教师名录
焦震钧
通讯地址:深圳南山区西丽大学城哈工大校区G栋412
电子邮件:jiaozhenjun@hit.edu.cn
联系电话:

个人简介

焦震钧,教授,博士研究生导师。长期担任包括Journal of Power Sources, Solid State Ionics,International Journal of Hydrogen Energy 等国际学术期刊审稿专家。博士期间在新加坡南洋理工大学师从国际著名微流体专家阮南忠教授进行微尺度液体驱动方面的研究。在日本东京大学工作期间从事固体氧化物燃料电池方向的研究。日本固体氧化物燃料电池(SOFC)协会会员。自2006年以来,在包括Acta Materilia, Journal of Power Sources 和 Journal of The Electrochemical Society 等国际知名学术期刊上发表学术论文近50篇,曾作为杰出外国研究者被日本国家电视台TBS单独采访报道。

同期主持和完成日本政府基金项目一项并参与两项日本国家政府基金项目和多个民间财团资助研究项目。与英国帝国理工,丹麦技术大学等世界顶尖研究小组保持长期友好合作关系,对SOFC以及SOEC技术进行从制备到超长时间运行劣化机制的深入基础研究。同时积极推进产-学-研深度融合,参与日本工业界大型企业电装公司合作研究项目。目前所开发的金属高温烧结模拟计算方法以及新型高速微波陶瓷烧结技术已被纳入公司研发项目。

研究方向

研究方向以微纳米力学为核心,涉及电化学、传热传质、微流体、数值模拟计算等领域,主攻固体氧化物燃料电池(SOFC)及电极微结构分析等研究,取得了一系列创新性研究成果。其中代表性研究为基于聚焦离子束/扫描电子显微镜双束三维微结构重构技术(FIB-SEM)的实验以及数值模拟技术以及首次提出利用激光辅助光学显微镜对于实际高温电化反应中金属镍在氧化物表面的结构变化进行微米尺度原位实时观察的技术。

教育经历

2006-2009  新加坡南洋理工大学 机械与航空航天工程博士
2002-2006  新加坡南洋理工大学 机械与航空航天工程学士

研究与工作经历

2019-至今  哈尔滨工业大学(深圳) 理学院 教授
2013-2018  日本东京大学 助理教授
2009-2013  日本东京大学 博士后研究员
  

专业资质与学术兼职

  

科研项目

  

科研成果及奖励

2013-2016  日本学术振兴会青年研究基金,“固体氧化物燃料电池燃料极中镍氧化还原过程中烧结机制的关研究”。(个人项目)
2013-2018  日本国立新能源产业技术综合开发机构(NEDO),“高温中固体氧化物燃料电池燃料极中金属镍超超长时间烧结数值模拟的关研究”。(参与,东京大学leader)
2009-2013  日本国立新能源产业技术综合开发机构(NEDO),“基于聚焦离子束/扫描电子显微镜双束三维微结构重构技术的固体氧化物燃料电池电极材料定量分析实验以及数值模拟的关研究”。(参与,东京大学leader)
2013-2016  科学技术振兴机构战略基础研究 (CREST),“关于固体氧化物燃料电池新材料,结构革新的多尺度连成解析相关研究”。(参与,东京大学leader)
2013-2016  ポスト「京」(超级计算机)重点課題,“基于超大规模解析的固体氧化物燃料电池设计的关研究”。(参与)

论文及著作

代表性论文:
1. Z. Jiao and N. Shikazono, Prediction of Nickel Morphological Evolution in Composite Solid Oxide Fuel Cell Anode Using Modified Phase Field Model, Journal of The Electrochemical Society, 165 (2) F55-F63, 2018.
2. Z. Jiao and N. Shikazono, Study on the effects of polarization on local morphological change of nickel at active three-phase-boundary using patterned nickel-film electrode in solid oxide fuel cell anode, Acta Materialia, 135, 124-131, 2017.
3. Y. T. Kim, Z. Jiao and N. Shikazono, Evaluation of La 0.6 Sr 0.4 Co 0.2 Fe 0.8 O 3-Gd 0.1 Ce 0.9 O 1.95 composite cathode with three dimensional microstructure reconstruction, Journal of Power Sources, 342, 787-795, 2017.
4. T. Shimura, Z. Jiao, S. Hara and N. Shikazono, Investigation of Microstructural Change of Nickel-Yttria Stabilized Zirconia Anode during Oxidation and Reduction Based on Three-Dimensional Reconstruction, Journal of The Electrochemical Society 164(2), F147-F153, 2017.
5. T. Shimura, Z. Jiao and N. Shikazono, Dependence of solid oxide fuel cell electrode microstructure parameters on focused ion beam–Scanning electron microscopy resolution, International Journal of Hydrogen Energy, 41(47), 22373-22380, 2016.
6. T. Shimura, Z. Jiao and N. Shikazono, Evaluation of nickel-yttria stabilized zirconia anode degradation during discharge operation and redox cycles operation by electrochemical calculation, Journal of Power Sources, 330,149-155, 2016.
7. Z. Jiao, A. Ueno, Y Suzuki and N. Shikazono, Study on the influences of reduction temperature on nickel-yttria-stabilized zirconia solid oxide fuel cell anode using nickel oxide-film electrode, Journal of Power Sources 328, 377-384, 2016.
8. Z. Jiao, A. Ueno and N. Shikazono, Study on the correlation between Solid Oxide Fuel Cell Ni-YSZ anode performance and reduction temperature, Journal of Physics: Conference Series 745(3), 032146, 2016.
9. Z. Jiao and N. Shikazono, 3D reconstruction size effect on the quantification of solid oxide fuel cell nickel–yttria-stabilized-zirconia anode microstructural information using scanning electron microscopy-focused ion beam technique, Science Bulletin 61(17), 1317-1323, 2016.
10. Z. Jiao and N. Shikazono, Simulation of the reduction process of solid oxide fuel cell composite anode based on phase field method, Journal of Power Sources 305, 10-16, 2016.
11. Z. Jiao and N. Shikazono, Quantitative study on the correlation between solid oxide fuel cell Ni-YSZ composite anode performance and reduction temperature based on three-dimensional reconstruction, Journal of the Electrochemical Society 162(6), F571-F578, 2015.
12. T. Shimura, Z. Jiao, S. Hara and N. Shikazono, Quantitative analysis of solid oxide fuel cell anode microstructure change during redox cycles, Journal of Power Sources 267, 58-68, 2014.
13. X. Sun, Y. Hasegawa, H. Kohno, Z. Jiao, K. Hayakawa, K. Okita and N. Shikazono, Calculation of contact angles at triple phase boundary in solid oxide fuel cell anode using the level set method, Materials Characterization 96, 100-107, 2014.
14. Z. Jiao and N. Shikazono, Study on the Influence of Current Collector on the Sudden Deterioration of Solid Oxide Fuel Cell Anode Performance, Journal of Fuel Cell Science and Technology 11(2), 021010, 2014.
15. Z. Jiao and N. Shikazono, Simulation of nickel morphological and crystal structures evolution in solid oxide fuel cell anode using phase field method, Journal of The Electrochemical Society 161 (5), F577-F582, 2014.
16. Z. Jiao and N. Shikazono, Simulation of solid oxide fuel cell anode microstructure evolution using phase field method, Journal of The Electrochemical Society 160 (6), F709-F715, 2013.
17. Z. Jiao, G. Lee and N. Shikazono, N. Kasagi, Quantitative study on the correlation between solid oxide fuel cell Ni-YSZ composite anode performance and sintering temperature based on three-dimensional reconstruction, Journal of The Electrochemical Society 159(7), F278-F286, 2012.
18. Z. Jiao and N. Shikazono, N Kasagi, Quantitative characterization of SOFC nickel-YSZ anode microstructure degradation based on focused-ion-beam 3D-reconstruction technique, Journal of The Electrochemical Society 159(3), B285-B29, 2012.
19. Z. Jiao and N. Shikazono, Study on the Influence of Current Collector on the Sudden Deterioration of Solid Oxide Fuel Cell Anode Performance, Journal of Fuel Cell Science and Technology, 11(2), 021010, 2013.
20. Z. Jiao and N. Shikazono, Simulation of Solid Oxide Fuel Cell Anode Microstructure Evolution Using Phase Field Method, Journal of the Electrochemical Society, 160(6), F1-F7, 2013.
21. Z. Jiao, N. Shikazono and N. Kasagi, Quantitative Study on the Correlation Between Solid Oxide Fuel Cell Ni-YSZ Composite Anode Performance and Sintering Temperature Based on Three- dimensional Reconstruction, Journal of the Electrochemical Society, 159(7), F278-F286, 2012.
22. Z. Jiao, N. Shikazono and N. Kasagi, Quantitative Characterization of SOFC Nickel-YSZ Anode Microstructure Degradation Based on Focused-Ion-Beam 3D-Reconstruction Technique, Journal of the Electrochemical Society, 159(3), B1-B7, 2012.
23. Z. Jiao, N. Shikazono and N. Kasagi, Study on Degradation of solid oxide fuel cell anode by using pure Ni electrode, Journal of Power Sources, 196, 8366–8376, 2011.
24. Z. Jiao, N. Shikazono and N. Kasagi, An Ultra-fast fabrication technique for anode support solid oxide fuel cells by microwave, Journal of Power Sources, 196(13), 5490-5493, 2011.
25. Z. Jiao, Takagi, N. Shikazono and N. Kasagi, Study on local morphological changes of nickel in Solid Oxide Fuel Cell anode using porous Ni pellet electrode, Journal of Power Sources, 2010, 196 (3), 1019-1029, 2011.
26. Z. Jiao, N. Shikazono and N. Kasagi, Comparison of ultra-fast microwave sintering and conventional thermal sintering in manufacturing of anode support Solid Oxide Fuel Cell, Journal of Power Sources, 195 (24), 8019-8027, 2010.
27. Z. Jiao, N. Shikazono and N. Kasagi, Performance of an anode support solid oxide fuel cell manufactured by microwave sintering, J. Power Sources, 195 (1), 151-154, 2010.
28. X. Huang, C. Y. Wen and Z. Jiao, A standing wave model for acoustic pumping effect in microchannels, APPLIED ACOUSTICS, 71(2), 164-168, 2010.
29. Z. Jiao, X. Huang, N. T. Nguyen, Scattering and attenuation of surface acoustic waves in droplet actuation, Journal of Physics A: Mathematical and Theoretical, 41, 355502, 2008.
30. S.S.Wang, Z. Jiao, X. Huang, N. T. Nguyen, Acoustically induced bubbles in a microfluidic channel for mixing enhancement, Microfluidics and Nanofluidics, 6: 847–852, 2009.
31. Z. Jiao, X. Huang, N. T. Nguyen, Manipulation of droplet in a planar channel by periodic thermocapillary actuation, Journal of Micromechanics and Microengineering, 18(4), 045027, 2008.
32. Z. Jiao, X. Huang, N. T. Nguyen, P. Abgrall, Thermocapillary actuation of droplet in a planar microchannel, Microfuidics and Nanofuidics, 5(2), 205-214, 2007.
33. Z. Jiao, N. T. Nguyen, X. Huang, Thermocapillary actuation of a water droplet encapsulated in an oil plug, Journal of Micromechanics and Microengineering, 17(9), 1843-1852, 2007.
34. Z. Jiao, N. T. Nguyen, X. Huang, Thermocapillary actuation of liquid plugs using a heater array, Sensors and Actuators A, 140(2), 145-155, 2007.
35. X. Huang, N. T. Nguyen, Z. Jiao, Nonlinear standing waves in a resonator with feedback control, The Journal of the Acoustical Society of America, 122(1), 38-41, 2007.
36. Z. Jiao, N. T. Nguyen, X. Huang, Chaotic motion of micro plugs under high-frequency thermocapillary actuation, Journal of Micromechanics and Microengineering, 17, 180-185, 2007.
37. Z. Jiao, N. T. Nguyen, X. Huang, Y. Z. Ang , Reciprocating thermocapillary plug motion in an externally heated capillary, Microfluidics and Nanofluidics, 3(1), 39-46, 2006.

任教和任导师经历

  
最后更新:2019-02-15 14:09:52