钒
材料科学
氧化还原
膜
化学工程
高分子科学
化学
冶金
工程类
生物化学
作者
Trung Tuyen Bui,Mingyu Shin,Saleem Abbas,Muhammad Mara Ikhsan,Xuan Huy,Asridin Dayan,Mads Radmer Almind,Sung‐Min Park,David Aili,Johan Hjelm,Jinyeon Hwang,Heung Yong Ha,Kobra Azizi,Yongchai Kwon,Dirk Henkensmeier
标识
DOI:10.1002/aenm.202401375
摘要
Abstract Ion conducting membranes play a crucial role in redox flow batteries, separating anolyte and catholyte while allowing proton transport to complete the circuit. However, most membranes are trapped in a trade‐off relation and show either low conductivity or high vanadium crossover. This study investigates the use of dense sulfonated para ‐polybenzimidazole membranes for vanadium redox flow batteries (VRFBs), and analyzes the effects of membrane preparation process, membrane thickness and operating temperature on the VRFB performance. The results demonstrate superior performance of VRFBs utilizing fluorine‐free sulfonated para ‐polybenzimidazole membranes compared to other types. Under optimal conditions, the VRFB exhibits high coulombic efficiency (>99%) and high energy efficiency (EE, 92.2% at a current density of 80 mA cm −2 ), and durability. The achieved EE represents one of the highest reported in the literature for VRFBs. In addition, it is shown that operation at 35 °C has benefits at high current densities (EE at 300 mA cm −2 is over 80% at 35 °C but 72% at 25 °C), while the operation at 80 mA cm −2 only shows a small temperature effect (91.8 and 92.2%, respectively).
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