离子
反向电渗析
膜
电压
化学物理
离子运输机
物理
光电子学
材料科学
纳米技术
化学
量子力学
电渗析
生物化学
作者
Justin C. Bui,Eric W. Lees,Andrew K. Liu,Wei Lun Toh,T. Nathan Stovall,Priyamvada Goyal,Francisco Javier Ubongen Galang,Yogesh Surendranath,Alexis T. Bell,Adam Z. Weber
出处
期刊:
日期:2024-12-20
卷期号:2 (1): 63-76
被引量:10
标识
DOI:10.1038/s44286-024-00154-x
摘要
The ability for bipolar membranes (BPMs) to interconvert voltage and pH makes them attractive materials for use in energy conversion and storage. Reverse-biased BPMs, which use electrical voltage to dissociate water into acid and base, have become increasingly well studied. However, forward-biased BPMs (FB-BPMs), in which voltage is extracted from pH gradients through recombination, require further study. Here physics-based modeling elucidates how the complex coupling of transport and kinetics dictates the performance of FB-BPMs in electrochemical devices. Simulations reveal that the open-circuit potential of FB-BPMs is dictated by the balance of ion recombination and crossover, where recombination of buffering counter-ions attenuates the open-circuit potential. Counter-ion mass-transport limitations and uptake of ionic impurities limit achievable current densities by reducing the applied pH gradient or the available fixed-charge sites that mediate recombination. Further, the model highlights the importance of selective ion management in mitigating energy losses and provides insight into the rational material design of FB-BPMs for energy applications.
科研通智能强力驱动
Strongly Powered by AbleSci AI