张海涛   研究员

             学历/学位：研究生/博士

             研究方向：能源材料、储能技术、电池回收

             邮箱：htzhang@ipe.ac.cn

             地址：北京市海淀区中关村北二街1号

             邮编：100190

简历介绍

张海涛，中科院过程所研究员、博士生导师。2006年6月于中国科学技术大获得博士学位，2011年加入中国科学院过程工程研究所，2006年7月至2011年12月间先后在新加坡国立大学材料系和日本国立材料研究所(NIMS)从事博士后研究。目前主要从事新能源材料和大规模储能技术的研究。先后主持国家新能源汽车专项课题、基金委面上基金和北京市科委重大专项，参与科技部“973”计划和基金委中韩联合基金，目前主持国家新能源汽车专项课题、北京市自然科学基金委员会的重点专题项目、河南省创新示范专项、中国科学院重点部署项目的课题和郑州市重大专项等重大研发项目。迄今为止，在Phys. Rev. Lett., Adv. Mater., Adv. Funct. Mater., Energy Storage Materials, Chem. Mater., J Mater. Chem., J Power Sources等期刊接收发表90余篇SCI论文，论文共被他人引用2400多次。中国有色金属产业技术创新战略联盟专家委员会委员，中国电工技术学会电池专业委员会委员。

代表论著

1. Da, H.R.; Li, J.; Zhang. H.T. Enhancing the depressed initial Coulombic efficiency of regenerated graphite anodes via the surface modification of a TiNb₂O₇ nanolayer. Carbon Accepted.

2. Tang, Y.J., Yang, L.P.; Zhu, Y.M., Zhang, Feng, F.J.; Zhang. H.T. Fabrication of highly stable Nb₂O₅@C/CNTs based anolyte for lithium slurry flow battery. Journal of Material Chemistry A. 2022, 10: 5620-5630

3. Li J.J.; Yang, L.P.; Zhang. H.T.; Ji, X.Y. Self-healing composite solid electrolytes with enhanced Li⁺ transport and mechanical properties for safe lithium metal batteries. Chemical Engineering Journal. 2022, 438: 135418.

4. Li, J.; Cai, Y.J.; Cui, Y.Y.; Wu, H.; Da, H.R.; Yang, Y.J.; Zhang, H.T.; Zhang, S.J. Fabrication of asymmetric bilayer solid-state electrolyte with boosted ion transport enabled by charge-rich space charge layer for -20~70°C lithium metal battery. Nano Energy. 2022, 95: 107027.

5. Su, P.P.; Zhang, H.T.; Yang, L.; Xing, C.X.; Pan, S.S.; Lu, W.; Zhang, S.J. Effects of conductive additives on the percolation networks and rheological properties of LiMn_0.7Fe_0.3PO₄ suspensions for lithium slurry battery. Chemical Engineering Journal. 2022, 433: 133203.

6. Yao, M.; Ruan, Q.Q.; Yu, T.; Zhang, H.T.; Zhang, S.J. Solid polymer electrolyte with in-situ generated fast Li⁺ conducting network enable high voltage and dendrite-free lithium metal battery. Energy Storage Materials, 2022, 44, 93-103.

7. Li, J.; Huo, F.; Yang, Y.; Chen, T.; Cui, Y.; Cai, Y.J.; Zhang, H.T. Constructing stable lithium interfaces via coordination of fluorinated ether and liquid crystal for room-temperature solid-state lithium metal batteries. Chemical Engineering Journal. 2022，433: 133562.

8. Song, X.L.; Wang, C.; Chen, J.; Xin, S.; Yuan, D.; Wang, Y.; Dong, K.; Yang, L.; Wang, G.Y.; Zhang, H.T.; Zhang, S.J. Unraveling the synergistic coupling mechanism of Li⁺ transport in an “Ionogel-in-Ceramic” hybrid solid electrolyte for rechargeable lithium metal battery. Advanced Functional Materials. 2022, 32: 2108706.

9. Yao, M.; Zhang, H.T.; Xing, C.X.; Li, Q.; Tang, Y.; Zhang, F.; Yang, K.; Zhang, S.J. Rational design of biomimetic ant-nest solid polymer electrolyte for high-voltage Li-metal battery with robust mechanical and electrochemical performance. Energy Storage Materials, 2021, 41, 51-60.

10. Pan, S.S.; Zhang, H.T.; Xing, C.X.; Yang, L.; Su, P.P.; Bi, J.; Zhang, S.J. Ultrahigh-capacity semi-solid SiO_x anolytes enabled by robust nanotube conductive networks for Li-ion flow batteries. Journal of Power Sources, 2021, 508, 230341-230353.

11. Yao, M.; Yu, T.; Ruan, Q.Q.; Chen, Q.; Zhang, H.T.; Zhang, S.J. High-voltage and wide-temperature lithium metal batteries enabled by ultrathin MOF-derived solid polymer electrolytes with modulated ion transport. ACS Applied Materials & Interfaces, 2021, 13 (39), 47163-47173.

12. Da, H.R.; Zhang, H.T.; Gan, M.; Jiang, D.F.; Xing, C.X.; Zhang, Z.Y.; Fei, L.F.; Cai, Y.; Zhang, S.J. Epitaxial regeneration of spent graphite anode material by an eco-friendly in-depth purification route. ACS Sustainable Chemistry & Engineering, 2021, 9(48), 16192-16202.

13. Zhang, H.T.; Zhang, S.J.; Zhang, X.X. Experimental discovery of magnetoresistance and its memory effect in methylimidazolium-typeiron-containing ionic liquids. Chemistry of Materials, 2016, 28: 8710-8714.