电导率
膜
氢氧化物
离子交换
化学工程
碱性燃料电池
化学
胺气处理
无机化学
碱性水电解
质子交换膜燃料电池
离子
电解
离子运输机
材料科学
支化(高分子化学)
氢氧化钾
氢氧化钠
燃料电池
电化学
电流密度
位阻效应
离子电导率
催化作用
作者
Haitao Zhang,Fengxiang Zhang,Shoutao Gong,Long Han,Omer Javed,Xinyu Wang,Yongpeng Li,Yujiang Song,Xiaoming Yan,Xinquan Cheng,Bo Zhao,Gaohong He
出处
期刊:Chemsuschem
[Wiley]
日期:2026-05-19
卷期号:19 (10): e70734-e70734
摘要
The key requirement for applying anion exchange membranes (AEMs) in water electrolyzers and fuel cells is the concurrent enhancement of hydroxide conductivity and alkaline stability. To this end, we herein report a novel hexa‐arm branched poly (aryl piperidinium) AEM incorporating bulky three‐dimensional tris (4‐carbazol‐9‐ylphenyl) amine (TCA) unit. The TCA unit creates a high‐density ion conduction network via increased free volume and promoted microphase separation, while its steric hindrance effect protects the piperidinium cations from hydroxide attack. With a TCA content of 3%, the fabricated membrane (ion exchange capacity being 2.75 mmol g −1 ) achieves an OH ‐ conductivity of 155.7 mS cm −1 at 80°C and retains 95.1% conductivity after 2000 h in 1 M NaOH at 80°C. When assembled into a fuel cell, it delivers a peak power density of 1.95 W cm −2 at 80°C under 1.3 bar back pressure; in a water electrolyzer operating at 80°C, it yields a current density of 9.51 A cm −2 at 2.0 V. This study offers a novel branching strategy to improve ion transport in AEMs and demonstrates how the branching degree influences alkaline stability of the membrane, which is useful for further improvement of the membrane and device performances.
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