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Modeling Ion Transport across Thin-Film Composite Membranes During Saltwater Electrolysis

Affordable thin-film composite (TFC) membranes are a potential alternative to more expensive ion exchange membranes in saltwater electrolyzers used for hydrogen gas production. We used a solution-friction transport model to study how the induced potential gradient controls ion transport across the polyamide (PA) active layer and support layers of TFC membranes during electrolysis. The set of parameters was simplified by assigning the same size-related partition and friction coefficients for all salt ions through the membrane active layer. The model was fit to experimental ion transport data from saltwater electrolysis with 600 mM electrolytes at a current density of 10 mA cm-2. When the electrolyte concentration and current density were increased, the transport of major charge carriers was successfully predicted by the model. Ion transport calculated using the model only minimally changed when the negative active layer charge density was varied from 0 to 600 mM, indicating active layer charge was not largely responsible for controlling ion crossover during electrolysis. Based on model simulations, a sharp pH gradient was predicted to occur within the supporting layer of the membrane. These results can help guide membrane design and operation conditions in water electrolyzers using TFC membranes.

This document is the Accepted Manuscript version of a Published Work that appeared in final form in Environmental Science & Technology, copyright © 2024 American Chemical Society, after peer review and technical editing by the publisher. To access the final edited and published work see https://doi.org/10.1021/acs.est.4c02397

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Work Title Modeling Ion Transport across Thin-Film Composite Membranes During Saltwater Electrolysis
Access
Open Access
Creators
  1. Rachel F. Taylor
  2. Xuechen Zhou
  3. Chenghan Xie
  4. Fernan Martinez
  5. Xinran Zhang
  6. Bastiaan Blankert
  7. Cristian Picioreanu
  8. Bruce E. Logan
Keyword
  1. Green hydrogen production
  2. Solution-friction modeling
  3. Donnan partitioning
  4. Polyamide membrane
  5. Seawater electrolysis
License In Copyright (Rights Reserved)
Work Type Article
Publisher
  1. Environmental Science & Technology
Publication Date June 11, 2024
Publisher Identifier (DOI)
  1. https://doi.org/10.1021/acs.est.4c02397
Deposited February 13, 2025

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Version 1
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  • Created

    February 13, 2025 19:21 by Researcher Metadata Database

  • Added 2024-Taylor-etal-ES_T-modeling-_accepted.pdf

    February 13, 2025 19:21 by Researcher Metadata Database

  • Added Creator Rachel F. Taylor

    February 13, 2025 19:21 by Researcher Metadata Database

  • Added Creator Xuechen Zhou

    February 13, 2025 19:21 by Researcher Metadata Database

  • Added Creator Chenghan Xie

    February 13, 2025 19:21 by Researcher Metadata Database

  • Added Creator Fernan Martinez

    February 13, 2025 19:21 by Researcher Metadata Database

  • Added Creator Xinran Zhang

    February 13, 2025 19:21 by Researcher Metadata Database

  • Added Creator Bastiaan Blankert

    February 13, 2025 19:21 by Researcher Metadata Database

  • Added Creator Cristian Picioreanu

    February 13, 2025 19:21 by Researcher Metadata Database

  • Added Creator Bruce E. Logan

    February 13, 2025 19:21 by Researcher Metadata Database

  • Published

    February 13, 2025 19:21 by Researcher Metadata Database

  • Updated

    February 13, 2025 21:04 by [unknown user]

  • Updated Keyword Show Changes

    April 09, 2025 11:47 by avs5190

    Keyword
    • Green hydrogen production, Solution-friction modeling, Donnan partitioning, Polyamide membrane, Seawater electrolysis
  • Updated Publisher's Statement Show Changes

    April 15, 2025 18:57 by avs5190

    Publisher's Statement
    • This document is the Accepted Manuscript version of a Published Work that appeared in final form in Environmental Science & Technology, copyright ©, [include copyright notice from the published article] after peer review and technical editing by the publisher. To access the final edited and published work see [insert ACS Articles on Request author-directed link to Published Work, see ACS Articles on Request ].”
    • This document is the Accepted Manuscript version of a Published Work that appeared in final form in Environmental Science & Technology, copyright © 2024 American Chemical Society, after peer review and technical editing by the publisher. To access the final edited and published work see https://doi.org/10.1021/acs.est.4c02397