教育经历:
2014–2017 博士 University of Waterloo化学系
2012–2014 硕士 University of Waterloo化学系
2008–2012 学士 华中科技大学材料科学与工程
工作经历:
2020 –今 助理教授 北京大学材料科学与工程学院
2017 – 2020 博后 Massachusetts Institute of Technology, DMSE
2017 博后 University of Waterloo, Chemistry
研究兴趣:
我们电化学能源技术实验室以电化学技术手段为切入点,来解决能源领域存在的共性问题,包括电化学储能(电池)、气体捕集、资源利用等。我们关注传统及新型电化学体系中的电极材料设计,电解液开发,异相界面演化和设计,电化学反应机理及衰减机制,通过光谱学、显微学、理论计算来理解电化学本质。我们也致力于将基础问题研究与发展工程技术相结合,解决当前能源和环境的短板问题。
In our group, we are interested in solving the most urgent and tough energy problems in front of us, and we tackle the problems from the perspective of electrochemistry. We aim to develop efficient, reliable and yet low-cost batteries, geared towards grid energy storage and electric transportation, both of which are critical sectors for a clean and renewable future. We also aim to extend our expertise to develop electrochemical solutions for solving the pressing questions pertaining to fossil fuel shortage, CO2 accumulation, innovation on resources recycling and exploitation. One thrust of our research is to develop new chemical systems and materials/chemical solutions (electrolytes, electrodes) towards our envisioned systems and applications, and the other is to understand the chemical/materials origin and mechanism of how it works or fails, by applying a range of characterization techniques developed by us and the field.
荣誉与奖励:
阿里巴巴达摩院青橙科学家奖(2023)
科睿唯安高被引科学家(2020、2022、2023)
重点研发计划青年首席科学家(新能源汽车, 2021)
科研成果:
近几年在全固态电池、熔融盐电池、锂硫电池、多价离子电池等低成本电化学储能体系领域取得突出成果,在Nature、Nature Energy,Joule, Matter, PNAS, Nature Commun., Adv. Mater., Angew. Chem.,ACS Cent. Sci. 等期刊发表30余篇论文,总引用超过12000次, h-index27,并与多家公司积极探索产业化研究。
代表性学术论文:
1. Pang, Q.*, Meng, J., Gupta, S., Hong,X.,Kwok,C.Y.,Zhao, J.,Jin, Y.,Xu, L.,Karahan,O.,Wang, Z.,Toll, S.,Mai, L.,Nazar, L. F.,Balasubramanian, M.,Narayanan, B., Sadoway,D.R. * (2022) Fast-charging aluminium–chalcogen batteries resistant to dendritic shorting, Nature, 608, 704.
2. He, M., Zhu, L., Ye, G., An, Y., Hong, X., Ma, Y., Xiao, Z., Jia, Y.,Pang, Q.* (2024) Angew. Chem. Intl. Ed. e202401051.
3. Liu, Y., An, Y., Zhu, J., Zhu, L., Li, X., Gao, P., He, G.,Pang, Q.* (2024)Integrated energy storage and CO2conversion using an aqueous battery with tamed asymmetric reactions. Nature Commun. 15, 977.
4. Meng, J., Hong, X., Xiao, Z., Xu, L., Zhu, L., Jia, Y., Liu, F., Mai, L.,Pang, Q.*(2024) Rapid-charging aluminium-sulfur batteries operated at 85° C with a quaternary molten salt electrolyte. Nature Commun.15, 595.
5. Liu, Y., Zhu, L., Wang, E., An, Y., Liu, Y., Shen, K., He, M., Jia, Y., Ye, G., Xiao, Z., Li, Y.,Pang, Q.* (2023) Electrolyte engineering with tamed electrode interphases for high‐voltage sodium‐ion batteries. Adv. Mater.2310051.
6. Liu, Y., Xu, L., Yu, Y., He, M., Zhang, H., Tang, Y., Xiong, F., Gao, S., Li, A., Wang, J., Xu, S., Aurbach, D., Zou, R.,Pang, Q.* (2023) Stabilized Li-S batteries with anti-solvent-tamed quasi-solid-state reaction. Joule. 7, 2074.
7. Meng, J., Yao, X., Hong, X., Zhu, L., Xiao, Z., Jia, Y., Liu, F., Song, H., Zhao, Y.,Pang, Q.*(2023) A solution-to-solid conversion chemistry enables ultrafast-charging and long-lived molten salt aluminium batteries. Nature Commun., 14, 3909.
8. Liu, Y., Elias, Y., Meng, J., Aurbach, D., Zou, R., Xia, D.,Pang, Q*. (2021) Electrolyte solutions design for lithium-sulfur batteries. Joule, 5, 2323.
9. Pang, Q., Shyamsunder, A.,Narayanan, B., Kwok, C.Y., Curtiss, L.A., Nazar L.F.* (2018)Tuning the electrolyte network structure to invoke quasi-solid state sulfur conversion and suppress lithium dendrite formation in Li–S batteries. Nature Energy, 3, 783.
10. Pang, Q.†,Liang, X.†, Kwok, C. Y.†, Nazar, L. F. * (2016) Advances in lithium–sulfur batteries based on multifunctional cathodes and electrolytes. Nature Energy,1, 16132.
11. Pang, Q., Kundu, D., Cuisinier, M., Nazar, L. F.* (2014) Surface-enhanced redox chemistry of polysulphides on a metallic and polar host for lithium-sulphur batteries. Nature Commun., 5, 4759.
