郭浩然

职称：讲师

性别：男

职务：专任教师

办公电话：隐藏

移动电话：隐藏

家庭电话：隐藏

家庭住址：隐藏

电子邮箱：GuoHRan@163.com

工作学习经历

主讲课程

研究方向 

电催化理论计算

主要学术成果 

一作及通讯成果：

[1] H. Guo, P. Yuan, J. Zhao, J. Zhao, Q. Peng, R. Song*, First-principles studies of monolayers MoSi₂N₄ decorated with transition metal single-atom for visible light-driven high-efficient CO₂ reduction by strain and electronic engineering, Chemical Engineering Journal, (2022), 450, 138198.

[2] H. Guo, L. Li, X. Wang, G. Yao, H. Yu, Z. Tian*, B. Li*, L. Chen*, Theoretical Investigation on the Single Transition-Metal Atom-Decorated Defective MoS₂ for Electrocatalytic Ammonia Synthesis, ACS Applied Materials & Interfaces, (2019), 11, 36506-36514.

[3] H. Guo, H. Zhang, J. Zhao, P. Yuan, Y. Li, Y. Zhang, L. Li, S. Wang, R. Song*, Two-Dimensional WO₃-Transition-Metal Dichalcogenide Vertical Heterostructures for Nitrogen Fixation: A Photo(Electro) Catalysis Theoretical Strategy, Journal of Physical Chemistry C, (2022), 126, 3043-3053. 

[4] H. Guo, P. Yuan, M. Xu, Y. Zhang, R. Song*, Toward Rational Design of the Two-Dimensional h-WO₃/ZrGe₂P₄ Heterostructure for N₂/CO₂ Reduction: Incorporating Multiple Electronic Modulation Engineering, Journal of Physical Chemistry C, (2023), 127(30), 14784-14796

[5] B. Li*, H. Guo, Y. Wang, W. Zhang, Q. Zhang, L. Chen, X. Fan, W. Zhang, Y. Li, W.-M. Lau*, Asymmetric MXene/monolayer Transition Metal Dichalcogenide Heterostructures for Functional Applications, npj Computational Materials, (2019), 5, 16. 

[6] H. Du†, H. Guo†, K. Wang, X. Du, B.A. Beshiwork, S. Sun, Y. Luo, Q. Liu, T. Li*, X. Sun*, Durable Electrocatalytic Reduction of Nitrate to Ammonia over Defective Pseudobrookite Fe₂TiO₅ Nanofibers with Abundant Oxygen Vacancies, Angewandte Chemie International Edition, (2023), e202215782. 

[7] H. Zhang†, H. Guo†, Y. Li, Q. Zhang, L. Zheng, L. Gu, R. Song*, The Guest Doping Effects of Fe on Bimetallic NiCo Layered Double Hydroxide for Enhanced Electrochemical Oxygen Evolution Reaction: Theoretical Screening and Experimental Verification, Advanced Functional Materials, (2023). 2304403.

[8] L. Li†, H. Guo†, G. Yao, C. Hu, C. Liu, Z. Tian*, B. Li*, Q. Zhang, L. Chen*, Visible/infrared light-driven high-efficiency CO₂ conversion into ethane based on a B–Co synergistic catalyst, Journal of Materials Chemistry A, (2020), 8, 22327-22334.

[9] H. Xian†, H. Guo†, J. Xia†, Q. Chen, Y. Luo, R. Song, T. Li*, E. Traversa, Iron-Doped MoO₃ Nanosheets for Boosting Nitrogen Fixation to Ammonia at Ambient Conditions, ACS Applied Materials & Interfaces, (2021), 13, 7142-7151.

[10] R. Zhang†, H. Guo†, L. Yang, Y. Wang, Z. Niu, H. Huang, H. Chen, L. Xia, T. Li, X. Shi, X. Sun*, B. Li, Q. Liu, Electrocatalytic N₂ Fixation over Hollow VO₂ Microspheres at Ambient Conditions, ChemElectroChem, (2019), 6, 1014-1018.

[11] X. He†, H. Guo†, X. Zhang, T. Liao, Y. Zhu, H. Tang*, T. Li*, J.S. Chen*, Facile electrochemical fabrication of magnetic Fe₃O₄ for electrocatalytic synthesis of ammonia used for hydrogen storage application, International Journal of Hydrogen Energy, (2021), 46, 24128-24134.

[12] S. Dong, A. Niu, K. Wang, P. Hu, H. Guo*, S. Sun, Y. Luo, Q. Liu, X. Sun*, T. Li*, Modulation of oxygen vacancy and zero-valent zinc in ZnCr₂O₄ nanofibers by enriching zinc for efficient nitrate reduction, Applied Catalysis B: Environmental, (2023), 333, 122772.

[13] Y. Zhang*, H. Guo*, M. Song, L. Sun, R. Song*, Modulation of the morphology and electronic structure of Ni₃S₂ nano-forests via P and Mo co-doping in polyoxometalates to promote the urea oxidation reaction, Journal of Materials Chemistry A, (2023), 11, 3584-3593. 

[14] B. Admasu Beshiwork, X. Wan, M. Xu, H. Guo*, B. Sirak Teketel, Y. Chen, J. Song Chen, T. Li*, E. Traversa, A defective iron-based perovskite cathode for high-performance IT-SOFCs: Tailoring the oxygen vacancies using Nb/Ta co-doping, Journal of Energy Chemistry, (2024), 88, 306-316. 

[15] T. Li*, J. Xia, Q. Chen, K. Xu, Y. Gu, Q. Liu, Y. Luo, H. Guo*, E. Traversa, Monodisperse Cu Cluster-Loaded Defective ZrO₂ Nanofibers for Ambient N₂ Fixation to NH₃, ACS Applied Materials & Interfaces, (2021), 13, 40724-40730. 

[16] T Z. Zhang, T. Wang, J. Song Chen, K. Dong, S. Sun, Y. Luo, H. Guo*, X. Sun, T. Li*, Cr₃C₂ nanoparticles decorated carbon nanofibers for efficient nitrate reduction to ammonia at ambient conditions, Journal of Colloid and Interface Science, (2023), 648, 693-700.

[17] Y. Zhang*, H. Guo*, M. Song, Z. Qiu, S. Wang, L. Sun, Hierarchical interfaces engineering-driven of the CoS₂/MoS₂/Ni₃S₂/NF electrode for high-efficient and stable oxygen evolution and urea oxidation reactions, Applied Surface Science, (2023), 617, 156621.

[18] P. Hu, S. Hu, H. Du, Q. Liu, H. Guo*, K. Ma, T. Li*, Efficient electrocatalytic reduction of nitrate to ammonia over fibrous SmCoO₃ at ambient conditions, Chemical Communications, (2023). 59(38), 5697-5700.

[19] Q. Chen, J. Liang, L. Yue, Y. Luo, Q. Liu, N. Li, A.A. Alshehri, T. Li*, H. Guo*, X. Sun, CoO nanoparticle decorated N-doped carbon nanotubes: a high-efficiency catalyst for nitrate reduction to ammonia, Chemical Communications, (2022), 58, 5901-5904.

[20] J. Xia, H. Du, S. Dong, Y. Luo, Q. Liu, J.S. Chen, H. Guo*, T. Li*, Heterogenous Cu@ZrO₂ nanofibers enable efficient electrocatalytic nitrate reduction to ammonia under ambient conditions, Chemical Communications, (2022), 58, 13811-13814.

[21] T. Li*, J. Xia, H. Xian, Q. Chen, K. Xu, Y. Gu, Y. Luo, Q. Liu, H. Guo*, E. Traversa, Fe(III) grafted MoO₃ nanorods for effective electrocatalytic fixation of atmospheric N₂ to NH₃, International Journal of Hydrogen Energy, (2022), 47, 3550-3555.

[22] X. Du, K. Wang, T. Wang, H. Guo*, J.S. Chen, J. Wang, T. Li*, Constructing n-type TiO₂ by Nb doping for electrocatalytic nitrate reduction to ammonia at ambient conditions, International Journal of Hydrogen Energy, (2023), 48(95), 37077-37085.

[23] S. Dong, J. Xia, H. Zhu, X. Du, Y. Gu, Q. Liu, Y. Luo, Q. Kong, H. Guo*, T. Li*, E. Traversa, ZrO₂/C Nanosphere Enables High-Efficiency Nitrogen Reduction to Ammonia at Ambient Conditions, ChemCatChem, (2022), 14, e202200458.

[24] H. Zhu, S. Dong, X. Du, H. Du, J. Xia, Q. Liu, Y. Luo, H. Guo*, T. Li*, Defective CuO-rich CuFe₂O₄ nanofibers enable the efficient synergistic electrochemical reduction of nitrate to ammonia, Catalysis Science & Technology, (2022), 12, 4998-5002.

[25] T. Li*, Q. Chen, J. Yu, J. Xia, Y. Li, K. Xu, Y. Luo, Q. Liu, H. Guo*, YF₃: a nanoflower-like catalyst for efficient nitrogen fixation to ammonia under ambient conditions, Catalysis Science & Technology, (2021), 11, 6750-6754.

[26] Y. Gu, Q. Chen, X. Ju, Z. Zhang, P. Hu, H. Guo*, T. Li*, CoO (111) nanowire arrays for High-efficiency electrochemical nitrate reduction to ammonia, Materials Letters, (2023), 341, 134252. 

个人简介

郭浩然，男，博士，河北邢台人。2011年本科就读于西南科技大学，师从徐光亮教授；2016年硕士就读于电子科技大学，师从李白海副教授；2018年进入中国科学院宁波材料所联合培养，师从田子奇研究员与陈亮研究员；2019年博士就读于中国科学院大学，师从宋锐教授。于2023年6月获得博士学位，2023年9月加入湘潭大学化学学院裴勇教授团队工作，主要从事应用于OER，HER，NRR，NO₃RR，CO₂RR，UOR等光/电催化剂的开发，运用理论计算研究催化机理，并通过材料性质解析电化学现象本质。欢迎有志学子报考！

个人学术主页：

ResearchGate：https://www.researchgate.net/profile/Haoran-Guo-12

Google学术：https://scholar.google.com/citations?user=zqr6cEwAAAAJ&hl=zh-CN&oi=ao