一、个人简介

郑云，教授，博士生导师，入选国家教育部海外引才专项、福建省引进高层次创业创新人才项目（省引才“百人计划”）、福建省“闽江学者”奖励计划项目。长期致力于高安全高比能固态电池的基础与应用研究。近十年共发表SCI论文110多篇，其中以第一作者或通讯作者在PNAS、Joule、J. Am. Chem. Soc.、Angew. Chem. Int. Ed.（2篇）、Adv. Mater.（5篇）、Adv. Energy Mater.（3篇）、Adv. Funct. Mater.（2篇）、Chem. Soc. Rev.（2篇）、Prog. Mater. Sci. 等著名期刊上发表论文近60篇，13篇入选高被引论文、热点文章和封面文章。共出版学术专著3本，授权/公布发明专利22项，主持/参与国家级科研项目10余项。

（欢迎有材料、化学、化工、能源、物理等专业背景的学生报考博士/硕士研究生！）

 

主要社会兼职：

1. 著名国际电化学组织International Academy of Electrochemical Energy Science（IAOEES）理事（Board Committee Member, 2022-）

2. 中国科协青年人才托举工程博士生专项计划托举导师（2025-）

3. 化学工业出版社“氢能技术丛书”编委会委员（2023-）

4. 著名期刊International Journal of Green Energy编委（2022-）

5. 著名期刊Renewables、Exploration、Carbon Neutrality、Advanced Powder Materials青年编委（2024-）

6. 中国工程院院刊系列Frontiers in Energy青年编委、客座编辑和学科编辑（2022-）

7. Advanced Materials, Advanced Energy Materials等国际知名期刊审稿人

 

个人联系方式：

电子邮箱：yunzheng@fzu.edu.cn 

个人主页：https://scholar.google.com/citations?user=VXNb6poAAAAJ&hl=zh-CN 

 

 

二、教育/工作经历

2023.01—至 今，福州大学，材料科学与工程学院，新能源材料与工程研究院，教授

2019.04—2022.12，加拿大滑铁卢大学，化学工程系，博士后

2015.08—2019.01，清华大学，核能与新能源技术研究院，博士

 

 

三、研究方向

主要从事固态电化学能源材料方面的研究，具体包括：

（1）高安全高比能固态电池（柔性固态电解质及电极界面调控）

（2）氢能燃料电池催化剂及电极材料

 

 

四、获奖及荣誉

1. 中国材料大会2025“高水平学术报告”奖励（2025）

2. 2024威立中国开放科学高贡献作者（Wiley）

3. 2024全球前2%顶尖科学家（Elsevier/Stanford）

4. 中国工程院院刊系列Frontiers in Energy“优秀青年编委”（2024）

5. 中国精品科技期刊顶尖学术论文（F5000，2024）

6. 2024年度福州大学五四青年奖章

7. 福建省“闽江学者”奖励支持计划（福建省，2023）

8. 加拿大政府MITACS项目奖（加拿大政府，2021）

 

 

五、科研成果

 

学术专著：

[1]  Yun Zheng, Bo Yu, Jianchen Wang, Jiujun Zhang, Carbon dioxide reduction through advanced conversion and utilization technologies, CRC Press, Taylor & Francis Group, Suite 300, Boca Raton, Florida 33487, U.S.A., May 2019, 1-326, ISBN 9781138095298 (hardback), ISBN 9781315104171 (ebook). (共16章)

[2]  郑云, 新型固体氧化物池异质结构氧电极研究, 清华大学出版社, 北京, 2025. (共7章)

 

学术论文（近五年代表性论文）：

[1]  Song Duan, Zongtao Lu, Yun Zheng*, Lifen Zhang, Zhenghao Li, Zewen Liu, Yiyuan Luo, Bingsen Qin, Xiang Liu, Yao Liu*, Maojun Pei, Jiaming Xu, Xiuzhou Lin, Wei Yan, Jiujun Zhang*, Directionally aligned “mechanical balance” design enables near-frictionless Li⁺ transport in polymer electrolytes, Journal of the American Chemical Society, 2025, Accept.

[2]  Tianzhu Zhang, Tao Wang, Yun Zheng*, Lanting Qian*, Xiang Liu, Wei Yan*, Jiujun Zhang*, Atomic layer deposition for sodium-ion battery, Advanced Energy Materials, 2025, Accept.

[3]  Zhenghao Li, Hongyao Wang, Yun Zheng*, Yanfei Zhu, Bingsen Qin, Zongtao Lu, Wei Yan*, Jiujun Zhang*, “Gene editing” design upgrades eutectic-polymer electrolytes with ultra-high Li⁺ conductivity, Angewandte Chemie International Edition, 2025, e202508857.

[4]  Song Duan, Lifen Zhang, Yun Zheng*, Zhenghao Li, Zewen Liu, Can Liao*, Hongyao Wang, Wei Yan, Jiujun Zhang*, “Rigid exterior, soft interior” design enables high-voltage polyether electrolytes for quasi-solid-state batteries, Angewandte Chemie International Edition, 2025, e202502728. 

[5]  Yun Zheng*, Na Yang, Song Duan, Zhenghao Li, Rui Gao, Yanfei Zhu, Hongyao Wang, Tianzhu Zhang, Gaoran Li, Dan Luo, Leixin Yang, Dongniu Wang, Wei Yan, Jiujun Zhang*, Zhongwei Chen*, Dual-enhanced charge transfer through prelithiation strategy in polymer electrolyte enables robust LiF-rich SEI for ultralong-life all-solid-state batteries, Advanced Functional Materials, 2025, e11011.

[6]  Tianzhu Zhang, Kaixin Huang, Yun Zheng*, Dan Luo, Wei Yan, Jiujun Zhang*, Zhongwei Chen*, Loss and recovery of effective lithium in anode-free solid-state lithium metal batteries, Advanced Materials, 2025, e15702.

[7]  Hongyao Wang, Lanting Qian, Yun Zheng*, Song Duan, Bingsen Qin, Zewen Liu, Zhenghao Li, Qianyi Ma, Yidong Jiang, Wei Yan*, Jiujun Zhang*, Microenvironment regulation unlocks high Li⁺ conduction in polyether electrolytes for high-performance quasi-solid-state batteries, Advanced Materials, 2025, e10197.

[8]  Zhenghao Li, Yun Zheng*, Can Liao, Song Duan, Xiang Liu, Guohui Chen, Li Dong, Wei Yan*, Jiujun Zhang*, Advanced polymer materials for protecting lithium metal anodes of liquid-state and solid-state lithium batteries, Advanced Functional Materials, 2024, 2404427.

[9]  Song Duan, Lanting Qian, Yun Zheng*, Yanfei Zhu*, Xiang Liu, Li Dong, Wei Yan, Jiujun Zhang*, Mechanisms of the Accelerated Li⁺ Conduction in MOF-based solid-state polymer electrolytes for all-solid-state lithium metal batteries, Advanced Materials, 2024, 2314120. (ESI 1%, 高被引)

[10] Yun Zheng, Na Yang, Rui Gao, Zhaoqiang Li, Haozhen Dou, Gaoran Li, Lanting Qian, Yaping Deng, Jiequan Liang, Leixin Yang, Yizhou Liu, Qianyi Ma, Dan Luo, Ning Zhu, Kecheng Li, Xin Wang*, Zhongwei Chen*, “Tree trunk” design for flexible solid-state electrolyte with hierarchical ion-channels enabling ultralong-life lithium metal batteries, Advanced Materials, 2022, 2203417.

[11] Shufan Wang, Yun Zheng*, Chenhui Xu, Haishan Liu, Lingfei Li, Wei Yan*, Jiujun Zhang*, Performance failure mechanisms and mitigation strategies of high-temperature proton exchange membrane fuel cells, Progress in Materials Science, 2025, 148, 101389.

[12] Shufan Wang, Lingfei Li, Yun Zheng*, Chenhui Xu, Zewen Zhuang*, Kaian Sun, Wei Yan*, Jiujun Zhang*, Charge regulation through rare earth metal oxides for single-atomic/cluster Co-based electrocatalysts towards boosting oxygen reduction reaction, Applied Catalysis B: Environment and Energy, 2025, 377, 125493. 

[13] Chunxia Wang †, Wenxuan Guo†, Tianle Chen, Wenyi Lu, Zhaoyi Song, Chengcheng Yan, Ying Feng, Fuming Gao, Xiaona Zhang, Yupeng Rao, Lanting Qian, Shengming Xu, Guoyong Huang*, Yun Zheng*, Wei Yan, Jiujun Zhang*, Advanced noble-metal/transition-metal/metal-free electrocatalysts for hydrogen evolution reaction in water-electrolysis for hydrogen production, Coordination Chemistry Reviews, 2024, 514, 215899. (ESI 1%, 高被引)

[14] Guobin Wen, Bohua Ren, Xin Wang*, Dan Luo, Haozhen Dou, Yun Zheng, Rui Gao, Jeff Gostick, Aiping Yu*, Zhongwei Chen*, Continuous CO₂ electrolysis using a CO₂ exsolution-induced flow cell, Nature Energy, 2022, 7, 978–988. (ESI 1%, 高被引)

[15] Yun Zheng, Zhongwei Chen*, Jiujun Zhang*, Solid oxide electrolysis of H2O and CO2 to produce hydrogen and low-carbon fuels, Electrochemical Energy Reviews, 2021, 4, 508–517. 

[16] Yun Zheng, Yuze Yao, Jiahua Ou, Matthew Li, Dan Luo, Haozhen Dou, Zhaoqiang Li, Khalil Amine, Aiping Yu and Zhongwei Chen*, A review of composite solid-state electrolytes for lithium batteries: Fundamentals, key materials and advanced structures, Chemical Society Reviews, 2020, 49, 8790-8839. (ESI 1%, 高被引, 热点文章)

[17] Yun Zheng, Jianchen Wang, Bo Yu*, Wenqiang Zhang, Jing Chen, Jinli Qiao*, Jiujun Zhang*, A review of high temperature co-electrolysis of H2O and CO2 to produce sustainable fuels using solid oxide electrolysis cells (SOECs): advanced materials and technology, Chemical Society Reviews, 2017, 46, 1427-1463. (ESI 1%, 高被引, 封面文章)

[18] Yanfei Zhu, Qi Zhang, Yun Zheng (Co-first), Gaoran Li, Rui Gao, Zhihong Piao, Dan Luo, Run-Hua Gao, Mengtian Zhang, Xiao Xiao, Chuang Li, Zhoujie Lao, Jian Wang, Zhongwei Chen,* and Guangmin Zhou*, Uncoordinated chemistry enables highly conductive and stable electrolyte/filler interfaces for solid-state lithium-sulfur batteries, Proceedings of the National Academy of Sciences, 2023, 120 (15), e2300197120. 

[19] Moin Ahmed, Yun Zheng (Co-first), Anna Amine, Hamed Fathiannasab, Zhongwei Chen*, The Role of artificial intelligence in electric vehicle mass adoption, Joule, 2021, 5(9), 2296-2322.

[20] Qianyi Ma, Yun Zheng (Co-first), Dan Luo, Tyler Or, Yizhou Liu, Leixin Yang, Haozhen Dou, Jiequan Liang, Yihang Nie, Xin Wang*, Aiping Yu, Zhongwei Chen*, Two-dimensional materials for all-solid-state lithium batteries, Advanced Materials, 2022, 2108079.