个人简介

2017-至今，深圳大学，化学与环境工程学院，副教授 2012-2016，深圳大学，化学与环境工程学院，讲师 2011-2012，香港科技大学，机械工程系，博士后 2007-2011，香港科技大学，机械工程系，博士 2005-2007，华中科技大学，能源与动力工程学院，硕士 2001-2005，华中科技大学，能源与动力工程学院，本科 2012年进入深圳大学从事教学和科研工作，目前为能源科学与工程系主任，负责“新能源科学与工程”专业的发展规划与建设。长期从事燃料电池、储能液流电池等新能源利用领域的研究，作为项目负责人主持国家自然科学基金1项、广东省自然科学基金2项、深圳市科技计划3项，作为骨干成员先后参与香港研究资助局项目4项、香港创新及科技局项目1项。至今在Energy & Environmental Science、Renewable & Sustainable Energy Reviews、Journal of Power Sources、International Journal of Heat & Mass Transfer等权威能源类期刊上发表SCI论文近50篇，论文被SCI期刊他引近1000次，h-index为20。2013年获香港科技大学博士生“卓越研究奖” （每年不超过3名），同年获香港科学会“青年科学家奖”的第三名（能源工程领域唯一入选者）。2013年入选深圳市海外高层次（B类）人才，2016年入选深圳大学“荔园优秀青年教师”培养计划。长期担任Journal of Power Sources、Applied Energy、International Journal of Hydrogen Energy、Renewable Energy, Applied Thermal Engineering、Journal of Micromechanics and Microengineering、Smart Materials and Structures、Nanotechnology、RSC Advances、International Journal of Energy Research、Journal of Energy Storage等国际期刊的审稿人。指导多名研究生在国家级A类学科竞赛中获得全国二等奖和国家奖学金等

研究领域

长期从事燃料电池、储能液流电池等新能源利用领域的研究

研究兴趣与方向 课题组的主要研究思路是应用与拓展经典流体力学、传热传质学、热力学、材料学、反应动力学的基本原理，认识与揭示新能源前沿技术（燃料电池、储能液流电池、太阳能海水淡化等）中的复杂物理化学现象和特性，进而提出高效的过程调控和优化方法，提升新能源技术的性能和可靠性。具体研究方向包括： 1. 宏观流动-介观传递-微观反应的耦合机制与调控 2. 新能源器件中流动与传热传质现象的现场原位表征技术 3. 燃料电池的器件设计与建模 4. 新型高能量密度的流动电池 5. 局部界面式太阳能海水淡化技术 科研项目 1. 国家自然科学基金-青年基金，2014.01-2016.12，项目负责人 2. 广东省自然科学基金-自由探索, 2018.05-2021.4, 项目负责人 3. 广东省自然科学基金-博士启动，2013.10-2015.10，项目负责人 4. 深圳市基础研究学科布局项目，2017.2-2021.1，项目负责人 5. 深圳市基础研究项目，2013.9-2015.8，项目负责人 6. 深圳市孔雀计划技术创新项目，2014.12-2016.12，项目负责人 7. 深圳市高端人才启动项目，2013.9-2015.12，项目负责人 8. 深圳大学交叉学科创新团队，2017，副组长 9. 深圳大学新进教师科研启动项目，2013.1-2014.12， 项目负责人

近期论文

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[1] X. Zhou, L.Y. Lin, Y.H. Lin, X.Y. Zhang, L.D. Fan, Q.X. Wu*, “Elucidating effects of component materials and flow fields on Sn-Fe hybrid flow battery performance”, Journal of Power Sources 2019, in press. [2] X.Y. Zhang, Y.X. Huang, X. Zhou, F. Wang, Z.K. Luo, Q.X. Wu*, “Characterizations of carbonized electrospun mats as diffusion layers for direct methanol fuel cells”, Journal of Power Sources 2019, 227410. [3] X. Zhou, X.Y. Zhang, Y.H. Lv, L.Y. Lin, Q.X. Wu*, “Nano-catalytic layer engraved carbon felt via copper oxide etching for vanadium redox flow batteries”, Carbon, 153 (2019) 674-681. [4]Q.X. Wu, Y.H. Lv, L.Y. Lin, X.Y. Zhang, Y. Liu, X. Zhou, “An improved thin-film electrode for vanadium redox flow batteries enabled by a dual layered structure”, Journal of Power Sources 410-411 (2019) 152-161. [5] Q.X. Wu, X.Y. Zhang, Y.H. Lv, L.Y. Lin, Y. Liu, X. Zhou, Journal of Materials Chemistry A 6 (2018) 20347-20355. (2018 Journal of Materials Chemistry A HOT Papers) [6] X. Zhou, L.Y Lin, Y.H. Lv, X.Y. Zhang, Q.X. Wu*, “A Sn-Fe flow battery with excellent rate and cycle performance”, Journal of Power Sources 404 (2018) 89-95. [7]Q.X. Wu, Z. Pan, L. An*, “Recent advances in alkali doped polybenzimidazole membranes for fuel cell applications”, Renewable & Sustainable Energy Reviews 89 (2018) 168-183. [8] Y. Cui, Y. Liu, J.W Wu*, F. Zhang, A.P. Baker, M. Lavorgna*, Q.X. Wu*, Q. Tang, J. Lu, Z. Xiao, X. Liu, “Porous silicon-aluminium oxide particles functionalized with acid moieties: An innovative filler for enhanced Nafion-based membranes of direct methanol fuel cell”, Journal of Power Sources 403 (2018) 118-126. [9] R.G. Mei, J.J. Xi, Lei. Ma, L. An, F. Wang, H.Y. Sun, Z.K. Luo, Q.X. Wu*, “Multi-scaled porous Fe-N/C nanofibrous catalysts for the cathode electrodes of direct methanol fuel cells”, Journal of The Electrochemical Society 164 (2017) F1556-F1565. [10] R.G. Mei, L. Ma, L. An, F. Wang, J.J. Xi, H.Y. Sun, Z.K. Luo, Q.X. Wu*, “Layered Spongy-like O-Doped g-C3N4: An Efficient Non-Metal Oxygen Reduction Catalyst for Alkaline Fuel Cells”, Journal of The Electrochemical Society 164 (2017) F354-F363. [11] J.J. Xi, F. Wang, R.G. Mei, Z.J. Gong, X.P. Fan, H. Yang, L. An, Q.X. Wu*, Z.K. Luo*, "Catalytic performance of pyrolyzed graphene supported Fe-N-C composite and its application for acid direct methanol fuel cells", RSC Advances 6 (2016) 90797-90805. [12] F. Wang, H.J. Li, Q.X. Wu*, J. Fang, Y. Huang, C.L. Yin, Y.H. Xu, Z.K. Luo, "Improving the performance of a non-aqueous lithium-air battery by defective titanium dioxides with oxygen vacancies", Electrochimica Acta 202 (2016) 1-7. [13] Z.J. Gong, Q.X. Wu*, F. Wang, X. Li, X.P. Fan, H. Yang, Z.K. Luo*,"A hierarchical micro/mesoporous carbon fiber/sulfur composite for high-performance lithium-sulfur batteries", RSC Advances 6 (2016) 37443-37451. [14] B. Zhang, H. Xie, J. Ni, X, Xiang, Q.X. Wu*, L. Wang*, "Preparation and properties of branched sulfonated poly(arylene ether ketone) / polytetrafluoroethylene composite materials for proton exchange membranes", RSC Advances 6 (2016) 61410-61417. [15]Q.X. Wu*, H.Y. Li, W.X. Yuan, Z.K. Luo, F. Wang, H.Y. Sun, X.X. Zhao, H.D. Fu, “Performance evaluation of an air-breathing high-temperature proton exchange membrane fuel cell”, Applied Energy 160 (2015) 146-152. [16]X.X. Zhao, W.X. Yuan, Q.X. Wu*, H.Y. Sun, Z.K. Luo, H.D. Fu, “High-temperature passive direct methanol fuel cells operating with concentrated fuels”, Journal of Power Sources 273 (2015) 517-521. [17]Q.X. Wu, L. An, X.H. Yan. T.S. Zhao*, “Effects of design parameters on the performance of passive direct methanol fuel cells fed with concentrated fuel”, Electrochimica Acta 133 (2014) 8-15. [18]Q.X. Wu, T.S. Zhao*, R. Chen, L. An, “A sandwich structured membrane for direct methanol fuel cells operating with neat methanol”, Applied Energy 106 (2013) 301-306. [19]Q.X. Wu, S.Y. Shen, Y.L. He, T.S. Zhao*, “Effect of water concentration in the anode catalyst layer on the performance of direct methanol fuel cells operating with neat methanol”, International Journal of Hydrogen Energy 37 (2012) 5958-5968. [20]Q.X. Wu, T.S. Zhao*, W.W. Yang, “Effect of the cathode gas diffusion layer on the water transport behavior and the performance of passive direct methanol fuel cells operating with neat methanol”, International Journal of Heat and Mass Transfer 54 (2011) 1132-1143. [21]Q.X. Wu, T.S. Zhao*, “Characteristics of water transport through the membrane in direct methanol fuel cells operating with neat methanol”, International Journal of Hydrogen Energy 36 (2011) 5644-5654. [22]Q.X. Wu, Y.L. He, T.S. Zhao*, “Recent advances in understanding of mass transfer phenomena in direct methanol fuel cells operating with concentrated fuel”, Frontiers in Heat and Mass Transfer 2 (2011), 032001. [23]Q.X. Wu, T.S. Zhao*, R. Chen, W.W. Yang, “A microfluidic-structured flow field for passive direct methanol fuel cells operating with highly concentrated fuels”, Journal of Micromechanics & Microengineering 20 (2010) 045014. [24] Q.X. Wu, T.S. Zhao*, R. Chen, W.W. Yang, “Enhancement of water retention in the membrane electrode assembly for direct methanol fuel cells operating with neat methanol”, International Journal of Hydrogen Energy 35 (2010) 10547-10555. [25] Q.X. Wu, T.S. Zhao*, R. Chen, W.W. Yang, “Effects of anode microporous layers made of carbon powder and nanotubes on water transport in direct methanol fuel cells”, Journal of Power Sources 191 (2009) 304-311