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范培迅
助理研究员

博士
电话:+86-10-62781032
电子邮箱:fanpeixun@tsinghua.edu.cn
办公地址:清华大学李兆基楼A203

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2009/09-2014/06   清华大学,材料科学与工程专业,工学博士

2012/03-2012/08   英国曼彻斯特大学,国家留学基金委公派联合培养博士

2005/09-2009/06   华中科技大学,材料成型及控制工程专业,工学学士


2022/06-至今  清华大学,材料学院,助理研究员

2018/02-2022/02  美国内布拉斯加大学林肯分校,电子与计算机工程系,博士后,研究助理教授

2017/02-2018/02  美国弗吉尼亚大学,电子与计算机工程系,博士后

2014/07-2017/01  清华大学,精密仪器系光学工程博士后


担任International Journal of Extreme Manufacturing (IJEM)青年编委。

担任Advanced Materials, Advanced Functional Materials, ACS Nano, ACS Applied Materials & Interfaces, Scientific Reports, Journal of Colloid and Interface Science, Journal of Alloys and Compound, Optics Express, Optics and Lasers in Engineering, Optics and Laser Technology, Journal of Laser Applications等国际期刊审稿人。


超快激光减材、增材微纳制造

激光直接及复合材料加工

激光极端制造

材料表面工程


长期从事超快激光减材、增材微纳制造,激光材料加工,以及激光极端制造的基础和应用研究。作为主要执行负责人,在国家自然科学基金重大及面上项目、国家重点基础研发计划等工作中发挥骨干作用,并与美国能源部国家实验室、海军实验室等国家机构,麻省理工学院、斯坦福大学、罗彻斯特大学等知名高校,美国康宁、日本三菱重工等大型公司深入合作,帮助其解决复杂结构的精密微纳加工和制造难题。在金属、陶瓷、玻璃、聚合物等材料的激光加工和处理技术、方案、系统开发方面积累了丰富经验。特别是建立了多种宏-微-纳跨尺度结构的可控构建新机理和新方法,并系统开展了激光所制备独特结构在宽谱减反、光电催化、超疏水、超疏液、防除冰、减摩减阻、表面拉曼增强等方面的功能化应用研究。目前已完成以表面宏-微-纳结构高效制备及分级调控实现最黑人工金属表面、惯性约束核聚变微纳靶腔一体化设计制造等为代表的10余项激光微纳制造新技术的开发,受到国内外媒体的广泛关注。


目前已在国内外重要学术期刊及国际会议上发表论文60余篇,包括以第一作者/共同一作/共同通讯在ACS Nano,Nano Letters,Nano Energy,Applied Materials Today,International Journal of Extreme Manufacturing等SCI期刊上发表论文17篇,授权国家发明专利5项,受邀在Springer等国际出版社的重要专著中发表书稿3章。在本领域具有重大影响的国际会议(如ICALEO等)多次做邀请或口头报告。所发表论文已被Nature Communications, Advanced Materials, Advanced Functional Materials, Advanced Energy Materials, Advanced Science, Angewandte Chemie, Small, ACS Nano, Nano Energy, Energy & Environmental Science, Journal of Materials Chemistry A, Materials Today, Materials Horizons, Light: Science & Applications, Chemical Reviews, Progress of Material Science等主流期刊引用>2000次,h因子>20。代表性论文如下(完整列表见Google scholar或Researchgate):

(# Co-First Authors,*Co-Corresponding Authors)

[1] P. Fan*, B. Bai, M. Zhong*, H. Zhang, J. Long, J. Han, W. Wang, and G. Jin, “General Strategy toward Dual-Scale-Controlled Metallic Micro-Nano Hybrid Structures with Ultralow Reflectance”, ACS Nano, 2017, 11, 7401-7408.

[2] P. Fan*, B. Bai, J. Long, D. Jiang, G. Jin, H. Zhang, and M. Zhong*, “Broadband high-performance infrared antireflection nanowires facilely grown on ultrafast laser structured Cu surface”, Nano Letters, 2015, 15, 5988-5994.

[3] G. Ou#, P. Fan#, H. Zhang, W. Yu, H. Wei, M. Zhong*, and H. Wu*, “Large-scale hierarchical oxide nanostructures for high-performance electrocatalytic water splitting”, Nano Energy, 2017, 35, 207-214.

[4] P. Fan*, H. Wu, M. Zhong*, H. Zhang, B. Bai, and G. Jin, “Large-scale cauliflower-shaped hierarchical copper nanostructures for efficient photothermal conversion”, Nanoscale, 2016, 8, 14617-14624.

[5] Q. Zhu#, P. Fan#,*, N. Li, T. Carlson, B. Cui, J.F. Silvain, J.L. Hudgins, and Y. Lu*, “Femtosecond-laser sharp shaping of millimeter-scale geometries with vertical sidewalls”, International Journal of Extreme Manufacturing, 2021, 3, 045001.

[6] A. Mao#, P. Fan#,*, L. Constantin, N. Li, X. Huang, B. Cui, J.F. Silvain, X. Wang, and Y. Lu*, “Forming three-dimensional micro-objects using two-dimensional gradient printing”, Applied Materials Today, 2022, 28, 101538.

[7] M. Cai#, P. Fan#, J. Long, J. Han, Y. Lin, H. Zhang, and M. Zhong*, “Large-scale Tunable 3D Self-Supporting WO3 Micro-Nano Architectures as Direct Photoanodes for Efficient Photoelectrochemical Water Splitting”, ACS Applied Materials & Interfaces, 2017, 9, 17856-17864.

[8] G. Ou#, P. Fan#, X. Ke, Y. Xu, K. Huang, H. Wei, W. Yu, H. Zhang, M. Zhong*, H. Wu*, and Y. Li, “Defective Molybdenum Sulfide Quantum Dots as Highly Active Hydrogen Evolution Electrocatalyst”, Nano Research, 2018, 11, 751-761.

[9] P. Fan, R. Pan, and M. Zhong*, “Ultrafast Laser Enabling Hierarchical Structures for Versatile Superhydrophobicity with Enhanced Cassie-Baxter Stability and Durability”, Langmuir, 2019, 35, 16693-16711.

[10] P. Fan, Z. Sun, G.C. Wilkes, and M.C. Gupta*, “Low-temperature laser generated ultrathin aluminum oxide layers for effective c-Si surface passivation”, Applied Surface Science, 2019, 480, 35-42.

[11] P. Fan*, B. Bai, G. Jin, H. Zhang, and M. Zhong*, “Patternable fabrication of hyper-hierarchical metal surface structures for ultrabroadband antireflection and self-cleaning”, Applied Surface Science, 2018, 457, 991-999.

[12] P. Fan, M. Zhong*, B. Bai, G. Jin, and H. Zhang, “Tuning the optical reflection property of metal surface via micro-nano particle structures fabricated by ultrafast laser”, Applied Surface Science, 2015, 359, 7-13.

[13] Q. Zou, L. Deng, P. Fan*, D. Li, C. Zhang, L. Fan, L. Jiang, J.F. Silvain, and Y. Lu*, “Refractory Vertically Aligned Carbon Nanotube–Boron Nitride Nanocomposites for Scalable Electrical Anisotropic Interconnects”, ACS Applied Nano Materials, 2019, 2, 100-108.

[14] P. Fan*, M. Zhong*, B. Bai, G. Jin, and H. Zhang, “Large Scale and Cost Effective Generation of 3D Self-Supporting Oxide Nanowire Architectures by a Top-Down and Bottom-Up Combined Approach”, RSC Advances, 2016, 6, 45923-45930.

[15] P. Fan, M. Zhong*, L. Li, T. Huang, and H. Zhang, “Rapid fabrication of surface micro/nano structures with enhanced broadband absorption on Cu by picosecond laser”, Optics Express, 2013, 21, 11628-11637.

[16] P. Fan, M. Zhong*, L. Li, P. Schmitz, C. Lin, J. Long, H. Zhang, “Angle-independent colorization of copper surfaces by simultaneous generation of picosecond-laser-induced nanostructures and redeposited nanoparticles”, Journal of Applied Physics, 2014, 115, 124302.

[17] P. Fan, M. Zhong*, L. Li, P. Schmitz, C. Lin, J. Long, H. Zhang, “Sequential color change on copper surfaces via micro/nano structure modification induced by a picosecond laser”, Journal of Applied Physics, 2013, 114, 083518.

[18] P. Fan*, and M. Zhong*, “Progress on ultrafast laser fabricating metal surface micro-nano antireflection structures”, Infrared and Laser Engineering, 2016, 45, 0621001.

[19] P. Fan*, J. Long, D. Jiang, H. Zhang, and M. Zhong*, “Study on Ultrafast Laser Fabrication of UV-FIR Ultra-broad-band Antireflection Surface Micro-Nano Structures and Their Properties”, Chinese Journal of Lasers, 2015, 42, 0806005.

[20] W. Liu, P. Fan, M. Cai, X. Luo, C. Chen, R. Pan, H. Zhang, and M. Zhong*, “An integrative bioinspired venation network with ultra-contrasting wettability for large-scale strongly self-driven and efficient water collection”, Nanoscale, 2019, 11, 8940-8949.

[21] J. Long, P. Fan, D. Gong, D. Jiang, H. Zhang, L. Li, and M. Zhong*, “Superhydrophobic Surfaces Fabricated by Femtosecond Laser with Tunable Water Adhesion: From Lotus Leaf to Rose Petal”, ACS Applied Materials & Interfaces, 2015, 7, 9858-9865.

[22] J. Long, P. Fan, D. Jiang, J. Han, Y. Lin, M. Cai, H. Zhang, and M. Zhong*, “Anisotropic Sliding of Water Droplets on the Superhydrophobic Surfaces with Anisotropic Groove-Like Micro/Nano Structures”, Advanced Materials Interfaces, 2016, 3, 1600641.

[23] J. Long, P. Fan, M. Zhong*, H. Zhang, Y. Xie, and C. Lin, “Superhydrophobic and colorful copper surfaces fabricated by picosecond laser induced periodic nanostructures”, Applied Surface Science, 2014, 311, 461-467.

[24] D. Jiang, P. Fan, D. Gong, J. Long, H. Zhang, and M. Zhong*, “High-temperature imprinting and Superhydrophobicity of Micro/nano Surface Structures on Metals Using Molds Fabricated by Ultrafast Laser Ablation”, Journal of Materials Processing Technology, 2016, 236, 56-63.

[25] M. Zhong*, and P. Fan, “Applications of laser nano manufacturing technologies”, Chinese Journal of Lasers, 2011, 38, 0601001.

[26] P. Fan, and M. Zhong, Chapter “Laser Surface Micro-Nano Structuring via Hybrid Process” in the book Handbook of Laser Micro- and Nano- Engineering, Springer, 2020.

[27] M. Zhong, and P. Fan, Chapter “Ultrafast Laser Enabling Versatile Fabrication of Surface Micro-Nano Structures” in the book Laser Micro-Nano-Manufacturing and 3D Microprinting, Springer, 2020.

[28] R. Prince, P. Fan, Y. Lu, T. Baldacchini, and E.O. Potma, Chapter “Visualizing TPP Structures with Coherent Raman Scattering Microscopy” in the book Three-Dimensional Microfabrication Using Two-Photon Polymerization, William Andrew, 2019.


指导学生

        已协助导师指导博士研究生7名

        指导清华大学本科毕业设计3名,其中1名获清华大学优秀毕业论文



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