聚酰亚胺
材料科学
Nafion公司
膜
钒
选择性
电导
化学工程
高分子化学
复合材料
有机化学
电化学
电极
化学
图层(电子)
物理化学
工程类
催化作用
组合数学
数学
生物化学
冶金
作者
Jun Long,Wenheng Huang,Huiting Li,Liang Chen,Jinchao Li,Ji‐Jun Chen,Aibing Lu,Yaping Zhang
标识
DOI:10.1021/acsami.4c03314
摘要
Membrane with remarkable proton conductance and selectivity plays a key role in obtaining high vanadium flow battery (VFB) performance. In this work, the trade-off effect between proton conductance and vanadium ion blocking was overcome by the introduction of a cross-linking structure to prepare covalent cross-linked fluorine-containing sulfonated polyimide (CFSPI-PVA) membranes. Herein, the CFSPI-PVA-15 membrane possesses excellent comprehensive properties, including acceptable area resistance (0.21 Ω cm 2 ), lower vanadium ion permeability (0.76 × 10 –7 cm 2 min –1 ), and remarkable proton selectivity (3.11 × 10 5 min cm –3 ) compared with the commercial Nafion 212 membrane. At the same time, the CFSPI-PVA-15 membrane exhibits higher coulomb efficiencies (97.26%–99.34%) and energy efficiencies (68.65%–88.11%) and a longer self-discharge duration (29.2 h) in contrast with the Nafion 212 membrane. Moreover, 500 cycles of the CFSPI-PVA-15 membrane at 160 mA cm –2 are also stably executed. The internal reasons for the improved chemical stability of the CFSPI-PVA-15 membrane are clarified from theoretical calculations with the mean square displacement value and fractional free volume. Therefore, the CFSPI-PVA-15 membrane exhibits great potential for application in VFB.
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