代表论著:
近3年代表论著
1)J. Yang, H. Yan, H. Hao, Y. Song, Y. Li, Q. Liu*, A. Tang*, Synergetic Modulation on Solvation Structure and Electrode Interface Enables a Highly Reversible Zinc Anode for Zinc–Iron Flow Batteries, ACS Energy Letters, 2022, 7, 2331-2339.
2)H. Hao, Q. Zhang, Z. Feng*, A. Tang*, Regulating flow field design on carbon felt electrode towards high power density operation of vanadium flow batteries, Chemical Engineering Journal, 2022, doi.org/10.1016/j.cej.2022.138170
3)M. Yang, Z. Xu, W. Xiang, H. Xu, M. Ding*, L, Li, A. Tang*, R. Gao, G. Zhou*, C. Jia*, High performance and long cycle life neutral zinc-iron flow batteries enabled by zinc-bromide complexation, Energy Storage Materials, 2022, 44, 433-440.
4)Y. Jiang, Z. Liu, Y. Lv, A. Tang*, L. Dai, L. Wang, Z. He*, Perovskite enables high performance vanadium redox flow battery, Chemical Engineering Journal, 2022, 443, 136341.
5)K. Zhang, C. Yan, A. Tang*, Oxygen-induced electrode activation and modulation essence towards enhanced anode redox chemistry for vanadium flow batteries, Energy Storage Materials, 2021, 34, 301-310.
6)Y. Song, K, Zhang, X. Li, C. Yan, Q. Liu*, A. Tang*, Tuning the ferrous coordination structure enables a highly reversible Fe anode for long-life all-iron flow batteries, Journal of Materials Chemistry A, 2021, 9(46), 26354-26361.
7)K. Zhang, C. Yan, A. Tang*, Interfacial Co-polymerization Derived Nitrogen-doped Carbon Enables High-performance Carbon Felts for Vanadium Flow Batteries, Journal of Materials Chemistry A, 2021, 9(32), 17300-17310.
8)J. Yang, Y. Song, Q. Liu, A. Tang*, High-capacity zinc–iodine flow batteries enabled by a polymer–polyiodide complex cathode, Journal of Materials Chemistry A, 2021, 9(29), 16093-16098.
9)X. Yu, Y. Song, A. Tang*, Tailoring manganese coordination environment for a highly reversible zinc-manganese flow battery, Journal of Power Sources, 2021, 507, 230295.
10)K. Zhang, J. Xiong, C. Yan, A. Tang*, In-situ measurement of electrode kinetics in porous electrode for vanadium flow batteries using symmetrical cell design, Applied Energy, 2020, 272, 115093.
11)K. Zhang, C. Yan, A. Tang*, Unveiling electrode compression impact on vanadium flow battery from polarization perspective via a symmetric cell configuration, Journal of Power Sources, 2020, 479, 228816.
12)Y. Song, X. Li*, C. Yan, A. Tang*, Unraveling the viscosity impact on volumetric transfer in redox flow batteries, Journal of Power Sources, 2020, 456, 228004.
13)Y. Song, X. Li, C. Yan, A. Tang*, Uncovering ionic conductivity impact towards high power vanadium flow battery design and operation, Journal of Power Sources, 2020, 480, 229141.
14)Y. Song, X. Li, J. Xiong, L. Yang, G. Pan, C. Yan, A. Tang*, Electrolyte transfer mechanism and optimization strategy for vanadium flow batteries adopting a Nafion membrane, Journal of Power Sources, 2020, 449, 227503.
15)Q. Liu, X. Li*, C. Yan, A. Tang*, A dopamine-based high redox potential catholyte for aqueous organic redox flow battery, Journal of Power Sources, 2020, 460, 228124.
学术活动(近期国际国内会议报告及任职等):
* 唐奡,全钒液流电池动态建模与仿真平台开发,第三届全国储能科学与技术大会,深圳,2016年10月
* Ao Tang, Maria Skyllas-Kazacos, Jie Bao. Mathematical modelling and simulation of thermal effects on electrolyte temperature for the all-vanadium redox flow battery, International Flow Battery Forum, Munich, Germany, 2012.6