中国地质大学(武汉)导师教师师资介绍简介-蔡卫卫

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基本信息Personal Information 副教授博士生导师硕士生导师
性别 : 男
出生年月 : 1985年01月12日
毕业院校 : 中国科学院大学
学历 : 博士研究生毕业
学位 : 理学博士学位
在职信息 : 在职
所在单位 : 材料与化学学院
入职时间 : 2014年10月31日
学科 : 应用化学
办公地点 : 未来城校区材化楼654办公室
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同专业博导同专业硕导
个人简介Personal Profile 教育科研背景
2013年毕业于中国科学院长春应用化学研究所获理学博士学位，在新加坡国立大学从事博士后研究工作后于2014年10月起就职于中国地质大学（武汉），任副教授。近年来以发表SCI论文100余篇。

研究兴趣
高效电化学催化剂设计；电化学催化机理探索；高分子固体电解质改性；燃料电池/水电解器件优化；新型电化学过程研究。

主持项目
? 国家自然科学基金，面上项目（2019/01-2022/12），65万元，主持。
? 国家自然科学基金，青年基金（2016/01-2018/12），21万元，主持。
? 浙江省自然科学基金，公益项目（2019/01-2021/12），10万元，主持。
? 中央高校基本科研业务费，“杰出人才培育基金”（2016/01-2020/12），30万元，主持。

代表性通讯作者论文
1. J. Li, W. Cai,* et. al., Hetero-structural Mass Transfer Channel Boosts Electrocatalytic Oxygen Reactions of Metallic Catalyst, Chem. Eng. J., 2021; In Press. (IF=10.652)
2. F. Luo, W. Cai,* et. al., Regulated Coordination Environment of Ni Single Atom Catalyst toward High-efficiency Oxygen Electrocatalysis for Rechargeable Zinc-air Batteries, Energy Storage Mater., 2021; 35:723-730. (IF=16.28)
3. Q. Zhang, W. Cai,* et. al., Nitrogen dopants in nickel nanoparticles embedded carbon nanotubes promote overall urea oxidation, Appl. Catal. B, 2021; 280:119436. (IF= 16.683)
4. Z. Liu, W. Cai,* et. al., Heterointerface-rich Mo₂C/MoO₂ porous nanorod enables superior alkaline hydrogen evolution, Chem. Eng. J., 2021; 421:127807. (IF=10.652)
5. Z. Liu, W. Cai,* et. al., Mater. Today Phys., Co nanocluster strain-engineered by atomic Ru for efficient and stable oxygen reduction catalysis, 2021; 421:127807. (IF=10.443)
6. F. Luo, W. Cai,* et. al., Robust and Stable Acidic Overall Water Splitting on Ir Single Atoms, Nano Lett., 2020; 20:2120. (IF= 11.238)
7. F. Luo, W. Cai,* et. al., Palladium phosphide as stable and efficient electrocatalyst for overall water splitting, Angew. Chem. Int. Ed., 2018; 57:14862. (IF= 12.959)
8. J. Xiong, W. Cai,* et. al., In-situ Engineering of Double Phase Interface in Mo/Mo₂C Heteronanosheets for Boosted Hydrogen Evolution Reaction, ACS Energy Lett., 2018; 3:341. (IF= 19.003)
9. J. Liang (本科生), W. Cai,* et. al., Boosting the acidic electrocatalytic nitrogen reduction performance of MoS₂ by strain engineering, J. Mater. Chem. A, 2020; 8:10426. (IF= 11.301)
10. Q. Zhang, W. Cai,* et. al., Identification of functionality of heteroatoms in boron, nitrogen and fluorine ternary-doped carbon as a robust electrocatalyst for nitrogen reduction reaction powered by rechargeable zinc–air batteries, J. Mater. Chem. A, 2020; 8:8430. (IF= 11.301)
11. F. Luo, W. Cai,* et. al., Robust hydrogen evolution reaction activity catalyzed by ultrasmall Rh–Rh2P nanoparticles, J. Mater. Chem. A, 2020; 8:12378. (IF= 11.301)
12. Y. Ling, W. Cai,* et. al., Strain induced rich planar defects in heterogeneous WS2/WO2 enable efficient nitrogen fixation at low overpotential, J. Mater. Chem. A, 2020; 8:12996. (IF= 11.301)
13. H. Hu, W. Cai,* et. al., Electronically delocalized Ir enables efficient and stable acidic water splitting, J. Mater. Chem. A, 2020; 8:20168. (IF= 11.301)
14. X. Wei, W. Cai,* et. al., Highly-defective Fe-N-C catalysts towards pH-Universal oxygen reduction reaction, Appl. Catal. B, 2020; 263:118347. (IF= 16.683)
15. J. Xiong, W. Cai,* et. al., Metallic 1T-MoS₂ nanosheets in-situ entrenched on N,P,S-codoped hierarchical carbon microflower as an efficient and robust electro-catalyst for hydrogen evolution, Appl. Catal. B, 2019; 243:614. (IF= 16.683)
16. J. Xiong, W. Cai,* et. al., Engineering highly active oxygen sites in perovskite oxides for stable and efficient oxygen evolution, Appl. Catal. B, 2019; 256:117817. (IF= 16.683)
17. F. Luo, W. Cai,* et. al., Engineering oxygen vacancies of cobalt tungstate nanoparticles enable efficient water splitting in alkaline medium, Appl. Catal. B, 2019; 259: 118090. (IF= 16.683)
18. S. Xing, W. Cai,* et. al., Rh nanoroses for isopropanol oxidation reaction, Appl. Catal. B, 2019; 259: 118082. (IF= 16.683)
19. Z. Liu, W. Cai,* et. al., Engineering of Ru/Ru₂P interfaces superior to Pt active sites for catalysis of the alkaline hydrogen evolution reaction, J. Mater. Chem. A, 2019; 7:5621. (IF= 11.301)
20. J. Xiong, W. Cai,* et. al., Salt-templated synthesis of defect-rich MoN nano-sheet for boosted hydrogen evolution reaction, J. Mater. Chem. A, 2017; 5:24193. (IF= 11.301)
21. Z. Liu, W. Cai,* et. al., Pt/Mo₂C heteronanosheets for superior hydrogen evolution reaction, J. Energy Chem., 2020; 47:317.
22. J. Xiong, W. Cai,* et. al., A novel thermomechanically stable LaF3CsH5(PO4)2 composite electrolyte with high proton conductivity at elevated temperatures over 150°C, J. Energy Chem., 2019; 30:114.
23. J. Shi, W. Cai,* et. al., Multi-stage porogen induced hetero-porous Co, N-doped carbon catalyst toward efficient oxygen reduction, Chem. Commun., 2021; 57:903.
24. J. Shi, W. Cai,* et. al., N-rich hetero-porous defective carbon induced by trace B-doping enables efficient oxygen reduction, Chem. Commun., 2020; 56:12214.
25. G. Xu, W. Cai,* et. al., Targeted filling silica in Nafion by a modified in-situ sol-gel method for boosted fuel cell performance at elevated temperature and low humidity, Chem. Commun., 2019; 55:5499.
26. L. Guo, W. Cai,* et. al., Robust hydrogen evolution reaction catalysis by ultrasmall amorphous ruthenium phosphide nanoparticles, Chem. Commun., 2019; 55:7623.
27. Q. Zhang, W. Cai,* et. al., A robust electrocatalytic activity toward the hydrogen evolution reaction from W/W2C heterostructured nanoparticles coated with a N,P dual-doped carbon layer, Chem. Commun., 2019; 55:9665.
28. J. Li, W. Cai,* et. al., Effect of nano-size of functionalized silica on overall performance of swelling-filling modified Nafion membrane for direct methanol fuel cell application, Appl. Energy, 2018; 213:408.
29. Y. Ling, W. Cai,* et. al., A self-template synthesis of defect-rich WS2 as a highly efficient electrocatalyst for the hydrogen evolution reaction, Chem. Commun., 2018; 54:2631.
30. Q. Zhang, W. Cai,* et. al., Chem. Commun., Carbon nitride simultaneously boosted a PtRu electrocatalyst's stability and electrocatalytic activity toward concentrated methanol, 2018; 54:9282.
31. Guoxiao Xu, Weiwei Cai,* et. al., J. Membr. Sci., Performance dependence of swelling-filling treated Nafion membrane on nano-structure of macromolecular filler, 2017; 534:68.
32. J. Li, W. Cai,* et. al., An in-situ nano-scale swelling-filling strategy to improve overall performance of Nafion membrane for direct methanol fuel cell application, J. Power Sources, 2016; 332:37.
33. L. Ma, W. Cai,* et. al., A high performance polyamide-based proton exchange membrane fabricated via construction of hierarchical proton conductive channels, J. Power Sources, 2016; 302:189.
34. J. Li, W. Cai,* et. al., Towards neat methanol operation of direct methanol fuel cells: a novel self-assembled proton exchange membrane, Chem. Commun., 2015; 51:6556.

招生倾向
1. 对物理化学、电化学催化及新能源方向有兴趣；
2. 具有无机合成或高分子合成经验。
欢迎感兴趣的同学咨询报考。

教育经历Education Background
工作经历Work Experience
2007.92013.1
中国科学院大学
物理化学
研究生(博士)毕业
理学博士学位
2002.92006.7
哈尔滨工业大学
化学工程与工艺
本科(学士)
工学学士学位
2014.10至今
中国地质大学（武汉）
材料与化学学院
副教授
2013.42014.10
新加坡国立大学
博士后研究员

研究方向Research Focus
社会兼职Social Affiliations
电化学催化材料及过程研究；
质子交换膜开发及改性研究；
燃料电池集成及优化研究；
电解水及其他电合成技术。

基本信息Personal Information 副教授博士生导师硕士生导师
性别 : 男
出生年月 : 1985年01月12日
毕业院校 : 中国科学院大学
学历 : 博士研究生毕业
学位 : 理学博士学位
在职信息 : 在职
所在单位 : 材料与化学学院
入职时间 : 2014年10月31日
学科 : 应用化学
办公地点 : 未来城校区材化楼654办公室
联系方式 : **
Email :

扫描关注

同专业博导同专业硕导

当前位置: 中文主页 >> 科学研究
研究领域
电化学催化过程研究及纳米催化剂设计；
质子交换膜功能化设计及改性；
燃料电池及电解水器件设计及优化。

科研项目
高温应用“储水囊”改性Nafion膜开发及匹配低铂甲醇氧化催化剂研制, 国家自然科学基金项目-2022/12/31
著作成果
专利
论文成果More>>
72.张晶, 冯立纲, 蔡卫卫, 刘长鹏, 邢巍, 甲醇浓度对被动式自呼吸直接甲醇燃料电池性能的影响, 中国科学: 化学, 2011;41:1864-1870.
71.Liang Ma, Weiwei Cai, Jing Zhang, Liang Liang, Jianhui Liao, Changpeng Liu, Wei Xing, Optimization of Membrane Electrode Assembly in Air-Breathing Direct Methanol Fuel Cell, 电化学, 2010;16:131-136.
70.Ligang Feng, Fengzhan Si, Shikui Yao, Weiwei Cai, Wei Xing, Changpeng Liu, Effect of deposition sequences on electrocatalytic properties of PtPd/C catalysts for formic acid electrooxidation, Catalysis Communications, 2011;12:772-775.
69.Jing Zhang, Ligang Feng, WeiWei Cai, Changpeng Liu, Wei Xing, The function of hydrophobic cathodic backing layers for high energy passive direct methanol fuel cell, Journal of Power Sources, 2011;196:9510-9515.
68.Ligang Feng, Jing Zhang, Weiwei Cai, Liang Liang, Wei Xing, Changpeng Liu, Single passive direct methanol fuel cell supplied with pure methanol, Journal of Power Sources, 2011;196:2750-2753.
67.Xiao Zhao, Jianbin Zhu, Weiwei Cai, Meilin Xiao, Liang Liang, Changpeng Liu, Wei Xing, Pt-Pb hollow sphere networks: self-sacrifice-templating method and enhanced activity for formic acid electrooxidation, RSC Advances, 2013;3:1763-1767.

基本信息Personal Information 副教授博士生导师硕士生导师
性别 : 男
出生年月 : 1985年01月12日
毕业院校 : 中国科学院大学
学历 : 博士研究生毕业
学位 : 理学博士学位
在职信息 : 在职
所在单位 : 材料与化学学院
入职时间 : 2014年10月31日
学科 : 应用化学
办公地点 : 未来城校区材化楼654办公室
联系方式 : **
Email :

扫描关注

同专业博导同专业硕导

论文成果当前位置: 中文主页 >> 科学研究 >> 论文成果
[1]72.张晶, 冯立纲, 蔡卫卫, 刘长鹏, 邢巍, 甲醇浓度对被动式自呼吸直接甲醇燃料电池性能的影响, 中国科学: 化学, 2011;41:1864-1870.
[2]71.Liang Ma, Weiwei Cai, Jing Zhang, Liang Liang, Jianhui Liao, Changpeng Liu, Wei Xing, Optimization of Membrane Electrode Assembly in Air-Breathing Direct Methanol Fuel Cell, 电化学, 2010;16:131-136.
[3]70.Ligang Feng, Fengzhan Si, Shikui Yao, Weiwei Cai, Wei Xing, Changpeng Liu, Effect of deposition sequences on electrocatalytic properties of PtPd/C catalysts for formic acid electrooxidation, Catalysis Communications, 2011;12:772-775.
[4]69.Jing Zhang, Ligang Feng, WeiWei Cai, Changpeng Liu, Wei Xing, The function of hydrophobic cathodic backing layers for high energy passive direct methanol fuel cell, Journal of Power Sources, 2011;196:9510-9515.
[5]68.Ligang Feng, Jing Zhang, Weiwei Cai, Liang Liang, Wei Xing, Changpeng Liu, Single passive direct methanol fuel cell supplied with pure methanol, Journal of Power Sources, 2011;196:2750-2753.
[6]67.Xiao Zhao, Jianbin Zhu, Weiwei Cai, Meilin Xiao, Liang Liang, Changpeng Liu, Wei Xing, Pt-Pb hollow sphere networks: self-sacrifice-templating method and enhanced activity for formic acid electrooxidation, RSC Advances, 2013;3:1763-1767.
[7]66.Yunfeng Zhang, Joycelyn Woo Yun Ting, Weiwei Cai, Jing Li, Guodong Xu, Rupesh Rohan, An Lin and Hansong Cheng, Fabrication of A Proton Exchange Membrane via Blended Sulfonimide Functionalized Polyamide, Journal of Materials Sciences, 2014;49:3442-3450.
[8]65.Rupesh Rohan, Yubao Sun, Weiwei Cai, Kapil Pareek, Yunfeng Zhang, Guodong Xu, Hansong Cheng, Functionalized Meso/Macro-Porous Single Ion Polymeric Electrolyte for Applications in Lithium Ion Batteries, Journal of Materials Chemistry A, 2014;2: 2960-2967.
[9]64.Yunfeng Zhang, Yubao Sun, Guodong Xu, Weiwei Cai, Rupesh Rohan, An Lin, Hansong Cheng, Lithium-ion batteries with a wide temperature range operability enabled by highly conductive sp3 boron-based single ion polymer electrolytes, Energy Technology, 2014;2:643-650.
[10]63.Yunfeng Zhang, Rupesh Rohan, Weiwei Cai, Guodong Xu, An Lin, Yubao Sun, Hansong Cheng, A gel single ion polymer electrolyte membrane for lithium-ion batteries with wide-temperature range operability, RSC Advances, 2014;4: 21163-21170.
[11]62.Guodong Xu, Yubao Sun, Yunfeng Zhang, Rupesh Rohan, Weiwei Cai, Hansong Cheng, A lithium poly(pyromellitic acid borate) gel electrolyte membrane for lithium ion batteries, Journal of Materials Sciences, 2014; 49: 6111-6117.
[12]61.Guodong Xu, Yunfeng Zhang, Rupesh Rohan, Weiwei Cai, Hansong Cheng, Synthesis, Characterization and Battery Performance of A Lithium Poly (4-vinylphenol) Phenolate Borate Composite Membrane, Electrochimica Acta, 2014;139:264-269.
[13]60.Yubao Sun, Rupesh Rohan, Weiwei Cai, Xifei Wan, Kapil Pareek, An Lin, Yunfeng Zhang, Hansong Cheng, A Polyamide Single-Ion Electrolyte Membrane for Application in Lithium-Ion Batteries, Energy Technology, 2014;2:698-704.
[14]59.Yunfeng Zhang, Rupesh Rohan, Weiwei Cai, Guodong Xu, Yubao Sun, An Lin, Hansong Cheng, Influence of chemical microstructure of single ion polymeric electrolyte membranes on performance of lithium ion batteries, ACS Applied Materials & Interfaces, 2014;6:17534-17542.
[15]58.Yunfeng Zhang, Corina Anrou Lim, Weiwei Cai, Rupesh Rohan, Guodong Xu, Yubao Sun, Hansong Cheng, Design and synthesis of a single ion conducting block copolymer electrolyte with multifunctionality for lithium ion batteries, RSC Advances, 2014; 4:43857-43864.
[16]57.Rupesh Rohan, Yubao Sun, Weiwei Cai, Yunfeng Zhang, Kapil Pareek, Guodong Xu, Hansong Cheng, Functionalized polystyrene based single ion conducting gel polymer electrolyte for lithium batteries, Solid State Ionics, 2014;268: 294–299.
[17]56.Rupesh Rohan, Kapil Pareek, Weiwei Cai, Yunfeng Zhang, Guodong Xu, Zhongxin Chen, Zhiqiang Gao, Dan Zhao, Hansong Cheng, Melamine-Terephthalaldehyde-Lithium Complex: A Porous Organic Network Based Single Ion Electrolyte for Lithium Ion Batteries, Journal of Materials Chemistry A, 2015;3:5132-5139.
[18]55.Rupesh Rohan, Kapil Pareek, Zhongxin Chen, Weiwei Cai, Yunfeng Zhang, Guodong Xu, Zhiqiang Gao and Hansong Cheng, A high performance polysiloxane-based single ion conducting polymeric electrolyte membrane for application in lithium ion batteries, Journal of Materials Chemistry A, 2015,3:20267-20276.
[19]54.Liying Ma, Jing Li, Weiwei Cai, Kun Fan, Yao Jiang, Hansong Cheng, A facile method to construct highly efficient methanol resistive polyamide-based proton exchange membrane, International Journal of Hydrogen Energy, 2016, 41:16205-16211.
[20]53.Yunfeng Zhang, Cuicui Li, Xupo Liu, Zehui Yang, Jiaming Dong, Yuan Liu, Weiwei Cai, and Hansong Cheng, Fabrication of a polymer electrolyte membrane with uneven side chains for enhancing proton conductivity, RSC Advances, 2016;6:79593-79601.
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