakthrough technologies. Optical structures with precisely designed and engineered properties will be needed for the development, implementation and on-chip integration of quantum computing systems. In this talk I will introduce cutting-edge advances in plasmonic and photonic crystal platforms based on nanoporous anodic alumina – a nanoporous material produced by electrochemical oxidation of aluminium – and their application in optical sensing and biosensing, and photocatalysis forenvironmental remediation.