姓名:王智力(纳米多孔金属和微纳结构材料的精准合成与催化性能研究)
性别:男
职称:教授
所在系别:金属材料工程
是否博导:是
最高学历:研究生
最高学位:博士
办公地点:吉林大学南岭校区,机械材料馆610
电话:13351504759
Email:zhiliwang@jlu.edu.cn
所在学科专业: 金属材料工程
研究方向:金属功能材料;燃料电池催化材料;
讲授课程:金属材料学
教育经历:2005.09-2009.06 吉林大学 高分子材料与工程 学士
2009.09-2014.06 吉林大学 材料学 博士
工作经历:2014.10-2018.03 日本国立东北大学原子分子材料科学高等研究机构 研究助手
2019.01-至今 吉林大学材料科学与工程学院 学术带头人,教授
科研项目:1. 国家自然科学基金青年基金(2020.01-2023.12),24万,负责人
学术论文:
主要从事微纳结构材料的基础科学与应用研究,包括三维纳米多孔材料和纳米复合材料的精准合成与催化性能的研究;电催化氮气还原合成氨;燃料电池催化材料;催化、电催化储氢/制氢。主持和参与多项国家自然科学基金、日本东北大学科研基金项目。到目前为止,以第一作者或通讯作者在Nature Communications, Advanced Materials, Angew. Chem. Int. Ed., Advanced Energy Materials等高水平国际学术期刊上发表SCI论文30余篇,被SCI期刊他引1500余次。
[1] Zhili Wang, Pan Liu, Jiuhui Han, Chun Cheng, Shoucong Ning, Akihiko Hirata, Takeshi Fujita, and Mingwei Chen, Engineering the internal surfaces of three-dimensional nanoporous catalysts by surfactant modified dealloying, Nature Communications, 2017, 8, 1066
[2] Zhili Wang, Shoucong Ning, Pan Liu, Yi Ding, Akihiko Hirata, Takeshi Fujita, and Mingwei Chen, Tuning Surface Structure of 3D Nanoporous Gold by Surfactant-Free Electrochemical Potential Cycling, Advanced Materials 2017, 1703601.
[3] Zhili Wang, Junmin Yan, Yun Ping, Hongli Wang, Weitao Zheng, and Qing Jiang, An efficient CoAuPd/C catalyst for hydrogen generation from formic acid at room temperature, Angewandte Chemie International Edition, 2013, 52, 4406
[4] Zhili Wang, Jing Du, Yongzheng Zhang, Jiuhui Han, Shouqiang Huang, Akihiko Hitata, and Mingwei Chen, Free-standing nanoporous gold for direct plasmon enhanced electro-oxidation of alcohol, Nano Energy, 2019, 56, 286
[5] Hongli Wang, Yue Chi, Dawei Gao, Zhili Wang*, Cong Wang, Liying Wang, Minggang Wang, Daowen Cheng, Jingjing Zhang, Chen Wu, Zhankui Zhao*, Enhancing formic acid dehydrogenation for hydrogen production with the metal/organic interface, Applied Catalysis B: Environmental, 2019,255, 117776.
[6] Junmin Yan, Zhili Wang, Lin Gu, Sijia Li, Hongli Wang, Weitao Zheng, and Qing Jiang, AuPd-MnOx/MOF-Graphene: An Efficient Catalyst for Hydrogen Production from Formic Acid at Room Temperature, Advanced Energy Materals 2015, 5, 1500107
[7] Zhili Wang, Junmin Yan, Hongli Wang, Yun Ping, and Qing Jiang, Au@Pd core-shell nanoclusters growing on nitrogen-doped mildly reduced graphene oxide with enhanced catalytic performance for hydrogen generation from formic acid, Journal of Materials Chemistry A, 2013, 1, 12721.
[8] Zhili Wang, Junmin Yan, Yuefei Zhang, Yun Ping, Hongli Wang and Qing Jiang, Facile synthesis of nitrogen-doped graphene supported AuPd-CeO2 nanocomposites with high-performance for hydrogen generation from formic acid at room temperature, Nanoscale, 2014, 6, 3073.
[9] Zhili Wang, Hongli Wang, Junmin Yan, Yun Ping, Songll O, Sijia Li and Qing Jiang, DNA-directed growth of ultrafine CoAuPd nanoparticles on graphene as efficient catalysts for formic acid dehydrogenation, Chemical Communications, 2014,50,2732.
[10] Zhili Wang, Junmin Yan, Hongli Wang, Yun Ping, and Qing Jiang, Pd/C Synthesized with Citric Acid: An Efficient Catalyst for Hydrogen Generation from Formic Acid/Sodium Formate, Scientific Reports, 2012, 598.
[11] Junmin Yan, Zhili Wang, Hongli Wang, and Qing Jiang, Rapid and energy-efficient synthesis of a grapheme-CuCo hybrid as a high performance catalyst, Journal of Materials Chemistry, 2012, 22, 10990.
[12] Zhili Wang, Junmin Yan, Hongli Wang, Qing Jiang, Self-protective cobalt nanocatalyst for long-time recycle application on hydrogen generation by its free metal-ion conversion, Journal of Power Sources, 243, 431.
[13] Zhili Wang, Yun Ping, Junmin Yan, Hongli Wang, and Qing Jiang, Hydrogen generation from formic acid decomposition at room temperature using a NiAuPd alloy nanocatalyst, International Journal of Hydrogen Energy, 2012, 39, 4850.
