个人简历

开设课程：
材料热力学与动力学
个人简介：
2007年毕业于西北工业大学，获博士学位；2007年11月进入南京大学物理学院凝聚态物理博士后流动站做博士后， 在南京大学环境材料与再生能源研究中心从事光催化材料研究；2010年11月就职于南京大学现代工程与应用科学学院；2011年12月晋升为副教授；2018年晋升为教授。
主要从事基于太阳能的能量转换与环境应用研究。课题组现已在Angew. Chem. Int. Ed., J. Am. Chem. Soc., Adv. Funct. Mater., Energy Environ. Sci. 等国际学术期刊上发表研究论文100余篇。论文他引5000余次，8篇论文他引超过100次，单篇论文引用达1000余次。获得2012和2016年度江苏省科学技术一等奖以及2014年度国家自然科学技术二等奖。承担国家973项目和自然科学基金等多项科研项目。承担研究生核心课程《材料热力学与动力学》、本科生通识课《新能源科学与技术》教学任务。已经毕业博士生6名，均在高校就职；毕业硕士生10名，就业于华为、中兴、TP-LINK、岛津等企业。

研究领域

""（1）光/电化学界面物理化学；（2）光/电化学反应的热力学与动力学；（3）光/电材料基本物性及新材料开发与制备""""

近期论文

[1] Y. Li, G. Xu, X. Zhu, Z. Man, X. Fu, Z. Hao, Y. Cui, C. Yuan, W. Zhang, S. Yan, H. Ge, Y. Chen, Z. Zou, A hierarchical dual-phase photoetching template route to assembling functional layers on Si photoanode with tunable nanostructures for efficient water splitting, Applied Catalysis B: Environmental 259 (2019) 118115
[2] L. Lu, Z. Xin, X. Wang, S. Wang, H. Zhu, T. Li, Y. Gu, S. Yan, Z. Zou, KOH-modified Ni/LaTiO2N Schottky junction efficiently reducing CO2 to CH4 under visible light irradiation, Appl. Catal. B-Environ., 244 (2019) 786-794.
[3]S. Wang, Z. Li, Y. Guan, L. Lu, Z. Shi, P. Weng, S. Yan, Z. Zou, Visible light driven TaON/V2O5 heterojunction photocatalyst for deep elimination of volatile-aromatic compounds, Appl. Catal. B-Environ., 245 (2019) 220-226.
[4] M. Zhao, Y. Gu, P. Chen, Z. Xin, H. Zhu, B. Wang, K. Zhu, S. Yan, Z. Zou, Highly selective electrochemical CO2 reduction to CO using a redox-active couple on low-crystallinity mesoporous ZnGa2O4 catalyst, Journal of Materials Chemistry A, 7 (2019) 9316-9323.
[5]L. Pei, T. Li, Y. Yuan, T. Yang, J. Zhong, Z. Ji, S. Yan, Z. Zou, Schottky junction effect enhanced plasmonic photocatalysis by TaON@Ni NP heterostructures, Chemical Communications, 55 (2019) 11754-11757.
[6] Z. Shi, D. Wu, H. Huang, T. Li, Z. Xu, J. Feng, S. Yan, Z. Zou, One-step synthesis of single crystalline wedge-shaped Ta3N5 nanoflakes with ultrathin top ends, CrystEngComm, 21 (2019) 2980-2984.
[7] B. Wang, J. Iocozzia, M. Zhang, M. Ye, S. Yan, H. Jin, S. Wang, Z. Zou, Z. Lin, The charge carrier dynamics, efficiency and stability of two-dimensional material-based perovskite solar cells, Chemical Society Reviews, 48 (2019) 4854-4891.
[8] H. Wang, Z. Shi, S. Yan, Z. Zou, Enhanced charge separation by oriented growth of Ta3N5-Cu2O n-p array heterojunction, Applied Physics Letters, 114, 132105 (2019).
[9] L. Pei, Y. Yuan, J. Zhong, T. Li, T. Yang, S. Yan, Z. Ji, Z. Zou, Ta3N5 nanorods encapsulated into 3D hydrangea-like MoS2 for enhanced photocatalytic hydrogen evolution under visible light irradiation, Dalton Transactions, 48 (2019) 13176-13183.
[10] Z. Xin, L. Lu, B. Wang, X. Wang, K. Zhu, Z. Xu, Z. Yu, S. Yan, Z. Zou, Lewis acid activated CO2 reduction over a Ni modified Ni-Ge hydroxide driven by visible-infrared light, Dalton Transactions, 48 (2019) 1672-1679.
[11] Y. Yan, S. Yan, Z. Yu, Z. Zou, Low-Work-Function Silver Activating N-doped Graphene as Efficient Oxygen Reduction Catalysts in Acidic Medium, ChemCatChem, 11 (2019) 1033-1038.
[12] T. Yang, L. Pei, S. Yan, Z. Yu, T. Yu, Z. Zou, In situ formed oxy/hydroxide antennas accelerating the water dissociation kinetics on a Co@N-doped carbon core-shell assembly for hydrogen production in alkaline solution, Dalton Transactions, 48 (2019) 11927-11933.
[13] H. Gao, Y. Guo, Z. Yu, M. Zhao, Y. Hou, Z. Zhu, S. Yan, Q. Liu, Z. Zou, Incorporating p-Phenylene as an Electron-Donating Group into Graphitic Carbon Nitride for Efficient Charge Separation, ChemSusChem, 12 (2019) 4285-4292.
[14]Tong Jiang, Yang Li, Shicheng Yan, Zhigang Zou. Silicon photoanodes partially covered by Ni@Fe core-shell particles with in situ formed gradient-enhanced junction electric field for photoelectrochemical water oxidation. Appl. Phys. Lett. 115, 213904 (2019).
[15] S. C. Yan, S. X. Ouyang, J. Gao, M. Yang, J. Y. Feng, X. X. Fan, L. J. Wan, Z. S. Li, J. H. Ye, Y. Zhou, Z. G. Zou. A Room-Temperature Reactive Template Route to Mesoporous ZnGa2O4 with Improved Photocatalytic Activity in Reduction of CO2. Angewandte Chemie International Edition . 2010, 49, 6400-6404.
[16] Y. F. Yao, Z. Xu, F. Cheng, W. C. Li, G. Z. Xu, S. Xu, P. Wang, G. D. Sheng, Y. D. Yan, Z. T. Yu, S. C. Yan,* Z. X. Chen, Z. G. Zou. Unlocking the Potential of Graphene for Water Oxidation Using an Orbital Hybridization Strategy. Energy & Environmental Science 2018, 11, 407-416.
[17] C. G. Zhou, S. M. Wang, Z. Y. Zhao, Z. Shi, S. C. Yan,* Z. G. Zou. A Facet-Dependent Schottky-Junction Electron Shuttle in a BiVO4{010}–Au–Cu2O Z-Scheme Photocatalyst for Efficient Charge Separation. Advanced Functional Materials 2018, DOI: 10.1002/adfm.201801214.
[18] L. Lu, B. Wang, S. M. Wang, Z. Shi, S. C. Yan*, Z. G. Zou. La2O3-Modified LaTiO2N Photocatalyst with Spatially Separated Active Sites Achieving Enhanced CO2 Reduction. Advanced Functional Materials 2017, 27, 1702447.
[19] S. C. Yan,* J. J. Wang, H. L. Gao, H. Yu, N. Y. Wang, Z. S. Li, Y. Zhou, Z. G. Zou. An Ion-Exchange Phase Transformation to ZnGa2O4 Nanocube towards Efficient sSolar Fuel Synthesis. Advanced Functional Materials 2013, 23, 758-763.
[20] S. C. Yan,* J. J. Wang, H. L. Gao, N. Y. Wang, H. Yu, Z. S. Li, Y. Zhou, Z. G. Zou. Zinc Gallogermanate Solid Solution: A Novel Photocatalyst for Efficiently Converting CO2 into Solar Fuels. Advanced Functional Materials 2013, 23, 1839-1845.
[21] B. Wang, X. Wang, L. Lu, C. G. Zhou, Z. Y. Xin, J. J. Wang, X. K. Ke, G. D. Sheng, S. C. Yan,* Z. G. Zou. Oxygen-Vacancy-Activated CO2 Splitting over Amorphous Oxide Semiconductor Photocatalyst, ACS Catalysis 2018, 8, 516−525.
[22] Z. Shi, J. Y. Feng, H. Shan, X. Wang, Z. Xu, H. T. Huang, Q. F. Qian, S. C. Yan,* Z. G. Zou. Low Onset Potential on Single Crystal Ta3N5 Polyhedron Array Photoanode with Preferential Exposure of {001} Facets. Applied Catalysis B: Environmental 2018, 237, 665–672.
[23] C. G. Zhou, J. K. Zhou, L. Lu, J. J. Wang, Z. Shi, B. Wang, L. Pei, S. C. Yan,* Z. T. Yu, Z. G. Zou. Surface Electric Field Driven Directional Charge Separation on Ta3N5 Cuboids Enhancing Photocatalytic Solar Energy Conversion. Applied Catalysis B: Environmental 2018, 237, 742–752.
[24] H. Zhu, M. M. Zhao, J. K. Zhou, W. C. Li, H. Y. Wang, Z. Xu, L. Lu, L. Pei, Z. Shi, S. C. Yan, Z. S. Li, Z. G. Zou. Surface States as Electron Transfer Pathway Enhanced Charge Separation in TiO2 Nanotube Water Splitting Photoanodes. Applied Catalysis B: Environmental 2018, 234, 100-108.
[25] S. M. Wang, Y. Guan, L. Lu, Z. Shi, S. C. Yan,* Z. G. Zou. Effective Separation and Transfer of Carriers into the Redox Sites on Ta3N5/Bi Photocatalyst for Promoting Conversion of CO2 into CH4. Applied Catalysis B: Environmental 2018, 224, 10-16.
[26] H. L. Gao, S. C. Yan,* J. J. Wang, Z. G. Zou. Inorganic Ions Promoted Photocatalysis based on Polymer Photocatalyst. Applied Catalysis B: Environmental 2014, 158, 321-328.