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宁波诺丁汉大学理工学院导师教师师资介绍简介-吴韬

本站小编 Free考研考试/2021-04-17

吴韬 宁波诺丁汉大学理工学院院长、诺丁汉大学卓越灯塔计划(宁波)创新研究院副院长
化学与环境工程系 / 理工学院



联系方式 办公室
理工楼418

校园
宁波诺丁汉大学

地址
宁波泰康东路199号宁波诺丁汉大学

电话
+86 (0) (ext 8269)

邮箱
tao.wu@nottingham.edu.cn



学历
化学工程 博士
化工工艺 工学硕士(优等)
无机化工工艺学 工学学士(优秀)

个人简介
吴韬教授主要从事清洁能源技术领域方面的研究,在化石能源和生物能源的高效转化与清洁利用方面拥有20多年的研发经验。他目前的研究项目涵盖范围广,涉及到开创性的前沿基础研究、产品开发的概念验证、专利技术商业化开发等。吴韬教授迄今为止已完成政府和企业资助的科研项目40多项。
他在能源转化技术及资源清洁高效利用相关领域发表80多篇论文,持有6项授权发明专利。他目前的研究兴趣集中于清洁能源转化技术、节能、废弃物减量化和回收利用技术。此外,他还是许多国家和地区专业团体的理事,现任宁波诺丁汉大学清洁能源转化技术市重点实验室和诺丁汉大学宁波新材料研究院的负责人。
工作经历2013年8月-2015年7月:宁波诺丁汉大学 副教授和准教授
2007年8月-2013年7月:宁波诺丁汉大学 讲师、副教授
2004年11月-2007年7月:英国诺丁汉大学 研究员
1996年7月-2000年9月:华东理工大学 讲师
奖项及荣誉2017: 宁波市政府授予科技促进奖
2015: 宁波市知识产权局授予优秀专利奖
2014: 宁波市科技协会授予优秀顾问
2010: 宁波市政府授予杰出海外归国人员
2008年1月:“第10届全国优秀专利奖”获奖专利“多喷嘴对置式水煤浆或煤粉气化炉及其应用”,已被世界上60多个大型装置上使用。
1999年:被国家石油化工局授予“科技进步3等奖”。获奖项目:“水煤浆气化系统仿真培训软件”。
1998年:被上海市授予“科技进步1等奖”。获奖项目:“新型水煤浆气化喷嘴的研究与开发”。
1997年:被中石化授予“科技进步3等奖”。获奖项目:“管式加热炉传热过程模拟”。


教学
目前指导5名博士生
任教科目包括:
分离过程 1(大三)
多组分分离(大四)
反应堆设计(大四)
工程管理(大四)
设计项目(大四)


发表文章
1. Zhao, H., G. Yang, X. Mu, P. Cao, X. Gao, and T. Wu. Hg0 Capture over MoS2 Nanosheets Containing Adsorbent: Effects of Temperature, Space Velocity, and Other Gas Species. in Energy Procedia. 2017.
2. Zhao, H., X. Mu, G. Yang, C. Zheng, C. Sun, X. Gao, and T. Wu, Microwave-induced activation of additional active edge sites on the MoS2 surface for enhanced Hg0 capture. Applied Surface Science, 2017. 420: p. 439-445.
3. Zhao, H., X. Mu, G. Yang, M. George, P. Cao, B. Fanady, S. Rong, X. Gao, and T. Wu, Graphene-like MoS2 containing adsorbents for Hg0 capture at coal-fired power plants. Applied Energy, 2017.
4. Xu, J., T. Wu, J. Zhang, H. Chen, W. Sun, and C. Peng, Microstructure measurement and microgeometric packing characterization of rigid polyurethane foam defects. Cellular Polymers, 2017. 36(4): p. 183-204.
5. Xu, J., T. Wu, W. Sun, and C. Peng, Characterization of insulation performance, poststability, and foaming process of rigid polyurethane sandwich panel for cold storage warehouse. Journal of Materials in Civil Engineering, 2017. 29(9).
6. Xu, J., T. Wu, C. Peng, and S. Adegbite, Influence of acid and alkali pre-treatments on thermal degradation behaviour of polyisocyanurate foam and its carbon morphology. Polymer Degradation and Stability, 2017. 141: p. 104-118.
7. Parvez, A.M. and T. Wu, Characteristics and interactions between coal and carbonaceous wastes during co-combustion. Journal of the Energy Institute, 2017. 90(1): p. 12-20.
8. Parvez, A.M., Y. Hong, E. Lester, and T. Wu, Enhancing the Reactivity of Petroleum Coke in CO2 via Co-Processing with Selected Carbonaceous Materials. Energy and Fuels, 2017. 31(2): p. 1555-1563.
9. Oladejo, J.M., S. Adegbite, C.H. Pang, H. Liu, A.M. Parvez, and T. Wu, A novel index for the study of synergistic effects during the co-processing of coal and biomass. Applied Energy, 2017. 188: p. 215-225.
10. Li, G., N.J. Miles, T. Wu, and P. Hall, Large eddy simulation and Reynolds-averaged NavierStokes based modelling of geometrically induced swirl flows applied for the better understanding of Clean-In-Place procedures. Food and Bioproducts Processing, 2017. 104: p. 77-93.
11. Hong, Y., W. Chen, X. Luo, C. Pang, E. Lester, and T. Wu, Microwave-enhanced pyrolysis of macroalgae and microalgae for syngas production. Bioresource Technology, 2017. 237: p. 47-56.
12. Cao, P., S. Adegbite, and T. Wu. Thermodynamic Equilibrium Analysis of CO2 Reforming of Methane: Elimination of Carbon Deposition and Adjustment of H2/CO Ratio. in Energy Procedia. 2017.
13. Zhao, H., G. Yang, X. Gao, C.H. Pang, S.W. Kingman, and T. Wu, Hg0 Capture over CoMoS/γ-Al2O3 with MoS2 Nanosheets at Low Temperatures. Environmental Science and Technology, 2016. 50(2): p. 1056-1064.
14. Zhao, H., G. Yang, X. Gao, C. Pang, S. Kingman, E. Lester, and T. Wu, Hg°-temperature-programmed surface reaction and its application on the investigation of metal oxides for Hg° capture. Fuel, 2016. 181: p. 1089-1094.
15. Zhang, H., J. Gao, Z. Zhao, G.Z. Chen, T. Wu, and F. He, Esterification of fatty acids from waste cooking oil to biodiesel over a sulfonated resin/PVA composite. Catalysis Science and Technology, 2016. 6(14): p. 5590-5598.
16. Yan, J., K. Shi, C. Pang, E. Lester, and T. Wu, Influence of minerals on the thermal processing of bamboo with a suite of carbonaceous materials. Fuel, 2016. 180: p. 256-262.
17. Wang, Z., N.J. Miles, T. Wu, F. Gu, and P. Hall, Recycling oriented vertical vibratory separation of copper and polypropylene particles. Powder Technology, 2016. 301: p. 694-700.
18. Parvez, A.M., I.M. Mujtaba, and T. Wu, Energy, exergy and environmental analyses of conventional, steam and CO2-enhanced rice straw gasification. Energy, 2016. 94: p. 579-588.
19. Parvez, A.M., I.M. Mujtaba, C. Pang, E. Lester, and T. Wu, Effect of the addition of different waste carbonaceous materials on coal gasification in CO2 atmosphere. Fuel Processing Technology, 2016. 149: p. 231-238.
20. Parvez, A.M., I.M. Mujtaba, P. Hall, E.H. Lester, and T. Wu, Synthesis of Bio-Dimethyl Ether Based on Carbon Dioxide-Enhanced Gasification of Biomass: Process Simulation Using Aspen Plus. Energy Technology, 2016. 4(4): p. 526-535.
21. Luo, X., Y. Hong, F. Wang, S. Hao, C. Pang, E. Lester, and T. Wu, Development of nano NixMgyO solid solutions with outstanding anti-carbon deposition capability for the steam reforming of methanol. Applied Catalysis B: Environmental, 2016. 194: p. 84-97.
22. Liu, X., T. Wu, Z. Dai, K. Tao, Y. Shi, C. Peng, X. Zhou, and G.Z. Chen, Bipolarly stacked electrolyser for energy and space efficient fabrication of supercapacitor electrodes. Journal of Power Sources, 2016. 307: p. 208-213.
23. Zhao, H., G. Yang, C.H. Pang, H. Fan, P. Hall, S. Kingman, and T. Wu, Screening of Metal Oxidesfor Hg0Capture. Energy Procedia, 2015. 75: p. 2421-2426.
24. Zhao, H., X. Luo, J. He, C. Peng, and T. Wu, Recovery of elemental sulphur via selective catalytic reduction of SO2over sulphided CoMo/-Al2O3catalysts. Fuel, 2015. 147: p. 67-75.
25. Wang, Z., P. Hall, N.J. Miles, T. Wu, P. Lambert, and F. Gu, The application of pneumatic jigging in the recovery of metallic fraction from shredded printed wiring boards. Waste Management and Research, 2015. 33(9): p. 785-793.
26. Li, G., P. Hall, N. Miles, and T. Wu, Improving the efficiency of 'Clean-In-Place' procedures using a four-lobed swirl pipe: A numerical investigation. Computers and Fluids, 2015. 108: p. 116-128.
27. Shi, K., J. Yan, E. Lester, and T. Wu, Catalyst-free synthesis of multiwalled carbon nanotubes via microwave-induced processing of biomass. Industrial and Engineering Chemistry Research, 2014. 53(39): p. 15012-15019.
28. Shi, K., T. Wu, J. Yan, H. Zhao, P. Hall, and E. Lester, Thermogravimetric studies on co-combustion characteristics of mengxi coal and poplar, in Progress in Sustainable Energy Technologies Vol II: Creating Sustainable Development. 2014. p. 503-517.
29. Shi, K., T. Wu, J. Yan, H. Zhao, P. Hall, and E. Lester, Microwave enhanced pyrolysis of gumwood, in Progress in Sustainable Energy Technologies: Generating Renewable Energy. 2014. p. 699-708.
30. Pang, C.H., S. Gaddipatti, G. Tucker, E. Lester, and T. Wu, Relationship between thermal behaviour of lignocellulosic components and properties of biomass. Bioresource Technology, 2014. 172: p. 312-320.
31. Gu, F., P. Hall, N.J. Miles, Q. Ding, and T. Wu, Improvement of mechanical properties of recycled plastic blends via optimizing processing parameters using the Taguchi method and principal component analysis. Materials and Design, 2014. 62: p. 189-198.
32. Binner, E., E. Lester, S. Kingman, C. Dodds, J. Robinson, T. Wu, P. Wardle, and J.P. Mathews, A review of microwave coal processing. Journal of Microwave Power and Electromagnetic Energy, 2014. 48(1): p. 35-60.
33. Avila, C., T. Wu, and E. Lester, Estimating the spontaneous combustion potential of coals using thermogravimetric analysis. Energy and Fuels, 2014. 28(3): p. 1765-1773.
34. Avila, C., T. Wu, and E. Lester, Petrographic characterization of coals as a tool to detect spontaneous combustion potential. Fuel, 2014. 125: p. 173-182.


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