Enrico Drioli意大利卡拉布里亚大学教授
职业生涯
2016年,澳大利亚悉尼大学工程与信息技术学院的杰出的客座教授
2012年,沙特阿拉伯吉达阿卜杜拉国王大学海水淡化技术中心杰出兼职教授
2009年,汉阳大学能量工程学院的杰出客座教授
2012年,卡拉布里亚大学工程学院名誉教授
1968年至1982年期间,担任那不勒斯大学工程学院化学及电化学教授
1981年年2011年期间,担任卡拉布里亚大学工程学院教授
1982年至1985年期间,担任卡拉布里亚大学工程学院院长
自2011年至今,担任中国北车膜技术研究院的创建主任
1993年至2001年期间,担任国家研究委员会膜化学反应堆研究所主任
2002年至2008年期间,担任中国北车膜技术研究院的主任
研究领域
人造器官膜的应用,集成膜过程,膜制备传输现象、膜蒸馏及膜接触器,催化膜及催化膜反应器
个人简介
欧盟伊拉斯谟穆图斯膜工程博士学位协调员,国际合同/协议科技协调者,ITM-CNR-KACST-1)疏水膜制备膜接触器ITM-CNR-KISR(科威特科学研究所)用于评估膜蒸馏脱盐技术脱脂过滤高盐水的潜在应用、RHODIA等。并于2010年担任阿卜杜拉国王科技大学水脱盐和循环在利用中心科学顾问小组会员。
2015年10月,获得中国膜工业协会国际合作和促进国际奖项
2014年,获得俄罗斯工程院的院士Semenov金牌科学
2012年,获得捷克化学工程协会荣誉会员奖
2011年,因他对膜科技的杰出贡献而获得查理德梅林巴勒奖
2009年,获得法国图卢兹保罗萨巴蒂埃大学的名誉博士学位
2005年,因特别致力于中国膜工业协会,中国与欧洲膜科学与技术领域方面的合作,而获得国际合作荣誉奖。
2005至今,担任江苏工业学院客座教授
1999年,曾担任欧洲膜学会的名誉总监
1992 年,曾在俄罗斯科学院化学和化学技术部获得博士荣誉学位
1991 年,曾担任中国西北大学名誉教授,陕西,中国
1982-1998,曾担任欧洲膜学会会长
现在是Journal of Membrane Science,Polish Journal of Chemical Technology的顾问委员会委员,也是其他国际科学期刊的编辑部编辑。同时也是Applied Water Science Journal, Springer Berlin Heidelberg (德国) and Membrane Water Technology, Techno Press (韩国) 执行编辑。
到目前为止,共出版了750多篇科技论文,22项专利及24本书
演讲题目:Composite Graphene and beyond Graphene Membranes
主题会场石墨烯在海水淡化领域的应用&中意石墨烯双边合作论坛
开始时间
结束时间
内容摘要
Many areas around the globe suffer the scarcity of clean and fresh water as well as the access to adequate sanitation due to the exponential increase in the world’s population and industrial activities over the last decades.
Current state-of-the-art technology allows for the provision of refresh water by processing seawater and brackish water by means of membrane operations and in particularly reverse osmosis plants. Though the reverse osmosis is 10 folds more efficient than thermal processes, it is not yet an intensely competitive technology from an energetic point of view, especially for those countries that suffer important energy shortages (1). Also, seasonal variations in seawater quality as well as sensitivity to fouling, scaling and brine disposal make the RO-process necessary to the integration with pre-treatment steps, such as nanofiltration, and post-treatment steps, such as membrane distillation and membrane crystallization. Nanofiltration takes advantages of reducing hardness and total dissolved solid with a recover factor up to 50% and energy saving of 25-30%. Membrane Distillation and Crystallization are envisaged as suited processes to handle the brine problems, taking advantages of production of ultra-pure, desalted and demineralized water as well as concentration of aqueous salts or inorganic acids up to high concentrations, and crystallization (2).
Despite the sustainability of integrated membrane processes, there is still a great demand for advanced materials, which can yield more efficient production of clean and safe water while reducing the energy need to produce it. The choice of 2D layered materials for the fabrication of advanced membranes appears to be a reliable route for allocating in the same device complementary functions, including mass, charge and energy transport (3).
Herein, the potentiality of graphene and 2D materials beyond graphene in water processing is discussed. Nanopores, local defects and wrinkling in graphene sheets as well as the insertion of functional groups in the pore edges or between the stacked layers are discerned with the membrane ability to let water pass through, but also to stop pollutants and salts at the interface according to size exclusion, chemical and electrostatic interactions and Donnan’s exclusion mechanisms. Electronical features are also examined in relation to the possibility to realize devices for self-sustainable energy recovery, production and storage. Finally, perspectives on the future of 2D electronic materials beyond graphene, including phosphorene, silicene, and other transition metal dichalcogenide, are discussed with an emphasis to the synthesis, characterization and production of nanoporous desalination membranes through which water flow and ion filtering can be regulated (4-7).
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