
富鸣
博士、教授、发光与光信息技术教育部重点实验室副主任
博士、教授、发光与光信息技术教育部重点实验室副主任
办公电话: | 电子邮件: mfu@bjtu.edu.cn |
通讯地址:光电子技术研究所(1教)206 | 邮编:100044 |
(1) 2002年8月 -- 2007年7月 清华大学 博士研究生
获得工学博士学位,清华大学优秀博士论文获得者,导师:周济 院士
(2) 1998年 8月 -- 2002年7月 清华大学 本科
获得工学学士学位,清华大学优秀毕业生,导师:周济 院士
(1) 2014年至现在, 北京交通大学, 物理工程学院光电子技术研究所(发光与光信息技术教育部重点实验室), 教授,博士生导师. 现任发光与光信息技术教育部重点实验室副主任
(2) 2018年--2019年, 美国康奈尔大学(Cornell)工学院,访问教授
(3) 2012年--2013年, 美国伊利诺伊大学香槟分校(UIUC)工学院,访问学者
(4) 2010年--2014年, 北京交通大学, 理学院光电子技术研究所(发光与光信息技术教育部重点实验室), 副教授
(5) 2007年--2010年, 北京交通大学, 理学院光电子技术研究所(发光与光信息技术教育部重点实验室), 讲师
个人简介:
北京市青年英才、北京交大红果园人才,入选北京交大首批卓越百人计划。作为负责人课题负责人正在承担或完成国家自然科学基金面上项目、国家自然科学基金重大研究计划、国家自然科学基金青年基金、教育部博士点基金、中央高校基本科研业务费等科研项目;作为研究骨干参与了北京市、教育部、铁道部等科研项目工作。
研究思路与兴趣:
融合低成本构建手段、光电测试技术、光(电)仿真方法\人工智能(深度学习),着力开拓现代前沿光学手段,面向人类关注焦点问题:
①具有特异光学性能的微纳光子材料与器件的低成本实现前沿问题。基于自组织、光刻技术、二维三维复形手段进行光子晶体、超常电磁介质、等离子激元晶体等微纳光电子器件的构建及性能探索。
②以特异光学性能为手段,基于新型纳米光子结构—面向光能(太阳能)吸收与利用、面向健康医学的光学传感检测、面向舒适生活的光热调控与发光增强、面向新型光学系统的超透镜等前沿问题研究及性能发展探索。
微纳光电子技术 32学时(本科,主讲)
现代光谱技术 32学时 (研究生,主讲)
材料物理 32-64学时(本科,主讲)
光电信息科学与工程专业导论(本科,参与)
Introduction to Modern Materials and Nanoscience (本科,参与)
纳米技术 32-48学时(全校任选课, 曾主讲)
光电专业实验(本科,曾参与)
光电前沿 (本科,曾参与)
代表性学术论文:
1. Yuting Zhang, Zhengjie Guo, Gaoxiang Li, Ming Fu,* et.al., High-aspect-ratio photoresist nanopillar arrays with broadband near-perfect optical absorption performance using PDMS-assisted colloidal lithography, Journal of Material Chemistry C, doi.org/10.1039/D5TC00296F(2025)
2. Jiefeng Li, Ming Fu,* et.al., Hierarchical Microspheres‐Based Composite Materials with TiO₂‐Coated SiO₂ Combined with BaSO₄ or PNIPAM for Radiative Cooling, Advanced Optical Materials, 13, 2402846(2025)
3. Aiguo Rao, Shiyu Zhang,* et.al., Ming Fu,* Top Electrode‐Free Electrochromic Device with Ultra‐Flexibility and Wide Color Gamut Based on Porous Resonant Cavity. Small, 21, 2412644(2025)
4. Zheli Wu, Jie Long, Ming Fu,* et.al., Advanced photoelectrochemical performance of inverse-opal heterostructures fabricated using hydrogenated ZnO and TiO2, Journal of Materials Chemistry C,12, 11073-11084(2024)
5. Jiefeng Li, Ming Fu,* et.al, Versatile fabrication of spherical inverse opals from diverse materials including Bi₂O₃/g-C₃N₄ and MXene/H-TiO₂ using hierarchical microspheres as templates, Ceramics International, 51, 6253-6263(2025)
6. Xiaoyu Liu, Ming Fu*, et.al., The Broadband Optical Absorption Performance of Rod-Based Hyperbolic Metamaterials in Cuboidal Patterns. Advanced Optical Materials, 11, 2301304 (2023).
7. Xiaoyu Liu, Ming Fu*, et.al., Broadband near-perfect optical absorbers fabricated with complete spherical platinum shells with and without induced symmetry broken cracks using a simple colloidal route. Journal of Material Chemistry C, 11, 5337-5347 (2023).
8. Zheli Wu, Ming Fu*, et.al. Boosting the photocathode performances of protected Cu₂O inverse opals using photonic-crystal heterostructures, Applied Surface Science 644, 158792(2024).
9. Rui Yang, Ming Fu*, et.al., Band edge induced plasmonic excitation in heterostructures consisting of rod hyperbolic metamaterials and colloidal photonic crystals, Journal of the Optical Society of America B, 40, 1968-1975. (2023)
10. Chenhui Wei, Caixia Li, Zhengkang Dou, Ming Fu*, et.al., Directional Assembly of Large-Area Silica Nanorod Film Using the Electric-Field-Assisted Capillary Channel Method, Langmuir, 39, 11819-11827(2023).
11. Caixia Li, Jiatong Liu, Zheli Wu, Zhe Chen, Jingwen Jiang, Zhengkang Dou, Xiaoyu Liu, Ming Fu*, et.al., Hyperbolic Metamaterials Fabricated using Three-dimensional Assembled Nanorod Arrays and Enhanced Photocatalytic Performance, Advanced Optical Materials, 9, 2100778 (2021)
12. Zhengjie Guo, Xiaoyu Liu, Caixia Li, Jiefeng Li, Haotian Cai, Ming Fu*, et.al., Near-perfect Broadband Metamaterial Absorbers of Truncated Nanocones Using Colloidal Lithography, Optical Materials, 119, 111352 (2021)
13. Chenyan Geng, Haiyan Sun, Lihui Ma, Cheng Ling, Ming Fu*, et.al., 3D Hybrid Plasmonic Photonic Crystals by Colloidal-Crystal Templating and Hydrogel-Assisted Conformal Metal Etching, Advance Optical Materials, 7, 1900599 (2019)
14. Jie Long, Ming Fu*, et.al., Applied Surface Science, 454, 112-120 (2018)
15. Xin Wang, Yinglei Tao, Haiyan Zhao, Ming Fu*, et. al., Journal of Alloys and Compounds 704, 131-140 (2017)
16. Ming Fu*, Xin Wang et.al. CrystEngComm, 18, 7780-7786 (2016)
17. Yuqiong Zhao, Ming Fu*, et.al.,The Journal of Physical Chemistry C, 118,22785-22791(2014)
18. Shulei Li, Ming Fu* et. al., The Journal of Physical Chemistry C, 118,18015-18020 (2014)
19. Ming Fu*, Ailun Zhao et. al., Chemistry of Materials, 26, 3084-3088 (2014)
20. Ming Fu, Kundan Chaudhary et. al., Advanced Materials, 26, 1740-1745 (2014)
21. Shulei Li, Ming Fu* et. al., Journal of Materials Chemistry C, 1, 5072 (2013)
22. Ming Fu* et.al. The Journal of Physical Chemistry C, 114, 9216–9220 (2010)
23. Ming Fu et.al, Journal of Materials Chemistry, 18, 5986–5992 (2008)
24. Ming Fu et.al, Advanced Materials, 18, 1001–1004 (2006)