孔祥坤

发布者:张立江发布时间:2026-07-07浏览次数:11

个人简介:

孔祥坤,男,1999年生,山东临沂人,博士,准聘副教授硕士生导师。长期专注固态电池研发,具备氧化物、硫化物、卤化物与聚合物基固态电池多路线研究经验。迄今为止,已在包括Nat. Commun.Sci. Adv.Angew. Chem. Int. Ed.Energy Storage Mater.等国际国内期刊上合作发表论文。曾获博士国家奖学金、杨承宗奖学金(中国科学技术大学化学与材料科学学院最高奖学金)、安徽省优秀毕业生以及中国科学技术大学优秀毕业生等荣誉。

联系方式:

邮箱:kongxiangkun@mail.ustc.edu.cn

教育/工作经历:

  • 2026.07至今:中国矿业大学,准聘副教授

  • 2021.09-2026.06:中国科学技术大学,博士,导师:王成威教授

  • 2017.09-2021.06:山东科技大学,学士,导师:田健教授

研究方向:

  • 新型卤化物固态电解质的开发(锂电/钠电/钾电)

  • 新型氧化物固态电解质的开发(锂电/钠电/钾电)

  • 新型混合离子-电子导体材料的开发与应用

代表性科研成果:

  1. X. Kong, R. Gu, Z. Jin, L. Zhang, C. Zhang, W. Xiang, C. Li, K. Zhu, Y. Xu, H. Huang, X. Liu, R. Peng, C. Wang*, Maximizing interface stability in all-solid-state lithium batteries through entropy stabilization and fast kinetics. Nat. Commun. 15, 7247 (2024). Nature子刊,一作

  2. X. Kong1,Z. Jin1, L. Chen, X. Huang, B. Feng, H. Huang, Y. Xu, W. Wei, W. Yang, S. Shen, Z. Zhuo, W. Ping, R. Peng, C. Chen, C. Wang*, A High Entropy Mixed Ionic and Electronic Conductor for Accelerating the Cathode Dynamics in All-Solid-State Lithium Metal Batteries. Sci. Adv. 4710, 1-9 (2025).Science子刊,一作

  3. Z. Jin1, X. Kong1, H. Huang, Y. Jiang, W. Xiang, Y. Xu, L. Zhang, R. Peng, C. Wang*, Garnet-type solid-state mixed ionic and electronic conductor. Energy Storage Mater. 59, 102788 (2023).

  4. L. Chen1, X. Kong1, H. Huang, W. Wu, W. Ping, C. Wang*, Pyrochlore solid-state electrolytes and mixed ionic and electronic conductors. Energy Storage Mater. 83, 104752 (2025).

  5. Y. Xu1, Z. Jin1, X. Kong, C. Zhang, C. Li, Z. Zhuo, R. Peng, C. Wang*, Non-transition metal modulated reducibility strategy for highly conductive mixed electronic and ionic (LixLa2/3-x/3)TiO3 perovskite. Energy Storage Mater. 75, 104074 (2025).

  6. X. Liu, X. Kong,W. Xiang, Y. Jiang, B. Xiong, W. Ping, C. Xia, D. Huan, C. Wang*, LiCoO2 sintering aid towards cathode-interface-enhanced garnet electrolytes. J. Energy Chem. 84, 181–188 (2023).

  7. W. Xiang, R. Ma, X. Liu, X. Kong, S. Shen, L. Wang, Z. Jin, Z. Zhan, C. Chen, C. Wang*, Rapid Li compensation toward highly conductive solid state electrolyte film. Nano Energy. 116, 108816 (2023).