2012-2016   香港科技大學(xué)，機(jī)械工程， 博士
2008-2012   西安交通大學(xué)，能源動力系統(tǒng)及自動化，學(xué)士

2023- 至今      上海交通大學(xué)，燃料電池研究所，長聘副教授
2020-2023      上海交通大學(xué)，燃料電池研究所，長聘教軌副教授
2016-2019      上海交通大學(xué)，燃料電池研究所，特別副研究員

燃料電池技術(shù)
電解水制氫技術(shù)

電解氣泡動力學(xué)
燃料電池、電解水多尺度傳輸機(jī)制與傳質(zhì)強(qiáng)化
燃料電池/電解槽水/氣-熱管理

上海市電機(jī)工程學(xué)會電池與儲能專委會委員
Carbon Neutralization, 青年編委

電氣工程學(xué)報(bào), 客座編輯

擔(dān)任多種SCI期刊審稿人：ACS Energy Letters; eScience, Applied Energy; Chemical Engineering Science; Energy and AI; Chemical Engineering Journal...

2024-2025 慧眼行動重點(diǎn)項(xiàng)目，負(fù)責(zé)人
2023-2026 國家自然科學(xué)基金面上項(xiàng)目，"低鉑燃料電池中納米尺度離聚物對氧氣局域傳輸?shù)挠绊懸?guī)律及傳輸強(qiáng)化研究"，負(fù)責(zé)人
2022-2026 上海市市級重大科技專項(xiàng)課題，"電解池堆多物理場耦合模型構(gòu)建與在線檢測技術(shù)開發(fā)"，負(fù)責(zé)人。
2022-2023 浦東新區(qū)科技發(fā)展基金產(chǎn)學(xué)研專項(xiàng)，"具備健康管理功能的高性能燃料電池電堆快速活化系統(tǒng)"，負(fù)責(zé)人
2022-2025 國家重點(diǎn)研發(fā)計(jì)劃子課題，"電站膜電極關(guān)鍵材料部件衰減特征研究"，負(fù)責(zé)人
2021-2022 上海汽車工業(yè)科技發(fā)展基金項(xiàng)目，"燃料電池高效陰極技術(shù)"，負(fù)責(zé)人
2018-2020 國家自然科學(xué)基金青年項(xiàng)目，"PEMFC催化層中納米尺度Nafion樹脂的質(zhì)子傳導(dǎo)機(jī)理研究"，負(fù)責(zé)人

2025-2025 企業(yè)委托項(xiàng)目，“燃料電池氫氣滲透機(jī)理及優(yōu)化策略”，負(fù)責(zé)人

2022-2023 企業(yè)委托項(xiàng)目，"燃料電池膜電極技術(shù)與壽命評測技術(shù)"，負(fù)責(zé)人

2024-2028 國家自然科學(xué)基金重大項(xiàng)目，"電制合成燃料設(shè)計(jì)與制備基礎(chǔ)理論與關(guān)鍵技術(shù)"，參與

在燃料電池、電解水制氫相關(guān)領(lǐng)域發(fā)表SCI論文120余篇，引用5700余次 (google scholar)，h-index:43，2篇入選ESI熱點(diǎn)論文，5篇入選ESI高被引論文，出版英文專著1章。
一作/通訊論文如下：

[47] Shu Yuan, Lizhen Wu, Rongyi Wang, Rui Xue, Fangyuan Li, Huiyuan Li, Guiru Zhang, Peng Shen, Zhiming Bao, Congfan Zhao, Qing Wang, Jiewei Yin, Liuxuan Luo, Shuiyun Shen*, Liang An, Xiaohui Yan*, Junliang Zhang*, Breaking the transport limit of rib-channel flow field to enable amp-level CO2 electrolysis and high-purity CO output, Joule, in press.

[46] Lizhen Wu, Qing Wang, Shu Yuan, Wenzhi Li, Xiaohong Zou, Mingcong Tang, Kouer Zhang, Xiaohui Yan*, Liang An*, Bubble dynamics matters at high-rate water electrolysis, Nature Communications, in press.

[45] Shu Yuan, Congfan Zhao, Xiyang Cai, Lu An, Shuiyun Shen, Xiaohui Yan*, Junliang Zhang*, Bubble evolution and transport in PEM water electrolysis: Mechanism, Impact, and Management, Progress in Energy and Combustion Science, 96, 2023, 101075. (ESI熱點(diǎn)論文、高被引論文) ?

[44] Shu Yuan, Rongyi Wang, Rui Xue, Lizhen Wu, Guiru Zhang, Huiyuan Li, Qing Wang, Jiewei Yin, Liuxuan Luo, Shuiyun Shen*, Liang An, Xiaohui Yan*, Junliang Zhang*, Flow Field Design Matters for High Current Density Zero-Gap CO2 Electrolyzers, ACS Energy Letters, 9, 2024, 5945–5954. （封面論文）
[43] Congfan Zhao, Shu Yuan, Xiaojing Cheng, Shuiyun Shen, Ninghua Zhan, Rui Wu, Xiaohan Mei, Qian Wang, Lu An, Xiaohui Yan*, Junliang Zhang*, Agglomerate Engineering to Boost PEM Water Electrolyzer Performance, Advanced Energy Materials, 14, 2024, 2401588. (封面論文)

[42] Yongjian Su, Cheng Yan, Congfan Zhao, Enping Wang, Jiewei Yin, Shuiyun Shen, Xiaohui Yan*,  Junliang Zhang*, Tuning of Catalyst Ink Solids Content to Control Colloidal Structure and Mitigate Mass Transport Limitations in Proton Exchange Membrane Fuel Cells, Chemical Engineering Journal, in press.

[41] Shu Yuan, Congfan Zhao, Liuxuan Luo, Cehuang Fu, Huiyuan Li, Lu An, Xiaojing Cheng, Shuiyun Shen, Jiewei Yin, Xiaohui Yan*, Junliang Zhang*, Revealing the Role of Ionomer at the Triple-Phase Boundary in PEM Water Electrolyzer, The Journal of Physical Chemistry Letters, 15, 2024, 5223–5230.

[40] Xiaohui Yan, Shiqing Liu, Yongjian Su, Jiabin You, Huiyuan Li, Xiaojing Cheng, Congfan Zhao, Yong Feng, Miaomiao He, Guoqiang Zhang*, Junliang Zhang*, Effects of Ionomer Chemical Degradation on Low-Pt Proton Exchange, Future Batteries, 9, 2026, 100143. 

[39]Jiabin You, Jing Hu, Zhifeng Zheng, Huiyuan Li, Liuxuan Luo, Xiaojing Cheng, Xiaohui Yan*, Shuiyun Shen* , Junliang Zhang*, Porous carbon supports for low-Pt proton exchange membrane fuel cells, Electrochemical Energy Reviews, 8, 2025, 8-22.

[38] Yongjian Su, Shu Yuan, Jun Li, Yong Feng, Shuiyun Shen, Xiaohui Yan*, Junliang Zhang*, Bridging ink formulation and proton exchange membrane fuel cell performance: Deciphering the role of catalyst ink composition in regulating ionomer behaviors and aggregates/agglomerates structures for high performance cell design, Renewable and Sustainable Energy Reviews, 225, 2026, 116163.

[37] Rui Xue, Shu Yuan, Rongyi Wang, Tianzi Bi, Guiru Zhang, Huiyuan Li, Jiewei Yin, Liuxuan Luo, Shuiyun Shen*, Xiaohui Yan*, Junliang Zhang*, The insights into ionomer-catalyst interactions enabling high-efficiency CO2 electroreduction in pure water, Journal of Energy Chemistry, 108, 2025, 390-399.

[36] Lizhen Wu, Qing Wang, Shu Yuan, Xiaohan Mei, Qian Wang, Xiaohong Zou, Kouer Zhang, Xiaoyu Huo, Xingyi Shi, Zhefei Pan*, Xiaohui Yan*, Liang An*, Unrevealing the Interaction between Electrode Degradation and Bubble Behaviors in an Anion Exchange Membrane Water Electrolyzer, Advanced Science, 12, 2025, 2412962.

[35] Shu Yuan, Congfan Zhao, Cehuang Fu, Jiazhen Li, Yongjian Su, Rui Xue, Shuiyun Shen, Jiewei Yin, Xiaohui Yan*, Junliang Zhang*, Discovery of Bubble Accumulation Behavior in Catalyst Layer of Proton Exchange Membrane Water Electrolyzer, International Journal of Heat and Mass Transfer,  227, 2024, 125552.
[34] Yao Jiang, Tianzi Bi, Ming Cheng, Rui Xue, Shuiyun Shen, Xiaohui Yan*, Junliang Zhang*, Parameter sensitivity analysis for CO2 electrochemical reduction electrolyzer, International Journal of Hydrogen Energy, 100, 2025, 1291-1300.

[33] Congfan Zhao, Shu Yuan, Xiaojing Cheng, Fengdi Tu, Jingwei Zhou, Shuiyun Shen*, Jiewei Yin, Xiaohui Yan*, Junliang Zhang, Applications of Model Electrode for Investigations of Reaction and Transport Issues in PEMWE, Current Opinion in Electrochemistry, 49, 2025, 101601.
[32] Lizhen Wu, Zhefei Pan, Shu Yuan, Xiaoyu Huo, Qiang Zheng*, Xiaohui Yan*, Liang An*,  Optimization of dual-layer flow field in a water electrolyzer using a data-driven surrogate model, Energy and AI, 18, 2024, 100411.
[31] Xiaohui Yan, Jiazhen Li, Shu Yuan, Congfan Zhao, Cehuang Fu, Shuiyun Shen, Jiewei Yin, Junliang Zhang*, Influence and Improvement of Membrane Electrode Assembly Fabrication Methods for Proton Exchange Membrane Water Electrolysis, Journal of The Electrochemical Society, 171, 2024, 064504.
[30] Tianzi Bi, Rui Xue, Yao Jiang, Shu Yuan, Congfan Zhao, Guiru Zhang, Xiaojing Cheng, Jiewei Yin, Guanghua Wei*, Xiaohui Yan*, Junliang Zhang*, Regulating water transport and salt precipitation for CO2RR by creating a functional layer, International Journal of Hydrogen Energy, 90, 2024, 784.
[29] Shu Yuan, Congfan Zhao, Huiyuan Li, Shuiyun Shen, Xiaohui Yan*, Junliang Zhang*, Rational design of electrode for low cost proton exchange membrane water electrolyzer, Cell Reports Physical Science, 5, 2024, 101880. (Cell Reports Physical Science 2024年度最佳論文)
[28] Yongjian Su, Xiaojing Cheng, Yong Feng, Huiyuan Li, Cheng Yan, Miaomiao He, Liuxuan Luo, Shuiyun Shen, Xiaohui Yan*, Junliang Zhang*, Hierarchical Catalyst Layer Structure for Enhancing Local Oxygen Transport in Low Pt Proton Exchange Membrane Fuel Cells, Journal of Power Sources, 603, 2024, 234453.
[27] Jiabin You, Huiyuan Li, Yong Feng, Xiaojing Cheng, Liuxuan Luo, Daihui Yang, Guanghua Wei, Shuiyun Shen, Xiaohui Yan*, Junliang Zhang*, Insight  oxygen diffusion mechanism in ionomer film on catalyst surface with varying perfluorosulfonic acid and water contents, Journal of Materials Chemistry A, 12, 2024, 7248.
[26] Lizhen Wu, Zhefei Pan*, Shu Yuan, Xingyi Shi, Yun Liu, Fatang Liu, Xiaohui Yan*, Liang An*, A dual-layer flow field design capable of enhancing bubble self-pumping and its application in water electrolyzer, Chemical Engineering Journal, 488, 2024, 151000.
[25] Congfan Zhao, Shu Yuan, Xiaojing Cheng, Lu An, Jiazhen Li, Shuiyun Shen, Jiewei Yin, Xiaohui Yan*, Junliang Zhang*, Effect of PFSA Ionomer in Anode Catalyst Layer on PEM Water Electrolyzer Performance, Journal of Power Sources, 580, 2023, 233413.
[24] Shu Yuan, Congfan Zhao, Xiaohan Mei, Shuiyun Shen, Qian Wang, Xiaohui Yan*, Junliang Zhang*, Bubble Management in PEM Water Electrolysis via Imprinting Patterned Grooves on Catalyst Layer, International Journal of Heat and Mass Transfer, 212, 2023, 124249.
[23] Jiabin You, Zhifeng Zheng, Xiaojing Cheng, Huiyuan Li, Cehuang Fu, Liuxuan Luo, Guanghua Wei, Shuiyun Shen, Xiaohui Yan*, Junliang Zhang*, Insight  Oxygen Transport in Solid and High Surface Area Carbon Supports of Proton Exchange Membrane Fuel Cells, ACS Applied Materials & Interfaces, 15, 2023, 21457.
[22] Zhiling Xu, Shu Yuan, Lu An, Shuiyun Shen, Qian Xu, Xiaohui Yan*, Junliang Zhang*, Effect of Substrate Surface Charges on Proton Conduction of Ultrathin Nafion Films, ACS Applied Materials & Interfaces, 15, 2023, 10735.
[21] Congfan Zhao, Shu Yuan, Xiaojing Cheng, Zhifeng Zheng, Jia Liu, Jiewei Yin, Shuiyun Shen, Xiaohui Yan*, Junliang Zhang*, The effect of catalyst layer design on catalyst utilization in PEMFC studied via stochastic reconstruction method, Energy and AI, 13, 2023, 100245.
[20] Shiqing Liu, Shu Yuan, Yuwei Liang, Huiyuan Li, Zhiling Xu, Qian Xu, Jiewei Yin, Shuiyun Shen, Xiaohui Yan*, Junliang Zhang, Engineering the Catalyst Layers towards Enhanced Local Oxygen Transport of Low-Pt Proton Exchange Membrane Fuel Cells: Materials, Designs, and Methods, International Journal of Hydrogen Energy, 48, 2023: 4389.
[19] Xiaohui Yan, Zhiling Xu, Shu Yuan, Aidi Han, Yuanting Shen, Xiaojing Cheng, Yuwei Liang, Shuiyun Shen*, Junliang Zhang, Structural and Transport Properties of Ultrathin Perfluorosulfonic Acid Ionomer Film in Proton Exchange Membrane Fuel Cell Catalyst Layer: A Review, Journal of Power Sources, 536, 2022: 231523.
[18] Yuanting Shen, Xiaohui Yan*, Liang An, Shuiyun Shen, Lu An, Junliang Zhang*, Portable Proton Exchange Membrane Fuel Cell Using Polyoxometalates as Multi-functional Hydrogen Carrier, Applied Energy, 313, 2022: 118781.
[17] Shuiyun Shen, Lin Li, Cehuang Fu, Guanghua Wei, Xiaojing Cheng, Jiewei Yin, Xiaohui Yan*, Gang Wu, Junliang Zhang*, A Facile Strategy to Boost the Active Sites of Fe-N-C Electrocatalyst for the Oxygen Reduction Reaction, Journal of The Electrochemical Society, 169, 2022: 034506.
[16] Xiaohui Yan, Yimeng Peng, Yuanting Shen, Shuiyun Shen, Guanghua Wei, Jiewei Yin, Junliang Zhang*, The use of phase-change cooling strategy in proton exchange membrane fuel cells: a numerical study, Science China Technological Sciences, 64, 2021: 2762–2770.
[15] Yimeng Peng, Xiaohui Yan, Chen Lin, Shuiyun Shen, Jiewei Yin*, Junliang Zhang*,  Effects of flow field on thermal management in proton exchange membrane fuel cell stacks: a numerical study. International Journal of Energy Research, 45, 2021: 7617-7630.
[14] X.H. Yan, X.L. Li, C.H. Fu, C. Lin, H.M. Hu, S.Y. Shen, G.H. Wei, J.L. Zhang*, Large Specific Surface Area S-doped Fe–N–C Electrocatalysts Derived from Metal–Organic Frameworks for Oxygen Reduction Reaction.  Progress in Natural Science: Materials International, 30, 2020: 896-904.
[13] X.H. Yan, H.Z. Li, C. Lin, J.R. Chen, A.D. Han, S.Y. Shen, J.L. Zhang*, An inorganic-framework proton exchange membrane for direct methanol fuel cells with increased energy density. Sustainable Energy & Fuels, 4, 2020: 772-778.
[12] X.H. Yan, C. Lin, Z.F. Zheng, J.R. Chen, G.H. Wei, J.L. Zhang*, Effect of clamping pressure on liquid-cooled PEMFC stack performance considering inhomogeneous gas diffusion layer compression. Applied Energy, 258, 2020: 114073-114086.
[11] X.H. Yan, C. Guan, Y. Zhang, K.C. Jiang, G.H. Wei, X.J. Cheng, S.Y. Shen, J.L. Zhang*, Flow field design with 3D geometry for proton exchange membrane fuel cells. Applied Thermal Engineering, 147, 2019: 1107-1114.
[10] X.H. Yan, X.L. Zhou, T.S. Zhao*, H.R. Jiang, L. Zeng, A highly ive proton exchange membrane with highly ordered, vertically aligned, and subnanosized 1D channels for redox flow batteries. Journal of Power Sources, 406, 2018: 35-41.
[9] X.H. Yan, A. Xu, L. Zeng, P. Gao, T.S. Zhao*, A paper-based microfluidic fuel cell using hydrogen peroxide as fuel and oxidant. Energy Technology,  6, 2018: 140–143. ( "Best of Energy Technology 2018")
[8] X.H. Yan, P. Gao, G. Zhao, L. Shi, J.B. Xu, T.S. Zhao*, Transport of highly concentrated fuel in direct methanol fuel cells, Applied Thermal Engineering, 126, 2017: 290-295.
[7] X.H. Yan, Ruizhe Wu, J.B. Xu, Zhengtang Luo, T.S. Zhao*, A monolayer graphene - Nafion sandwich membrane for direct methanol fuel cells, J. Power Sources, 311, 2016: 188-194. (ESI高被引論文)
[6] X.H. Yan, H.R. Jiang, G. Zhao, L. Zeng, T.S. Zhao*, Preparations of an inorganic-framework proton exchange nanochannel membrane, J. Power Sources, 326, 2016: 466-475.
[5] X.H. Yan, T.S. Zhao*, L. An, G. Zhao, L. Shi, A direct methanol-hydrogen peroxide fuel cell with a Prussian Blue cathode, Int. J. Hydrogen Energy, 41, 2016: 5135-5140.
[4] X.H. Yan, T.S. Zhao*, G. Zhao, L. An, X.L. Zhou, A hydrophilic-hydrophobic dual-layer microporous layer enabling the improved water management of direct methanol fuel cells operating with neat methanol, J. Power Sources, 294, 2015: 232-238.
[3] X.H. Yan, T.S. Zhao*, L. An, G. Zhao, L. Zeng, A novel cathode architecture with a thin reaction layer alleviates mixed potentials and catalyst poisoning in direct methanol fuel cells, Int. J. Hydrogen Energy, 40, 2015: 16540-16546.
[2] X.H. Yan, T.S. Zhao*, L. An, G. Zhao, L. Zeng, A crack-free and super-hydrophobic cathode micro-porous layer for direct methanol fuel cells, Applied Energy, 138, 2014: 331-336. (ESI高被引論文)
[1] X.H. Yan, T.S. Zhao*, L. An, G. Zhao, L. Zeng, A micro-porous current collector enabling passive direct methanol fuel cells to operate with highly concentrated fuel, Electrochimica Acta, 139, 2014: 7-12.