■教育经历:
2012.09--2016.07湖北理工学院 无机非金属材料工程 工学学士
2017.09--2018.07华南理工大学 材料物理与化学硕博连读
2018.09--2022.07华南理工大学 物理学 理学博士
■工作经历:
2022年7月--至今,沙巴足球(中国)股份有限公司官网,专任教师
■学术论文:
[1]Chengwen Huang, Huangzhong Yu*, High Performance Polymer Solar Cells Based HfO2 passivated 2D-HfX2 (X=S, Se) as a Hole Transport Layers, Nano Energy, 2022, 103, 107750. (JCR一区,IF=19.096)
[2] Chengwen Huang, Shengwei Shi, Huangzhong Yu*, Work functions tuning of Nb2CTx flakes as hole and electron extraction layers in organic solar cells by controlling surface functional groups, ACS Energy Letters, 2021, 6, 3464−3472. (JCR 一区,IF=23.101)
[3] Chengwen Huang, Huangzhong Yu*, 2D Bi2O2Se with High Mobility for High Performance Polymer Solar Cells, ACS Applied Materials & Interfaces, 2020, 12, 19643. (JCR 一区,IF=9.229)
[4] Chengwen Huang, Huangzhong Yu*, Enhanced carrier mobility and power conversion efficiency of organic solar cells by adding 2D Bi2OS2, 2D Materials. 2020, 7, 025023. (JCR 一区,IF=7.103)
[5] Chengwen Huang, Huangzhong Yu*, Jinyun Chen, Jiang Zhang, Zuping Wu, Chunli Hou, Improved performance of polymer solar cells by doping with Bi2O2S nanocrystals, Solar Energy Materials and Solar Cells, 2019, 200, 110030. (JCR 一区,IF=7.267)
[6] Chengwen Huang, Huangzhong Yu*, Amino acid modified Ti3C2Tx as electron extraction layers for high performance organic solar cells, submitted.
[7] Chunli Hou, Chengwen Huang, Huangzhong Yu*. Surface-engineered Ti3C2Tx with tunable work functions for highly efficient polymer solar cells, 2022, 2201046. (共一作,JCR一区, IF=13.281)
[8] Jiankai Zhang, Chengwen Huang, Huangzhong Yu*, Modulate the work function of Nb2CTx MXene as the hole transport layer for perovskite solar cells, Applied Physics Letters, 2021,119, 033506. (JCR 二区,IF=3.791)
[9] Jiankai Zhang, Chengwen Huang, Huangzhong Yu*, Modulating the work function of niobium-carbide MXene combine with additive engineering for the preparation of high-performance methylammonium-free perovskite solar cells, Advanced Functional Materials, 2022, 2113367. (JCR 一区,IF=18.808)
[10]Jiankai Zhang, Yapeng Sun, Chengwen Huang, Bo Yu, Huangzhong Yu*,Reduced Vocloss of perovskite solar cells via forming p/p+ homojunction and interface electric field on the surfaces of perovskite film, Advanced Energy Materials. (JCR 一区,IF=29.698)
[11] Jingyu Tan, Yujun Zhao, Guangliang Li, Song Yang, Chengwen Huang, Huangzhong Yu*,High-performance Organic Solar Cells by adding Two-Dimensional GeSe, Advanced Functional Materials. (JCR 一区,IF=18.808)
[12] Jinyun Chen, Jiankai Zhang, Chengwen Huang, Zhuoneng Bi, Huangzhong Yu*, Shengwei Shi*, Xu, Xueqing Xu*, Two-dimensional Bi2OS2 doping improves the performance and stability of perovskite solar cells, Chemical Engineering Journal, 2021, 420, 127700. (JCR 一区,IF=13.273)
[13] Jinyun Chen; Jiankai Zhang; Chengwen Huang; Zhuoneng Bi; Xueqing Xu*; Huangzhong Yu*, SnO2/2D-Bi2O2Se new hybrid electron transporting layer for efficient and stable perovskite solar cells, Chemical Engineering Journal, 2021, 410, 128436. (JCR 一区,IF=13.273)
[14] Chunli Hou, Huangzhong Yu*, Chengwen Huang, Solution-processable Ti3C2Tx nanosheets as an efficient hole transport layer for high-performance and stable polymer solar cells, Journal of Materials Chemistry C, 2019, 7, 11549-11558. (JCR 一区,IF=7.393)
[15] Yapeng Sun, Jiankai Zhang, Huangzhong Yu*, Jianming Wang, Chengwen Huang, Jinzhen Huang, Mechanism of Bifunctional P-amino Benzenesulfonic Acid Modified Interface in Perovskite Solar Cells, Chemical Engineering Journal, 2021, 6, 129579. (JCR 一区,IF=13.273)
[16] Huangzhong Yu*, Xinxin Huang, Chengwen Huang, PEIE doped ZnO as a tunable cathode interlayer for efficient polymer solar cells, Applied Surface Science, 2019, 470, 318-330. (JCR 一区,IF=6.707)
[17] Xinxin Huang, Huangzhong Yu*, Shengwei Shi, Chengwen Huang, Improving the performance of inverted polymer solar cells by the efficiently doping and modification of electron transport layer-ZnO, Organic Electronics, 2019, 65, 311-320. (JCR 二区,IF=3.721)
[18]Huangzhong Yu*, Zuping Wu, Yifan Dong, Chengwen Huang, Shengwei Shi, Yuxia Zhang, ZnO nanorod arrays modified with Bi2S3 nanoparticles as cathode for efficient polymer solar cells, Organic Electronics, 2019, 75, 105369. (JCR 二区,IF=3.721)
[19] Huangzhong Yu*, Zuping Wu, Chengwen Huang, Chunli Hou, Surface Modification on Nanoripple-like ZnO Nanorod Arrays Using Two-dimensional (2D) Bi2OS2 to Fabricate High-Performance Inverted Polymer Solar Cells, Applied Surface Science, 2020, 513, 145874. (JCR 一区,IF=6.707)
■知识产权:
[1] 发明专利, 於黄忠; 黄承稳; 黄欣欣; 巫祖萍; 陈金雲; 韩俊杰, 一种CsGeI3掺杂有机太阳能电池及其制备方法,授权公布号:CN109244240B,申请号:201810824768.9。
[2] 发明专利, 於黄忠; 黄承稳, 一种高迁移率二维Bi2O2Se掺杂的三元太阳能电池及制备方法,申请号:2019109384283,授权公布号:CN110676386B。
[3] 发明专利, 於黄忠; 黄承稳; 张弜; 黄欣欣; 巫祖萍; 陈金雲, 有机太阳能电池的活性层及其制备方法,申请号:2018109208145,申请公布号:CN109256469A。
[4]发明专利,於黄忠; 黄承稳,一种基于HfS2为空穴传输层的有机太阳能电池及其制备方法,申请号:CN202110770901.9,申请公布号:CN113690373A
[5] 发明专利, 於黄忠; 张弜; 黄承稳; 黄欣欣; 巫祖萍; 陈金雲; 薛开元, 一种Cs2SnI6掺杂有机太阳能电池及其制备方法,授权公布号:CN109216563B,申请号:201810825225.9
[6] 发明专利, 於黄忠; 张弜; 黄承稳; 黄欣欣; 巫祖萍; 陈金雲; 林卓耿, 一种CsSnI3掺杂有机太阳能电池及其制备方法,授权公布号:CN109216553B,申请号:201810824771.0
[7] 发明专利, 於黄忠; 张弜; 黄承稳; 黄欣欣; 巫祖萍; 陈金雲, 一种Bi2OS2掺杂有机太阳能电池及其制备方法,授权公告号:CN109301070B,申请号:201810824964.6
[8] 发明专利, 於黄忠; 张弜; 黄承稳; 黄欣欣; 巫祖萍; 陈金雲, 一种CsPbBr3掺杂有机太阳能电池及其制备方法,授权公告号:CN109244241B,申请号:2018108252225
[9] 发明专利, 於黄忠;侯春利;黄承稳, 一种MXene掺杂PEDOT:PSS为阳极修饰层材料的有机太阳能电池及其制备方法,授权公告号:CN109904326B,申请号:2019100497962。
[10] 发明专利, 於黄忠;陈金雲;黄承稳;巫祖萍;侯春利;王键鸣, Bi2O2S修饰SnO2电子传输层的钙钛矿太阳能电池及制备方法,授权公告号:CN110350089B,申请号:2019105255902。
[11] 发明专利, 於黄忠;陈金雲;黄承稳;巫祖萍;侯春利;王键鸣,Bi2O2Se界面修饰的钙钛矿太阳能电池及制备方法,授权公告号:CN110350090B,申请号:2019105473447。
[12] 发明专利, 於黄忠;黄金珍;黄承稳;侯春利;王键鸣;张健开;孙亚鹏,以掺杂了生物材料GHK-Cu的ZnO薄膜为电子传输层的有机太阳能电池及其制备方法,申请号:202011488757.1
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