姓     名: 王元庆
出生年月: 1984
职     称: 讲师
个人主页: https://www.x-mol.com/groups/wang_yuanqing
邮     箱: yuanqingwang@shu.edu.cn
个人简况

工作经历                                                            

2020/10 – 至今 讲师,上海大学材料基因组工程研究院

2016/06 – 2020/09 博士后研究员,德国马普学会Fritz-Haber-Institute, 合作导师:Dr. Annette Trunschke, Prof. Robert Schlögl

2015/04 – 2016/03 博士后研究员,日本理化学研究所 Biofunctional Catalyst Research Team,合作导师: Prof. Ryuhei Nakamura

2013/05 – 2015/03 Research Associate,日本理化学研究所 RIKEN Innovation Center,合作导师: Dr. Shinichiro Nakamura


教育背景                                                                  

2009/03 – 2013/05 工学博士,环境工程,同济大学,导师:金放鸣教授

2005/09 – 2008/03 工学硕士, 环境科学, 东华大学,导师:周美华教授

2001/09 – 2005/07 理学学士, 环境科学, 青岛大学


主要奖励 & 荣誉

2015-2016  获得日本理化学研究所科研奖励基金. 主持项目名称:“Turning Frustration into Electrochemical CO2 Activation”. 项目经费:2百万日元

研究方向

1. 电催化材料(OER和CO2还原)的开发与表征

2. 原位拉曼光谱在多相催化中的应用

3. 多通道催化反应器的开发与应用

代表性成果

王元庆长期从事能源与环境催化领域的研究,研究方向主要集中于生物质的高效资源化和水热反应的开发,二氧化碳的电化学还原,以及催化相关的理论计算和振动光谱的基础研究。王元庆利用理论计算在全世界首次提出离子液体电催化还原二氧化碳的分子机制;利用拉曼光谱解析了金属氧化物催化剂上分子氧的活化过程以及对烷烃选择氧化的影响;作为主持人主持了日本理化学研究所的一项科研奖励基金项目;在化学、化工、能源和催化等领域SCI学术期刊上(如Angewandte Chemie,Chemical Communications,AIChE Journal,Applied Energy,ACS Catalysis, Applied Catalysis B:Environmental)共发表了25篇学术论文,其中第一作者/通讯作者SCI论文达到9篇;SCI论文已被引用超过300次;获邀在Springer和CRC等出版社发表英文著作章节3篇(一作)。


1) Wang, Y.*, Hayashi, T., He, D., Li, Y., Jin, F., Nakamura, R.* A reduced imidazolium cation layer serves as the active site for electrochemical carbon dioxide reduction. Applied Catalysis B: Environmental 2020, 264, 118495. (共同通讯作者兼一作)

2) Wang, Y., Wang, F., Li, C., Jin F. Kinetics and mechanism of reduction of CO2 by glycerol under alkaline hydrothermal conditions. International Journal of Hydrogen Energy 2016, 41(21), 9128-9134.

3) Duo, J., Jin, F.*, Wang, Y.*, Zhong, H., Yao, G., Lyu, L., Huo, Z. NaHCO3-enhanced Fe oxidation and in-situ efficient NaHCO3 reduction into formic acid. Chemical Communications 2016, 52, 3316-3319. (共同通讯作者)

4) Wang, Y., Hatakeyama, M., Ogata, K., Nakamura, S., Jin, F. Activation of CO2 by ionic liquid EMIM-BF4 in the electrochemical system, a theoretical study. Physical Chemistry Chemical Physics 2015, 17 (36), 23521-23531.

5) Wang, F.#, Wang, Y.#, Jin, F., Yao, G., Huo, Z., Zeng, X., Jing, Z. One-pot hydrothermal conversion of cellulose into organic acids with CuO as an oxidant. Industrial & Engineering Chemistry Research 2014, 53 (19), 7939-7946. (共同一作)

6) Wang, Y., Jin, F., Sasaki, M., Wahyudiono, Wang, F., Jing, Z., Goto, M. Selective conversion of glucose into lactic acid and acetic acid with copper oxide under hydrothermal conditions. AIChE Journal 2013, 59 (6), 2096-2104.

7) Wang, Y., Jin, F., Zeng, X., Yao, G., Jing, Z. A novel method for producing hydrogen from water with Fe enhanced by HS- under mild hydrothermal conditions. International Journal of Hydrogen Energy 2013, 38 (2), 760-768.

8) Wang, Y., Jin, F., Zeng, X., Ma, C., Wang, F., Yao, G., Jing, Z. Catalytic activity of Ni3S2 and effects of reactor wall in hydrogen production from water with hydrogen sulphide as a reducer under hydrothermal conditions. Applied Energy 2013, 104, 306-309.

9) Wang, Y., Wang, F., Jin, F., Jing, Z. Effects of metals and Ni3S2 on reactions of sulfur species (HS-, S and S2O32-) under alkaline hydrothermal conditions. Industrial & Engineering Chemistry Research 2013, 52 (16), 5616-5625.

10) Werny, M., Wang, Y., Girgsdies, F., Schlögl, R., Trunschke,. A. Fluctuating storage of the active phase in a MnNa2WO4/SiO2 catalyst for the oxidative coupling of methane. Angewandte Chemie International Edition 2020, 59 (35), 14921-14926.

11) Amakawa K., Wang Y., Kröhnert J., Schlögl., R., Trunschke A. Acid sites on silica-supported molybdenum oxides probed by ammonia adsorption: Experiment and theory. Molecular Catalysis 2019, 478, 110580.

12) Fu, T., Wang, Y., Wernbacher, A., Schlögl., R., Trunschke, A. Single-site vanadyl species isolated within molybdenum oxide monolayers in propane oxidation. ACS Catalysis 2019, 9 (6), 4875-4886.

13) Ooka, H., Wang, Y., Yamaguchi, A., Hatakeyama, M., Nakamura, S., Hashimoto, K., Nakamura, R. Legitimate intermediates of oxygen evolution on iridium oxide revealed by in-situ electrochemical evanescent wave spectroscopy. Physical Chemistry Chemical Physics 2016, 18, 15199-15204.

14) Trunschke, A., Bellini, G., Boniface, M., … &Wang, Y., Wrabetz, S. Towards Experimental Handbooks in Catalysis. Topics in Catalysis 2020. https://doi.org/10.1007/s11244-020-01380-2.


版权所有 © 上海大学   沪ICP备09014157   沪公网安备31009102000049号  地址:上海市宝山区上大路99号    邮编:200444   电话查询
 技术支持:上海大学信息化工作办公室   联系我们