王建德，男，2009至2016年本硕就读于湖南大学材料科学与工程学院，2021年博士毕业于比利时鲁汶大学（法语区），2022至2024年在麻省理工学院化学系从事博士后研究（Postdoc Associate）。主要研究领域为有机正极材料、有机或金属有机材料在储锂和导锂领域的应用。发表SCI期刊论文30余篇，其中以第一作者或通讯作者在Nature Materials、Nature Energy、JACS、Science Advances、Energy & Environmental Science、ACS Energy Letters、Angewandte Chemie International Edition等期刊发表高水平论文十余篇，申请美国发明专利2项。

Email: jiandewang@hnu.edu.cn

2022—2024，博士后研究员，麻省理工学院(Advisor: Mircea Dincă)

2025—至今，教授，博士生导师，湖南大学

2016—2021，Ph.D. : IMCN, UCLouvain, Belgium

2013—2016，Master: Materials Science and Engineering, Hunan University, China

2009—2013，Bachelor: Materials Science and Engineering, Hunan University, China

部分科研论文

[1]Yan Zhang, Xuelian Liu, Yichen Wei, Weiran Wang, Lu Bai, Alexandru Vlad*, Junzhong Wang*, Jiande Wang*. Machine Learning-Guided Design of a Flexible Highly Conductive Additive-Free Polymer Cathode. Angewandte Chemie International Edition (2026): e25729,https://doi.org/10.1002/anie.202525729

[2]Xiaolong Guo†, Robert Markowski†, Ashley Black†, Petru Apostol, Darsi Rambabu, ..., Jean-François Gohy, Jan Bitenc*, Jiande Wang*, Alexandre Ponrouch* and Alexandru Vlad*. Amorphous coordination polymers for versatile Mg2+, Ca2+, Sr2+, Ba2+, and Zn2+ cation storage. Energy & Environmental Science (2025).

[3]Tianyang Chen†, Jiande Wang†, Bowen Tan, Kimberly J. Zhang, Harish Banda, Yugang Zhang, Dong-Ha Kim, and Mircea Dincă*, High-Energy, High-Power Sodium-Ion Batteries from a Layered Organic Cathode. Journal of the American Chemical Society 2025 147 (7), 6181-6192.

[4]Y. Zhang, P. Apostol, D. Rambabu, X. Guo, X. Liu, X. Lin, H. Xie, X. Chen, K. Robeyns, J. Wang*, J. Wang*, A. Vlad*, Ionically conducting Li- and Na-phosphonates as organic electrode materials for rechargeable batteries. Chemical Science 2025 16, 1819-1825.

Before 2025

[1]J. Wang, T. Chen, et al. Superior Charge Transport in Ni-Diamine Conductive MOFs. Journal of the American Chemical Society 146 (29), 20500-20507 (2024)

[2]Zhang, J. Wang*, et al. Bimetallic Anionic Organic Frameworks with Solid-State Cation Conduction for Charge Storage Applications. Angew. Chem. Int. Ed. 62, e202310033. (2023)

[3]Zhang Y., Apostol P., Guo X., Liu X., Rambabu D., J. Wang*, et al. Validating the reversible redox of alkali-ion disulfonyl-methanide as organic positive electrode materials. Materials Today Chemistry, 28, 101379 (2023)

[4]J. Wang, et al. Revealing the reversible solid-state electrochemistry of lithium-containing conjugated oximates for organic batteries. Science Advances 9, eadg6079 (2023)

[5]J. Wang, et al. High-performance Li-, Na-, and K-ion storage in electrically conducting coordination polymers. Energy Environmental Science, 15, 3923-3932 (2022)

[6]J. Wang, X. Liu, et al. A High Voltage Organic Framework for High Performance Na- and K-ion Batteries. ACS Energy Letters 7, 2, 668–6742022 (2022)

[7]X. Liu†, J. Wang†, et al. New Cathode Materials in the Fe-PO4-F Chemical Space for High-Performance Sodium-Ion Storage. Advanced Science, 9, 2200924 (2022)

[8]X. Liu†, J. Wang†, M. et al. Unlocking the Electrochemistry and the Activation Mechanism in the Iron-Rich Na0.6Fe1.2PO4 Phase for High-Performance Sodium-Ion Storage. Batteries & Supercaps, 5, e202100390 (2022)

[9]J. Wang, A.E. Lakraychi, et al. Conjugated sulfonamides as a class of organic lithium-2, ion positive electrodes. Nature Materials 20, 665–673 (2021)

[10]J. Wang, A. Vlad. Empowering magnesium. Nature Energy 5, 945–946 (2020)