陈克强，特任教授，硕士生导师，中国地质大学（武汉），材料与化学学院

教育与工作经历：

2021.05~今:                 特任教授          中国地质大学（武汉）                    材料与化学学院

2019.07~2021.04:        副研究员          深圳大学                                            微纳光电子学研究院

2018.10~2019.12:        访问学者          美国纽约州立大学布法罗分校        化学学院

2017.07~2019.06:        博士后              深圳大学                                            电子科学与技术学院

2007.09~2017.06:        本/硕/博            武汉理工大学                                    材料科学与工程学院

 研究方向：

低维材料、半导体纳米材料的合成及其在太阳能电池、LEDs、探测器等光电领域的应用研究

欢迎对该领域感兴趣的同学们加入！

研究成果概述：

1.     以第一或通讯作者发表SCI论文16篇，包括JACS (1篇，封面论文，ESI高被引论文)，Adv. Funct. Mater. (2篇，其中1篇为ESI高被引论文)，Nano-Micro Lett. (1篇)，Coordin. Chem. Rev. (1篇)，Laser Photonics Rev. (1篇)，Adv. Opt. Mater. (2篇)，Nanoscale (4篇)，J. Mater. Chem. C (1篇)等高水平期刊论文，总引用1200余次，H因子22。获得9项中国发明专利授权。

2.     作为项目负责人主持深圳市基础研究项目（30万），广东省自然科学基金面上项目（10万），中国博士后科学基金面上项目（5万）。

期刊论文：

[1]   Keqiang Chen; Wei Jin; Yupeng Zhang; Tingqiang Yang; Peter Reiss*; Qiaohui Zhong; Udo Bach; Qitao Li; Yingwei Wang; Han Zhang; Qiaoliang Bao*; Yueli Liu*, High Efficiency Mesoscopic Solar Cells Using CsPbI₃ Perovskite Quantum Dots Enabled by Chemical Interface Engineering. Journal of the American Chemical Society, 2020, 142, 3775−3783. (封面论文, ESI高倍引论文，IF = 15.419)

[2]   Keqiang Chen, Qiaohui Zhong, Wen Chen, Binghua Sang, Yingwei Wang, Tingqiang Yang, Yueli Liu*, Yupeng Zhang*, Han Zhang*, Short-chain ligand-passivated stable α-CsPbI₃ quantum dot for all-inorganic perovskite solar cells. Advanced Functional Materials, 2019, 29, 201900991. (ESI高被引论文，IF = 18.808)

[3]   Chun-Ta Wang^#, Keqiang Chen^#, Ping Xu, Fion Yeung, Hoi-Sing Kwok, and Guijun Li*, Fully Chiral Light Emission from CsPbX₃ Perovskite Nanocrystals Enabled by Cholesteric Superstructure Stacks. Advanced Functional Materials, 2019, 29, 201903155. (IF = 18.808)

[4]   Keqiang Chen^#; Kun Qi^#; Tong Zhou^#; Tingqiang Yang^#; Yupeng Zhang;* Zhinan Guo; Chang-Keun Lim; Jiayong Zhang; Igor Zutic; Han Zhang;* Paras N. Prasad, Water-dispersible CsPbBr₃ perovskite nanocrystals with ultra-stability and its application in electrochemical CO₂ reduction. Nano-Micro Letters, 2021, 13, 172. (IF = 16.419)

[5]   Keqiang Chen; Cong Wang; Zhuoyin Peng; Kun Qi; Zhinan Guo*; Yupeng Zhang*; Han Zhang*, The chemistry of colloidal semiconductor nanocrystals: From metal-chalcogenides to emerging perovskite. Coordination Chemistry Reviews, 2020, 418, 213333. (IF = 22.315)

[6]   Linlin Shi^#; Keqiang Chen^#; Aiping Zhai;* Guohui Li; Mingming Fan; Yuying Hao, Furong Zhu; Han Zhang;* Yanxia Cui*, Status and Outlook of Metal-Inorganic Semiconductor-Metal Photodetectors. Laser & Photonics Reviews, 2021, 15, 2000401. (IF = 13.138)

[7]   Keqiang Chen^#; Yingwei Wang^#; Jiefeng Liu; Jianlong Kang; Yanqi Ge; Weichun Huang; Zhitao Lin; Zhinan Guo*; Yupeng Zhang*; Han Zhang*, In situ preparation of a CsPbBr₃/black phosphorus heterostructure with an optimized interface and photodetector application. Nanoscale, 2019, 11, 16852−16859. (IF = 7.79)

[8]   Keqiang Chen^#; Jing Zhou^#; Wen Chen; Qiaohui Zhong; Tingqiang Yang; Xue Yang; Chunyu Deng; Yueli Liu*, Growth kinetics and mechanisms of multinary copper-based metal sulfide nanocrystals. Nanoscale, 2017, 9 (34), 12470-12478. (IF = 7.79)

[9]   Keqiang Chen^#; Jing Zhou^#; Wen Chen; Qiao Chen; Peng Zhou; Yueli Liu*, A green synthesis route for the phase and size tunability of copper antimony sulfide nanocrystals with high yield. Nanoscale, 2016, 8 (9), 5146-5152. (IF = 7.79)

[10] Zhuoyin Peng*; Zheng Sun; Jianlin Chen; Wei Li; Zhimin Liu; Jian Chen; Yueli Liu*; Keqiang Chen*, Enhanced charge generation and transfer performance of the conical bamboo-like TiO₂ nanotube arrays photo-electrodes in quantum dot sensitized solar cells. Solar Energy, 2020, 205, 161−169. (IF = 5.742)

[11] Guohui Li^#; Keqiang Chen^#; Yanxia Cui*; Yupeng Zhang; Yue Tian; Bining Tian; Yuying Hao; Yucheng Wu*; Han Zhang*, Stability of Perovskite Light Sources: Status and Challenges, Advanced Optical Materials, 2020, 8, 1902012. (IF = 9.926)

[12] Leiming Wu^#; Keqiang Chen^#; Weichun Huang; Zhitao Lin; Jinlai Zhao; Xiantao Jiang; Yanqi Ge; Feng Zhang; Quanlan Xiao; Zhinan Guo; Yuanjiang Xiang; Jianqing Li; Qiaoliang Bao*; Han Zhang*, Perovskite CsPbX₃: A promising nonlinear optical material and its applications for ambient all-optical switching with enhanced stability. Advanced Optical Materials, 2018, 6 (19), 1800400. (IF = 9.926)

[13] Yingwei Wang^#, Keqiang Chen^#, Huang Hao, Guannan Yu, Bowen Zeng, Hui Wang, Feng Zhang, Leiming Wu, Jianqing Li, Si Xiao, Jun He, Yupeng Zhang*, Han Zhang*, Engineering ultrafast charge transfer in bismuthene/perovskite nanohybrid. Nanoscale, 2019, 11(6), 2637-2643. (IF = 7.79)

[14] Feng Zhang^#; Keqiang Chen^#; Qiangliang Bao*; Han Zhang*, Nonlinear optical absorption and ultrafast carrier dynamics of copper antimony sulfide semiconductor nanocrystals. Journal of Materials Chemistry C, 2018, 6 (33), 8977-8983. (IF = 7.393)

[15] Guang S. He^*#; Keqiang Chen^#; Junhui Liu; Paras N. Prasad, Two-Photon Excitation Enhanced High-Efficiency and Phase-Conjugate Stimulated Mie Scattering of Perovskite Nanocrystals Suspended in n-Hexane. The Journal of Physical Chemistry C, 2020, 124, 25944−25950. (IF = 4.126)

[16] Keqiang Chen^#; Jing Zhou^#; Wen Chen; Peng Zhou; Fan He; Yueli Liu*, Size-dependent synthesis of Cu₁₂Sb₄S₁₃ nanocrystals with bandgap tunability. Particle & Particle Systems Characterization, 2015, 32 (11), 999-1005. (IF = 3.31)

授权专利：

[1]  Cu₂ZnSnS₄纳米晶材料的可控制备方法，ZL201610813712.4

[2]  尺寸可控的铜锑硫纳米晶材料及其制备方法，ZL201510204845.7

[3]  Cu₁₂Sb₄S₁₃纳米晶材料的可控制备方法，ZL201510899799.7

[4]  CuSbS₂纳米晶材料的可控制备方法，ZL201510898263.3

[5]  Cu₃SbS₄纳米晶材料的可控制备方法，ZL201510893678.1

[6]  小尺寸蓝光CsPbBr₃量子点的可控制备方法，ZL201810222012.7

[7]  水溶性铜锗硫量子点及其制备方法，ZL201510204176.3

[8]  一种石墨烯与二氧化钛复合材料及其低温制备和应用方法，ZL201210582211.1

[9]  一种圆锥形TiO₂纳米管阵列材料及其可控制备方法，ZL201210582446.0