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        北京大学澳门十大赌厅网能源与资源工程系
2020 –今              Co-PI             北京市工程科学与新兴技术高精尖创新中心
2017 – 2020        博后                Massachusetts Institute of Technology, DMSE 
2017                    博后                University of Waterloo, Chemistry

研究领域：

我们电化学能源技术实验室以电化学技术手段为切入点，来解决能源和环境领域存在的共性问题，包括电化学储能，人工燃料合成、气体捕集等。我们关注电极材料设计，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，解决当前能源战略的短板问题。

诚挚欢迎有科学热情，有化学、材料、物理背景的博士生（夏令营直博、普博）、博士后、本科生和研究助理加入我们团队。

发表论文：

21. Pang, Q., Kwok, C.Y., Kundu, D., Nazar L.F.* (2018) Lightweight metallic MgB₂ mediates polysulfide redox and promises high-energy-density lithium-sulfur batteries. Joule, 3,136.

20. Pang, Q., Zhou, L., Nazar L.F.* (2018) An elastic and Li-ion-percolating hybrid membrane stabilizes Li metal plating. Proc. Natl. Acad. Sci. USA, 115, 12389.

19. Pang, Q., Liang, X., Kochetkov, I.R., Hartmann, P., Nazar L.F. * (2018) Stabilizing lithium plating by a biphasic surface layer formed in situ. Angew. Chem. Int. Ed., 57, 9795.

18. 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.

17. Pang, Q., Liang, X., Shyamsunder A., Nazar, L.F.* (2017) An in vivo formed solid electrolyte surface layer enables stable plating of Li metal. Joule, 1, 871.

16. Liang, X., Pang, Q., Kochetkov, I.R. Sempere, M.S., Huang, H., Sun, X., Nazar, L.F.* (2017) A facile surface chemistry route to a stabilized lithium metal anode. Nature Energy, 2, 17119.

15. Lee, C.-W. ^†, Pang, Q. ^†, Ha, S., Cheng, L., Han, S.-D., Gallagher, K.G., Nazar, L.F.,*Balasubramanian, M.* (2017) Directing the lithium-sulfur reaction pathway via sparingly solvating electrolytes for high energy density batteries. ACS Cent. Sci., 3,605.

14. Shyamsunder, A., Beichel, W., Klose, P., Pang, Q., Scherer, H., Hoffmann, A., Murphy, G.K., Krossing, I., Nazar, L.F., (2017) Inhibiting Polysulfide Shuttle in Lithium–Sulfur Batteries through Low‐Ion‐Pairing Salts and a Triflamide Solvent, Angew. Chem. Intl. Ed.,56, 6192.

13. 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.

12. Pang, Q., Liang, X., Kwok, C.Y., Kulisch, J., Nazar, L.F.* (2016) A comprehensive approach towards stable lithium-sulfur batteries with high volumetric energy density. Adv. Energy Mater., 7, 1601630.

11. Pang, Q., Nazar, L.F.* (2016) Long-life and high areal capacity Li-S batteries enabled by a light-weight polar host with intrinsic polysulfide adsorption. ACS Nano,10, 4111.

10. Pang, Q., Kundu, D., Nazar, L.F.* (2016) A graphene-like metallic cathode host for long-life and high-loading lithium-sulfur batteries. Mater. Horiz., 3,130.

9. Liang, X., R. Yverick, Kwok, C.Y., Pang, Q., Nazar, L.F.* (2016) Interwoven MXene nanosheet/carbon nanotube composites as Li-S cathode hosts. Adv. Mater., 29, 1603040.

8. Talaie, E., Bonnick, P., Sun, X., Pang, Q., Liang, X., Nazar, L.F.* (2016) Methods and protocols for electrochemical energy storage materials research. Chem. Mater., 29, 90.

7. Pang, Q., Liang, X., Kwok, C.Y., Nazar, L.F.* (2015) The importance of chemical interactions between sulfur host materials and polysulfides for advanced lithium-sulfur batteries. J. Electrochem. Soc., 162, A2567.

6. Pang, Q.,^† Tang, J.,^† Huang, H., Liang, X., Hart, C., Tam, K.C.,* Nazar, L.F.* (2015) A nitrogen and sulfur dual‐doped carbon derived from polyrhodanine/cellulose for lithium–sulfur batteries.  Adv. Mater., 27, 6021.

5. Liang X., Kwok, C.Y., Lodi-Marzano, F., Pang, Q., Cuisinier, M., Huang, H., Hart, C., Houtarde, D., Brezesinski, T., Janek, J., and Nazar, L.F.* (2015) Tuning transition metal oxide-sulfur interactions for long life lithium sulfur batteries: the ‘goldilocks’ principle. Adv. Energy Mater., 6, 1501636.

4. 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.

3. Liang, X., Hart, C., Pang Q., Garsuch, A., Weiss T., Nazar, L. F.* (2014) A highly efficient polysulphide mediator for lithium-sulphur batteries. Nature Commun., 6,5682.

2. Nazar, L. F.,* Cuisinier, M., Pang, Q. (2014) Lithium-sulfur batteries. MRS Bull., 39, 436.

1. Wang, Z., Pang, Q., Deng, K., Yuan, L., Peng, Y., Huang, Y.* (2012) Effects of titanium incorporation on phase and electrochemical performance in LiFePO₄ cathode material. Electrochim. Acta, 78, 576.