个人简介

        李微，工学博士，毕业于南开大学。入选天津市高校学科领军人才，并担任先进高效光电器件团队负责人。
        曾在中国电子科技集团公司第十八研究所从事科研工作，参与柔性铜铟镓硒薄膜太阳能电池中试线的开发，积累了丰富的新型化合物薄膜太阳电池技术研发经验。长期深耕于新型光伏/光电材料与器件技术领域，研究方向为半导体薄膜材料与器件。
        主持和参与包括国家自然科学基金、科技部“863”项目、科工局重点项目在内的多项纵向科研课题；同时承担中环领先、国家能源集团以及中电十八所等企业委托的横向项目，具备很强的工程实践开发的能力。
        在国际权威期刊发表SCI论文40余篇，已申请国内发明专利23项（其中授权专利9项），具备突出的科技创新能力。
        致力于新型化合物薄膜太阳电池产业发展，积极推动光伏领域人才培养，为区域新能源开发利用提供有力支撑。

项目

1.科技部“863”项目，规模化铜铟镓硒薄膜太阳电池成套制造工艺技术研发，主持
2.国家自然科学基金青年科学基金项目，K、Na共掺对柔性衬底CIGS薄膜表面、异质结界面微区调控的机理研究，主持
3.装备预研教育部联合基金，基于柔性可穿戴用有机/无机杂化太阳电池组件的研究，主持
4.横向课题，电镀铜薄膜技术开发，主持
5.横向课题，高温处理对硅片特性参数的研究项目，主持
6.横向课题，柔性砷化镓太阳电池衬底电镀金属层研究，主持

论文

[1] Peng Liu, Jinlian Bi *, Liyong Yao *, Boyan Li, Yujie Yuan, Yupeng Xinga, Wei Li*, Process-Structure-Property Relationships in Meniscus-Confined Electrodeposition of 3D Copper Microcomponents, ACS Applied Materials and Interface, 2026, Accepted
[2] Peng Liu, Gangchang Hu, Jinlian Bi*, Shuwang Zhang*, Wei Li*, Yujie Yuan, Yupeng Xing, Solution-Processable Protection: A Single-Step Zn-Doped Electrodeposition Strategy for Enhanced Cu Corrosion Resistance, Materials and Corrosion, 2026; 77:655–660
[3] Yuanli Li; Jinlian Bi; Wei Li; Liyong Yao; Yujie Yuan, Enhanced performance of CZTSSe solar cells with pulsed photothermal coupling surface heating: Grain growth and defect mitigation, Solar Energy Materials and Solar Cells, 302, 2026, 114341, https://doi.org/10.1016/j.solmat.2026.114341
[4] Shoutao Yang, Jinlian Bi*, Wei Li*, Yujie Yuan, High-Efficiency Ultrathin Cu(In,Ga)Se₂ Solar Cells via Enhanced Crystallinity Strategy: Rapid Thermal Process with Accelerated Cooling, Materials Letters, 417, 15, 2026, 140749, https://doi.org/10.1016/j.matlet.2026.140749
[5] Decheng Kong, Jinlian Bi*, Wei Li*, Yujie Yuan, Yupeng Xing, Copper Grid Lines Electrodepositing Assisted with High-Resolution Lithography. Journal of Electronic Materials, 2026, 55(1).DOI:10.1007/s11664-025-12464-8.
[6] Xinyi Li, Jinlian Bi*, Wei Li*, Yupeng Xing. Engineering of CdS Interlayer for Performance Enhancement in CZTS Solar Cells, Applied Physics A, (2025) 131:814   https://doi.org/10.1007/s00339-025-08938-5
[7] Gangchang Hu, Jinlian Bi*, Wei Li*, Yujie Yuan, Yupeng Xing, Micro-nano scaled copper nanowire: Deposited with meniscus-confined electrodeposition , Materials Science in Semiconductor Processing, 189, 2025, 109272
[9]Fabrication of reduced graphene oxide/manganese oxide ink for 3D-printing technology on the application of high-performance supercapacitors；JOURNAL OF MATERIALS SCIENCE；56(13)、8102-8114；2021
[9]Controllable (h k 1) Preferred Orientation of Sb2S3 Thin Films Fabricated by Pulse Electrodeposition, Solar Energy Materials and Solar Cells, 253 (2023), 112208
[10]Application of poly-Si/SiOx passivating contact in x-ray silicon pixel detector, Applied Physics A, 128 (2022) 808.
[11]Sulfurization of Electrodeposited Sb/Cu Precursors for CuSbS2: Potential Absorber Materials for Thin-Film Solar Cells. Frontiers in Materials, 8 (2022) , DOI: 10.3389/fmats.2021.818596.
[12]Smooth Cu electrodeposition for Cu(In, Ga)Se2 thin-film solar cells: Dendritic clusters elimination by Ag buffer layer. Energy Reports, 8 (2022) 1847–1852.
[13]Electrodeposition assisted sol-gel process to prepare CZTS thin films. Materials Science in Semiconductor Processing 148 (2022) 106784
[14]Interface passivation and band alignment of high efficiency Cu(In, Ga)Se2 solar cells: Application of Mo(OxSe1-x)2 buffer layer at Mo/ Cu(In, Ga)Se2 interface, Optical Materials, 133 (2022), 113059
[15]Influences of alkali incorporation and electrodeposited metal layer on formation of MoS 2 in CZTS thin films. Materials Science in Semiconductor Processing 2021, 134.
[16]wxAMPS theoretical study of the bandgap structure of CZTS thin film to improve the device performance. Optoelectronics Letters 2021, 17 (8), 475-481, DOI: 10.1007/s11801-021-0159-6.
[17]In situ observation of electric‑field induced magnetic domain evolution in (Ba,Ca)(Ti,Zr)O3–CoFe2O4 multiferroic films, Applied Physics A, 54 (2020) 126
[18]Effect of Cu content in CIGSe absorber on MoSe2 formation during post-selenization process. Materials Science in Semiconductor Processing, 2020, 121.
[19]Application of polycrystalline silicon carbide thin films as the passivating contacts for silicon solar cells, Sol Energ Mater Sol Cells, 2020, 110329
[20]Effect of sulfurization temperature on the properties of CuIn(S,Se)2 thin films fabricated from electrodeposited CuInSe2 precursors, Superlattices and Microstructures, 122 (2018) 614–623

专利

1.一种新型大晶粒ACZTS吸收层的制备方法，发明专利，天津理工大学；专利号：ZL202011092523.5
2.电沉积法与溶胶凝胶法相结合制备CZTS吸收层的方法，发明专利，天津理工大学；专利号：ZL202011091251.7