姓 名:郑益锋
性 别:男
出生年月:1983年3月
籍 贯:浙江丽水
职 称:教授、硕导
电子邮箱:zhengyifeng@njtech.edu.cn
办公地点:润德楼B201
学缘与工作经历
2023/05-至今,苏州国家实验室(双聘),研究员
2022/08-至今,南京工业大学,教授
2016/07-2022/07,南京工业大学,副教授
2016/04-2017/04,新加坡南洋理工大学,访问学者
2015/04-2016/06,南京工业大学,讲师
2013/08-2015/03,中国科学院宁波材料技术与工程研究所, 助理研究员
2011/07-2013/07,中国科学院宁波材料技术与工程研究所, 博士后
2006/09-2011/06,南京工业大学,研究生/博士
2002/09-2006/06,南京工业大学,本科生/学士
教学与科研简介
主要研究领域
长期从事1、固体氧化物燃料电池(SOFC)材料,2、高温电解(SOEC)水/CO2制备氢气/合成气材料,3、阴离子交换膜电解水制氢材料,4、轻质隔热陶瓷等研究。
人才项目
江苏省第七期“333高层次人才培养工程”第三层次。
教学及科研项目
承担本科生的《无机非金属材料生产设备》、《先进无机非金属材料》和研究生的《特种陶瓷》等课程教学。
近年来,作为项目负责人承担了国家自然科学基金面上项目和青年项目、浙江省重点科技创新团队课题(2项)、中国博士后科学基金面上资助(二等)、浙江省博士后科研项目择优资助(一等)及多项企业横向项目等。作为主要研究人员参与了国家实验室项目、国家863项目、科技部国际合作专项、中国科学院院长基金项目、中国科学院知识创新重要方向性项目等。
在Small、Journal of Materials Chemistry A、Chemical Engineering Journal、Journal of Power Sources、Energy、Separation and Purification Technology、Journal of CO2 Utilization等期刊上发表一百余篇SCI论文,申请发明专利十余项。
成果简介
高水平代表性论文(近五年)
[1] B. Qian, P.K. Shan, H. Ye, L. Ge, H. Chen, J. Yang*, Y.F. Zheng*, S. Cui, Achieving Fast Reconstruction of Metal/Ruddlesden-Popper Layered Perovskite Heterointerfaces via Structural Flexibility-Driven Phase Transition Engineering for Efficient and Durable CO2 Electrolysis, Small, 2025, 21: e08777.
[2] H. Ye, Z.P. Miao, Y.F. Fu, P.K. Shan, B. Qian, L. Ge, H. Chen, Y.F. Zheng*, S. Cui*, Chlorine-anion doping enhances the metal-oxygen covalency of Bi0.5Sr0.5FeO3-δ air electrode: achieving superior catalytic activity for reversible solid oxide cells, Chemical Engineering Journal, 2025, 524: 169403.
[3] C.S. Yuan, D.W. Feng, H. Ye, P.K. Shan, L. Ge, H. Chen, Y.F. Zheng*, S, Cui, B-site high valence cation co-doping boosts fast oxygen kinetics in a cobalt-free perovskite air electrode for reversible solid oxide cells, Journal of Materials Chemistry A, 2025, 13: 32562–32576.
[4] B. Qian, D. Zhang, P.K. Shan, H. Ye, Y.F. Zheng*, An active and robust La0.75Sr0.25Cr0.5Mn0.5O3-based fuel electrode coated with in situ grown nanoparticles via electron conduction and oxygen exchange enhancements for solid oxide electrolysis cells, Journal of Materials Chemistry A, 2025, 13: 16092–16101.
[5] J.X. Yan, X.K. Yi, W. Zhao, Y.F. Zheng*, Nonmetallic Phosphorus-Driven Oxygen Vacancy and Electronic Structure Modulation Enhancing Bifunctional Catalytic Activity of Cobalt-Based Spinel Air Electrode for Rechargeable Zn−Air Batteries, ACS Applied Materials & Interfaces, 2025, 17: 47057–47069.
[6] B. Yang, L. Wang, B. Yin, H. Chen*, Y.F. Zheng*, Ultra-low solid content porous alumina ceramics with high strength prepared from stable wet foam, Ceramics International, 2025, 51: 53223–53231.
[7] W. Zhao , J.X. Yan , C. Zhu , G.W. Zhuang , Y.F. Zheng*, Reduced graphene aerogel anchored with MnCo2O4.5 spinel by self-assembly technique to boost bifunctional catalytic activity for zinc-air batteries, International Journal of Hydrogen Energy, 2025, 123: 1–10.
[8] P.K. Shan, H. Ye, Z.P. Chen, B. Qian, C. Zhou, H. Yang*, Y.F. Zheng*, Anionic engineering of the Ruddlesden-Popper oxide La2NiO4+δ: Targeted enhancement of the electrocatalytic activity of air electrodes via chemical fluorination for solid oxide electrolysis cells, Journal of Power Sources, 2025, 642: 236940.
[9] J.Y. Qi, C.S. Yuan, H. Ye, P.K. Shan, S.Q. Li, S.C. He, H. Chen, L. Ge, Y.F. Zheng*, Tailoring the catalytic activity of PrBaFe2O5+δ cathode material with non-transition metal In-doping for solid oxide fuel cells, Journal of the European Ceramic Society, 2025, 45: 117057.
[10] H. Ye, Y.X. Feng, P.K. Shan, B. Qian, L. Ge, H. Chen, Y.F. Zheng*, Anionic and cationic co-doping to enhance the oxygen transport property of Bi0.5Sr0.5FeO3-δ as a high-performance air electrode for reversible solid oxide cells, Chemical Engineering Journal, 2024, 499: 156105.
[11] S. Wang, P.K. Shan, B. Qian, Y.F. Zheng*, Sulfur poisoning on the La0.75Sr0.25Cr0.5Mn0.5O3-δ-Gd0.1Ce0.9O2-δ fuel electrode for direct electrochemical CO2 reduction in solid oxide electrolysis cells, Journal of Power Sources, 2024, 592: 233930.
[12] B. Yang, B. Yin, H. Chen, Y.F. Zheng*, Corrosion resistance of insulating refractories for the synthesis of lithium-ion battery LiCoO2 cathode materials, International Journal of Applied Ceramic Technology, 2024, 22: e14948.
[13] Z.F. Li, H. Ye, P.K. Shan, Q. Ni, L. Sun, Y.F. Zheng*, A novel family of W-doped Bi0.5Sr0.5FeO3-δ perovskite as oxygen electrode catalyst for CO2 electrolysis in solid oxide electrolysis cells, Fuel, 2024, 358: 130381.
[14] B. Qian, S. Wang, Y.F. Zheng*, Q. Ni, H. Chen, L. Ge, J. Yang*, Ca-Fe co-doped La0.75Sr0.25Cr0.5Mn0.5O3 cathodes with high electrocatalytic activity for direct CO2 electrolysis in solid oxide electrolysis cells, Journal of CO2 Utilization, 2023, 67: 102305.
[15] Z.F. Li, B. Yang, B. Qian, S. Wang, Y.F. Zheng*, L. Ge, H. Chen, Evaluation of Fe-doped Pr1.8Ba0.2NiO4 as a high-performance air electrode for reversible solid oxide cell, Separation and Purification Technology, 2023, 308: 123002.
授权代表性发明专利
[1]一种高强度高孔隙率多孔陶瓷及其制备方法,ZL202110284412.2
[2]一种防返碱铝硅系浇注料及其制备方法,ZL202210947506.8
[3]一种气水混合装置和一种气水联供系统,ZL201210583649.1.
[4]一种密封材料及其制备方法,ZL201310648652.1.
[5]一种固体氧化物燃料电池堆生产和测试装置,ZL201310385899.9.
[6]平板式固体氧化物燃料电池系统,ZL201310566142.X.
[7]一种线切割用碳化硅微粉的提纯净化工艺,ZL200910033202.5.
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