职务职称:教授,博士生导师 |
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所在单位:材料化学系 |
联系电话:010-82317113 |
电子邮箱:liweiping@buaa.edu.cn |
办公地点:教学区(四)-222 |
个人主页: http://www.mse.buaa.edu.cn/info/1125/5904.htm |
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Ø 基本情况:
李卫平,女,教授,博士生导师。1997年获得北京航空航天大学腐蚀与防护专业工学硕士学位, 2007年获得北京航空航天大学材料物理与化学专业工学博士学位。主要从事功能涂镀层和光电信息材料方面的教学和科研工作,分别于2010年到英国剑桥大学,2011到美国西弗吉尼亚大学进行交流访问。参与完成了多项国家自然科学基金、国家重点研发课题、国家“863”计划、航空科学基金、教育部及北京市基础科研项目,以及企业合作研究项目。发表研究论文100余篇,获国家发明专利授权20余项。
Ø 主讲课程:
研究生课程:《材料表面防护理论与技术》
本科生课程:《航空航天结构材料》《材料腐蚀科学与防护》《课程设计》《科研课堂》《清洁生产与可持续发展》等
Ø 研究方向:
(1)腐蚀与防护:功能涂镀层制备技术;轻合金表面阳极氧化处理技术;材料加速腐蚀实验方法评估和寿命预测。
(2)光电信息材料:光致聚合物全息显示材料,光电化学电池材料、敏化太阳能电池、钙钛矿太阳能电池。
Ø 教学科研成果:
获奖情况:
(1)2022年获北京市教学成果二等奖;
(2)主编《航空航天结构材料》获工信部“十四五”规划教材;
(3)2021年获北京航空航天大学优秀共产党员;
(4)2020年获北京航空航天大学教学成果一等奖;
发明专利:
(1) 李卫平,耿楠,刘慧丛,陈海宁,朱立群. 一种适用于复合电沉积的纳米级无机颗粒的分散方法[P]. 北京市:CN111809216B,2022-04-19.
(2) 李卫平,周心,陈海宁,刘慧丛,朱立群. 一种有机无机杂化纳米胶囊及其制备方法[P]. 北京市:CN108579629B,2021-01-26.
(3) 李卫平,李少杰,陈海宁,刘慧丛. 端烃基超支化聚酯以及包含其的光致聚合物材料[P]. 北京市:CN112341615B,2021-07-27.
(4) 李卫平,史志伟,陈海宁,刘慧丛. 多组分光引发体系及光致聚合物材料[P]. 北京市:CN111410705B,2021-07-06.
(5) 李卫平,陈永俊,陈海宁,刘慧丛. 裸眼3D显示屏材料及其制备方法[P]. 北京市:CN111303478B,2021-06-08.
(6) 李卫平,史志伟,陈海宁,刘慧丛. 非水溶性光致聚合组合物、材料及应用[P]. 北京市:CN110737173B,2021-05-14.
(7) 李卫平,冯剑波,陈海宁,刘慧丛,朱立群,赵木欣. 红敏光致聚合物材料、制备方法及应用[P]. 北京市:CN108931887B,2021-01-01.
(8) 刘慧丛,及猛,李卫平,陈海宁,朱立群. 阳极氧化电解液及方法、具有阳极氧化膜的铝或铝合金[P]. 北京市:CN110219031B,2020-12-08.
(9) 李卫平,白鹭,刘慧丛,陈海宁,朱立群. 铜基材料缓蚀液及其制备方法、缓蚀方法[P]. 北京市:CN110219005B,2020-11-06.
(10) 李卫平,刘慧丛,张崇惠,陈海宁,朱立群. 一种镀镍层应力调节剂及其应用[P]. 北京市:CN108754549B,2020-10-30.
(11) 李卫平,田露,刘慧丛,陈海宁. 超亲水涂料及其制备方法、其制备的超亲水涂层及应用[P]. 北京市:CN109825156B,2020-10-16.
(12) 刘慧丛,李卫平,陈海宁,邵燕静,朱立群. 一种防高温液态沥青沾污涂层及其制备方法[P]. 北京市:CN107739572B,2020-05-08.
(13) 李卫平,赵木欣,陈海宁,刘慧丛,冯剑波. 一种低折射率含氟丙烯酸树脂光致聚合物成膜剂及其制备方法[P]. 北京市:CN107501468B,2019-10-25.
(14) 李卫平,陈海宁,刘慧丛,朱立群,田露,生婧玮. 一种二氧化硅亲水纳米粒子的制备方法及应用[P]. 北京市:CN107200333B,2019-06-25.
(15) 李卫平,刘慧丛,朱立群,耿慧芳,刘家铭,常肖文. 一种用于量子点敏化太阳能电池的复合对电极及其制备方法[P]. 北京市:CN105826077B,2018-10-12.
代表性论文:
[1] H. Wang, H. Liu, Z. Dong, X. Wei, Y. Song, W. Li, L. Zhu, Y. Bai, H. Chen, Extracting ammonium halides by solvent from the hybrid perovskites with various dimensions to promote the crystallization of CsPbI3 perovskite, Nano Energy 94 (2022).
[2] Z. Dong, W. Li, H. Wang, X. Jiang, H. Liu, L. Zhu, H. Chen, Carbon nanotubes in perovskite-based optoelectronic devices, Matter 5(2) (2022) 448-481.
[3] F. Zhao, H. Liu, H. Zhu, X. Jiang, L. Zhu, W. Li, H. Chen, Amorphous/amorphous Ni-P/Ni(OH)2 heterostructure nanotubes for an efficient alkaline hydrogen evolution reaction, Journal of Materials Chemistry A 9(16) (2021) 10169-10179.
[4] H. Wang, H. Liu, Z. Dong, T. Song, W. Li, L. Zhu, Y. Bai, H. Chen, Size mismatch induces cation segregation in CsPbI3: Forming energy level gradient and 3D/2D heterojunction promotes the efficiency of carbon-based perovskite solar cells to over 15%, Nano Energy 89 (2021).
[5] H. Wang, H. Liu, Z. Dong, W. Li, L. Zhu, H. Chen, Composition manipulation boosts the efficiency of carbon-based CsPbI3 perovskite solar cells to beyond 14%, Nano Energy 84 (2021).
[6] H. Wang, Z. Dong, H. Liu, W. Li, L. Zhu, H. Chen, Roles of Organic Molecules in Inorganic CsPbX3 Perovskite Solar Cells, Advanced Energy Materials 11(1) (2021).
[7] H. Pi, W. Li, Z. Shi, H. Chen, X. Jiang, Effect of Glycerol on an N-Vinylpyrrolidone-Based Photopolymer for Transmission Holography, Polymers 13(11) (2021).
[8] X. Mao, L. Zhu, H. Liu, H. Chen, W. Li, R. Cao, W. Li, Cu/graphene composite coatings electrodeposited in a directly dispersed graphene solution after electrochemical exfoliation with enhanced oxidation resistance, Journal of Alloys and Compounds 882 (2021).
[9] Z. Li, W. Liang, W. Li, Z. Wang, L. Zhu, H. Chen, H. Liu, Facile fabrication of a Janus mesh for water fluid unidirectional transportation, Rsc Advances 11(2) (2021) 1001-1011.
[10] Z. Dong, W. Li, H. Wang, X. Jiang, H. Liu, L. Zhu, H. Chen, High-Temperature Perovskite Solar Cells, Solar Rrl 5(9) (2021).
[11] H. Wang, H. Liu, W. Li, L. Zhu, H. Chen, Inorganic perovskite solar cells based on carbon electrodes, Nano Energy 77 (2020).
[12] X. Su, L. Zhu, W. Li, H. Chen, R. Cao, H. Liu, Ascorbic acid peptized alumina sol films with enhanced corrosion resistance performance, Colloids and Surfaces a-Physicochemical and Engineering Aspects 600 (2020).
[13] X. Su, L. Zhu, W. Li, H. Chen, R. Cao, H. Liu, Effect of Alumina Sol on Formation and Properties of Electrodeposited Zinc Coatings on NdFeB Magnet, Surfaces and Interfaces 21 (2020).
[14] H. Pi, W. Li, Z. Shi, H. Chen, X. Jiang, Effect of Monomers on the Holographic Properties of Poly(vinyl alcohol)-Based Photopolymers, Acs Applied Polymer Materials 2(11) (2020) 5208-5218.
[15] M. Ji, W. Li, H. Liu, L. Zhu, H. Chen, W. Li, Effect of titanium sol on sulfuric-citric acids anodizing of 7150 aluminum alloy, Surfaces and Interfaces 19 (2020).
[16] Y. Guo, H. Liu, W. Li, L. Zhu, H. Chen, Additive Engineering Toward High-Performance CsPbI3 Perovskite Solar Cells, Solar Rrl 4(12) (2020).
[17] L. Bai, W. Li, H. Ye, L. Zhu, H. Chen, H. Liu, Synergistic protective effect between phenyltriethoxysilane-functionalized silica and BTA and its synergy applications for electrical contact protection on brass, Colloid and Interface Science Communications 36 (2020).
[18] S. Xiang, W. Li, Y. Wei, J. Liu, H. Liu, L. Zhu, S. Yang, H. Chen, Natrium Doping Pushes the Efficiency of Carbon-Based CsPbI3 Perovskite Solar Cells to 10.7%, Iscience 15 (2019).
[19] H. Wang, S. Xiang, W. Li, H. Liu, L. Zhu, S. Xiao, S. Yang, H. Chen, Skillfully deflecting the question: a small amount of piperazine-1,4-diium iodide radically enhances the thermal stability of CsPbI3 perovskite, Journal of Materials Chemistry C 7(38) (2019) 11757-11763.
[20] F. Wang, W. Li, H. Liu, L. Zhu, H. Chen, Cation substitution enables the complete conversion of 1D perovskites to 3D perovskites for photovoltaic application, Nanoscale 11(30) (2019) 14465-14471.
[21] L. Tian, W. Li, H. Ye, L. Zhu, H. Chen, H. Liu, Environmentally benign development of superhydrophilic and underwater superoleophobic mesh for effective oil/water separation, Surface & Coatings Technology 377 (2019).
[22] X. Mao, L. Zhu, H. Liu, H. Chen, P. Ju, W. Li, Synthesis of graphene via electrochemical exfoliation in different electrolytes for direct electrodeposition of a Cu/graphene composite coating, Rsc Advances 9(61) (2019) 35524-35531.
[23] J. Liu, L. Zhu, S. Xiang, Y. Wei, M. Xie, H. Liu, W. Li, H. Chen, Growing high-quality CsPbBr3 by using porous CsPb2Br5 as an intermediate: a promising light absorber in carbon-based perovskite solar cells, Sustainable Energy & Fuels 3(1) (2019).
[24] J. Liu, L. Zhu, S. Xiang, H. Wang, H. Liu, W. Li, H. Chen, Cs-Doped TiO2 Nanorod Array Enhances Electron Injection and Transport in Carbon-Based CsPbI3 Perovskite Solar Cells, Acs Sustainable Chemistry & Engineering 7(19) (2019) 16927-16932.
[25] C. Xu, H. Liu, W. Liang, L. Zhu, W. Li, H. Chen, Creating gradient wetting surfaces via electroless displacement of zinc-coated carbon steel by nickel ions, Applied Surface Science 434 (2018) 940-949.
[26] S. Xiang, W. Li, Y. Wei, J. Liu, H. Liu, L. Zhu, H. Chen, The synergistic effect of non-stoichiometry and Sb-doping on air-stable alpha-CsPbI3 for efficient carbon-based perovskite solar cells, Nanoscale 10(21) (2018) 9996-10004.
[27] S. Xiang, Z. Fu, W. Li, Y. Wei, J. Liu, H. Liu, L. Zhu, R. Zhang, H. Chen, Highly Air-Stable Carbon-Based alpha-CsPbl3 Perovskite Solar Cells with a Broadened Optical Spectrum, Acs Energy Letters 3(8) (2018).
[28] Y. Wei, W. Li, S. Xiang, J. Liu, H. Liu, L. Zhu, H. Chen, Precursor effects on methylamine gas-induced CH3NH3PbI3 films for stable carbon-based perovskite solar cells, Solar Energy 174 (2018) 139-148.
[29] Q. Deng, W. Li, L. Zhu, H. Chen, P. Ju, H. Liu, Ultrathin, highly anticorrosive and hydrophobic film for metal protection based on a composite organosilicon structure, Colloids and Surfaces a-Physicochemical and Engineering Aspects 558 (2018) 359-366.
[30] H. Chen, S. Xiang, W. Li, H. Liu, L. Zhu, S. Yang, Inorganic Perovskite Solar Cells: A Rapidly Growing Field, Solar Rrl 2(2) (2018).
[31] R. Cao, L. Zhu, W. Li, H. Chen, H. Liu, The Influence of Alumina-Silica Sol Addition on Microstructure and Protective Properties of Electrodeposited Zinc Coatings on NdFeB Magnet, Journal of the Electrochemical Society 165(2) (2018) D64-D75.
