A H3PO4 preswelling strategy to enhance the proton conductivity of a H2SO4-doped polybenzimidazole membrane for vanadium flow batteries
发表时间:2019-03-09
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- 论文类型:
- 期刊论文
- 第一作者:
- Peng, Sangshan
- 通讯作者:
- He, GH (reprint author), Dalian Univ Technol, Sch Chem Engn, State Key Lab Fine Chem, R&D Ctr Membrane Sci & Technol, Dalian 116023, Peoples R China.
- 合写作者:
- Yan, Xiaoming,Zhang, Daishuang,Wu, Xuemei,Luo, Yongliang,He, Gaohong
- 发表时间:
- 2016-01-01
- 发表刊物:
- RSC ADVANCES
- 收录刊物:
- SCIE、EI
- 文献类型:
- J
- 卷号:
- 6
- 期号:
- 28
- 页面范围:
- 23479-23488
- ISSN号:
- 2046-2069
- 摘要:
- A H3PO4 preswelling strategy is proposed to prepare H2SO4-doped polybenzimidazole (PBI) membranes for vanadium flow batteries (VFB). Before being immersed in 3.0 M H2SO4, PBI membranes are preswelled by immersion in concentrated H3PO4, which leads to a higher H2SO4 doping level, thereby dramatically reducing the area resistance of the PBI membrane to 0.43 Omega cm(2), which is close to that of Nafion 212 (0.35 Omega cm(2)) and much lower than that of Fumasep (R) FAP-450 (0.64 Omega cm(2)). Meanwhile, the substantially high selectivity is maintained. The VFB assembled with the H3PO4 preswelled PBI membrane displays high energy efficiencies (EE: 80.9-89.2%) over a current density range of 20-80 mA cm(-2), much higher than those of the non-preswelled PBI membrane (EE: 66.8-84.5%), Nafion 212 (EE: 63.1-75.6%) and Fumasep (R) FAP-450 (EE: 75.5-82.6%). The stable performance over 50 charge-discharge cycles demonstrates the good physicochemical stability of the preswelled PBI membrane. Considering the above results, the H3PO4 preswelling strategy proposed herein is facile and efficient for fabricating high-performance PBI membranes for VFB.
- 是否译文:
- 否
