一、个人基本信息

姓名：韩建华

出生年月：1990年4月

籍贯：山西运城

性别：男

民族：汉

职称：副教授

政治面貌：中共党员

最高学历：博士研究生

工作单位：中国民航大学理学院

通讯地址：天津市，中国民航大学北院北教15-304

邮政编码：300300

电子邮箱：jhhan@cauc.edu.cn；hanjh15@tsinghua.org.cn

Researchgate主页：https://www.researchgate.net/profile/Jianhua-Han-5

ORCID：0000-0003-3811-9413

二、学习和工作经历

学习经历：

2015/09 – 2019/07，清华大学，材料科学与工程，博士；

2012/09 – 2015/06，天津城建大学，材料科学与工程，硕士；

2008/09 – 2012/06，天津城建大学，材料科学与工程，学士；

工作经历：

2019/12 – 至今，中国民航大学，理学院，副教授；

2019/07 – 2019/11，中国民航大学，理学院，讲师；

三、招生专业

材料科学与工程；物理学

四、主讲课程

材料科学基础（本科生课程）；先进能源材料（研究生课程）

五、主要研究方向

光电功能材料/表面化学/润湿性调控

六、主持的科研项目

[1] 国家自然科学基金，52402211，主持，2025-2027.

[2] 天津市自然科学基金，24JCYBJC00040，主持，2025-2027.

[3] 国家自然科学基金配套项目，3122025PT11，主持，2025-2026.

[4] 国家自然科学基金，52572238，合作单位主持，2026-2029.

[5] 中央高校基本科研业务费重点项目，3122024059，主持，2024-2025.

[6] 天津市自然科学基金，21JCQNJC00950，主持，2021-2023.

[7] 国家自然科学基金，52072207，合作单位主持，2021-2024.

[8] 蓝天青年学者人才项目，2021-2024.

[9] 天津市教委科研项目，2020KJ032，主持，2021-2022.

[10] 中央高校基本科研业务费项目，主持，2020-2021.

[11] 清华大学新型陶瓷与精细工艺国家重点实验室开放基金，主持，2020-2021.

七、学术兼职与荣誉

[1] 天津市科学技术进步二等奖；

[2] 天津市物理学会青年科技奖；

[3] 蓝天青年学者；

[4] 中国民航大学优秀教师；

[5] 中国民航大学青年五四奖章；

[6] Frontiers in Chemistry、Inorganics等期刊特邀编辑；

[7] 指导学生获“全国大学生材料分析大赛”一等奖，2025；“中国国际大学生创新大赛”天津市银奖，2024/2025；“第九届中国国际互联网＋大学生创新创业大赛”天津市银奖；

八、著作和论文

[1] Z. Wang, L. Ye, Y. Zhang, L. Zhang, Y. Han, J. Yang, X. Han, J. Han*, D. Oron, H. Lin*, Hyperdispersed CoO_x nanofluids enables CsPbBr₃ gradient hybrid photo-response layer for superb perovskite laser cells, Nano Energy, 2025, 141: 111146.

[2] L. Ye, Z. Wang, Y. Zhang, L. Zhang, Z. Zhang, Y. Han, X. Han, J. Han*, H. Lin*, Micro-Flame-Induced Grain Boundary Reconstruction for Highly Stable and Efficient Carbon-Based CsPbBr₃ Perovskite Laser Cells, Solar RRL, 2025, 9: 2500276.

[3] Y. Li, Y. Xu, Z. Wang, Y. Chen, K. Ai, P. Guo, Y. Zhang, M. Yao, J. Han*, Pre-implanted bimolecular co-anchoring: An innovative approach towards engineering robust superhydrophobic composite coatings on Al alloy, Applied Surface Science, 2025, 706: 163611.

[4] Y. Chen, Z. Wang, Y. Li, Y. Zhou, K. Ai, Y. Chen, J. Han*, Mechanically durable resin-based superhydrophobic coating on Al alloy with interface optimization via implanted molecular anchoring, Applied Surface Science, 2025, 680: 161382.

[5] Y. Xu, Y. Li, Z. Wang, K. Ai, Y. Chen, Y. Zhang, Y. Su, J. Han*, Interfacial bonding engineering in Cr-silane hybrid coatings: durable superhydrophobic Al alloy surfaces with dual-functional anti-icing and corrosion resistance, Surfaces and Interfaces, 2025, 72: 107395.

[6] K. Ai, Y. Li, Y. Xu, Y. Chen, Z. Wang, Y. Zhang, J. Han*, Reactive Element-Effect Optimized Ni-Cr-W-Al Alloy for Fabricating Robust and Fluorine-Free Superhydrophobic Coating on Al Alloy, Advanced Engineering Materials, 2025, 27: 2402798.

[7] Z. Wang, L. Zhang, X. Liu, L. Ye, S. Zhao, Y. Chen, H. Yan, J. Han*, H. Lin*, Superwetting nanofluids of NiO_x-nanocrystals/CsBr solution for fabricating quality NiO_x-CsPbBr₃ gradient hybrid film in carbon-based perovskite solar cells, Small Methods, 2024, 8: 2400283.

[8] X. Liu, H. Zhong, X. Wang, J. Yang, Z. Zhang, J. Han*, D. Oron*, H. Lin*, Interface engineering in CdS modified PbS nanosheet-FAPbI₃ heterostructure enabling high-performance perovskite solar cell, ACS Applied Materials & Interfaces, 2024, 16: 23434-23442.

[9] S. Zhao, Z. Wang, L. Ye, H. Yan, J. Han*, H. Lin*, Bi₂S₃ nanocrystals-CsPbBr₃ hybrid absorber enables durable and efficient carbon-based perovskite solar cells, ACS Applied Energy Materials, 2024, 7: 10155-10162.

[10] J. Han*, Y. Li, Y. Zhou, Y. Chen, Z. Wang, Y. Li, B. Wang, Fluorine-free, corrosion-resistant aluminum surfaces with nickel hydroxide and stearic acid superhydrophobic coatings, Journal of Materials Science, 2024, 59: 12065-12073.

[11] J. Pan, Y. Zhou, Y. Li, B. Wang, Y. Li, Y. Chen, L. Zhang, Q. Han*, J. Han*, Mechanically durable and fluorine-free Ni-Cr alloys based highly hard superhydrophobic coating on Al alloy, Advanced Engineering Materials, 2024, 26: 2302105.

[12] X. Liu, Z. Wu, H. Zhong, X. Wang, J. Yang, Z. Zhang, J. Han*, D. Oron*, H. Lin*, Epitaxial 2D PbS nanosheet-formamidinium lead triiodide heterostructure enabling high-performance perovskite solar cells, Advanced Functional Materials, 2023, 33: 2304140.

[13] J. Han*, S. Zhao, X. Liu, Z. Wang, H. Yan, H. Lin*, Robust and efficient carbon-based planar perovskite solar cells with CsPbBr₃-MoS₂ hybrid absorber, ACS Applied Materials & Interfaces, 2023, 15: 55895-55902.

[14] J. Han*, Z. Wang, A. Zhi, Y. Li, S. Zhao, H. Yan, Q. Han*, A smart electroplating approach to fabricate mechanically robust and fluorine-free Ni-W alloys based superhydrophobic coating on Al alloy, Vacuum, 2023, 217: 112501.  

[15] Y. Li, Y. Zhou, J. Pan, E. Liu, J. Hao, J. Han*, Facile fabrication of high-white and robust superhydrophobic Ni/Al₂O₃ composite coating on Al alloy, Advanced Engineering Materials, 2023, 25: 2300920.

[16] J. Han*, S. Zhao, Z. Wang, H. Yan, H. Lin*, Y. Su*, Facile synthesis of large bulk crystal based on perovskite-quantum dots hybrid structure, Crystal Research and Technology, 2023, 58: 2300213.  

[17] Y. Zhou, E. Liu, J. Kang, S. Zhao, L. Wang, H. Yan, C. Hu, J. Han*, A universal synthetic methodology of superhydrophobic protective film on various substrates with convenient and stable precursor, Vacuum, 2023, 210: 111847.

[18] J. Han*, E. Liu, Y. Zhou, S. Zhao, H. Yan, C. Hu, J. Kang, Q. Han, Y. Su, Robust superhydrophobic film on aluminum alloy prepared with TiO₂/SiO₂-silane composite film for efficient self-cleaning, anti-corrosion and anti-icing, Materials Today Communications, 2023, 34: 105085.

[19] E. Liu, Y. Zhou, S. Zhao, J. Hao, Y. Hu, Y. Su, J. Han*, Fabricating superhydrophobic protective films with enhanced self-cleaning and anti-corrosion properties through multiple anodic oxidations on aluminum alloys, ChemistrySelect, 2023, 8: e202203935.

[20] S. Wu, D. Zhang, H. Gong, Z. Wang, Y. Huang, L. Guo, C. Hu, H. Yan, J. Kang, J. Han*, Z. Liu*, Controlling superhydrophobicity of aluminum with hierarchical micro-nanostructure film for superb self-cleaning and anti-corrosion, ChemistrySelect, 2022, 7: e202200525.

[21] J. Han, H. Yan, C. Hu, Q. Song, J. Kang, Y. Guo, Z. Liu, Simultaneous modulation of interface reinforcement, crystallization, anti-reflection and carrier transport in Sb gradient-doped SnO₂/Sb₂S₃ heterostructure for efficient photoelectrochemical cell, Small, 2022, 18: 2105026.  

[22] J. Han, H. Xing, Q. Song, H. Yan, J. Kang, Y. Guo, Z. Liu. A ZnO@CuO core-shell heterojunction photoanode modified with ZnFe-LDH for efficient and stable photoelectrochemical performance, Dalton Transactions, 2021, 50(13): 4593-4603.  

[23] J. Han, S. Zhang, Q. Song, H. Yan, J. Kang, Y. Guo, Z. Liu, The synergistic effect with S-vacancies and built-in electric field on a TiO₂/MoS₂ photoanode for enhanced photoelectrochemical performance, Sustainable Energy & Fuels, 2021, 5: 509-517.  

[24] J. Han, Z. Liu, Optimization and modulation strategies of zinc oxide-based photoanodes for highly efficient photoelectrochemical water splitting, ACS Applied Energy Materials, 2021, 4: 1004-1013.

[25] J. Han, Y. Lan, Q. Song, H. Yan, J. Kang, Y. Guo, Z. Liu, Zinc ferrite-based p–n homojunction with multi-effect for efficient photoelectrochemical water splitting, Chemical Communications, 2020, 56: 13205-13208.

[26] J. Han, X. Yin, H. Nan, Y. Zhou, M. Tai, Y. Gu, J. Li, D. Oron, H. Lin, An excellent modifier: carbon quantum dots for highly efficient carbon-electrode-based methylammonium lead iodide solar cells, Solar RRL, 2019, 3: 1900146.

[27] J. Han, X. Yin, Y. Zhou, H. Nan, Y. Gu, M. Tai, J. Li, H. Lin, High efficient large-area perovskite solar cells based on paintable carbon electrode with NiO nanocrystal-carbon intermediate layer, Chemistry Letters, 2019, 48: 734-737.

[28] J. Han, S. Luo, X. Yin, Y. Zhou, H. Nan, J. Li, X. Li, D. Oron, H. Shen, H. Lin, Hybrid PbS quantum-dot-in-perovskite for high-efficiency perovskite solar cell, Small, 2018, 14: 1801016.

[29] J. Han, X. Yin, Y. Zhou, H. Nan, Y. Gu, M. Tai, J. Li, H. Lin, Perovskite/poly[bis(4-phenyl)(2,4,6-trimethylphenyl) amine] bulk heterojunction for high-efficient carbon-based large-area solar cells by gradient engineering, ACS Applied Materials & Interfaces, 2018, 10: 42328-42334.

[30] J. Han, X. Yin, H. Nan, Y. Zhou, Z. Yao, J. Li, D. Oron, H. Lin, Enhancing the performance of perovskite solar cells by hybridizing SnS quantum dots with CH₃NH₃PbI₃, Small, 2017, 13: 1700953.

[31] J. Han, Z. Liu, K. Guo, B. Wang, X. Zhang, T. Hong, High-efficiency photoelectrochemical electrodes based on ZnIn₂S₄ sensitized ZnO nanotube arrays, Applied Catalysis B: Environmental, 2015, 163: 179-188.

[32] J. Han, Z. Liu, K. Guo, X. Zhang, T. Hong, B. Wang, AgSbS₂ modified ZnO nanotube arrays for photoelectrochemical water splitting, Applied Catalysis B: Environmental, 2015, 179: 61-68.

[33] J. Han, Z. Liu, K. Guo, J. Ya, Y. Zhao, X. Zhang, T. Hong, J. Liu, High-efficiency AgInS₂-modified ZnO nanotube array photoelectrodes for all-solid-state hybrid solar cells, ACS Applied Materials & Interfaces, 2014, 6: 17119-17125.

[34] J. Han, Z. Liu, B. Yadian, Y. Huang, K. Guo, Z. Liu, B. Wang, Y. Li, T. Cui, Synthesis of metal sulfide sensitized zinc oxide-based core/shell/shell nanorods and their photoelectrochemical properties, Journal of Power Sources, 2014, 268: 388-396.

[35] J. Han, Z. Liu, X. Zheng, K. Guo, X. Zhang, T. Hong, B. Wang, J. Liu, Trilaminar ZnO/ZnS/Sb₂S₃ nanotube arrays for efficient inorganic-organic hybrid solar cells, RSC Advances, 2014, 4: 23807-23814.