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Abstract
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, are poorly understood. In this work, physics-based modeling elucidates how complex coupling of transport and kinetics dictates the performance of FB-BPMs in electrochemical devices. Simulations reveal that the open-circuit potential (OCP) of FB-BPMs is dictated by the balance of ion recombination and crossover, where recombination of buffering counter-ions attenuates OCP. Uptake of ionic impurities and fixed-charge neutralization limit achievable current densities by reducing the fraction of fixed-charge sites that mediate recombination. The model highlights the importance and nuances of selective ion management in mitigating energy losses and provides insight into the engineering of FB-BPMs for energy applications.
Supplementary materials
Title
Supplementary Information
Description
Supplementary Methods, Supplementary Tables (Including All Fit and Literature Parameters), Supplementary Notes and Derivations, and Supplementary Figures.
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