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Membrane-free electrochemical production of acid and base solutions capable of processing ultramafic rocks

Author

Listed:
  • Benjamin P. Charnay

    (Stanford University; 337 Campus Drive)

  • Yuxuan Chen

    (Stanford University; 337 Campus Drive)

  • Jason W. Misleh

    (Stanford University; 337 Campus Drive)

  • J. Gage Wright

    (Stanford University; 337 Campus Drive)

  • Rishi G. Agarwal

    (Stanford University; 337 Campus Drive)

  • Ethan R. Sauvé

    (Massachusetts Institute of Technology; 77 Massachusetts Ave)

  • Wei Lun Toh

    (Massachusetts Institute of Technology; 77 Massachusetts Ave)

  • Yogesh Surendranath

    (Massachusetts Institute of Technology; 77 Massachusetts Ave)

  • Matthew W. Kanan

    (Stanford University; 337 Campus Drive)

Abstract

Electrochemical production of acid and base from water enables their use as regenerable reagents in closed-loop processes, with attractive applications including CO2 capture or mineralization and low-temperature production of Ca(OH)2. Conventional systems utilize ion exchange membranes (IEMs) to inhibit H+/OH– recombination, which leads to high resistive losses that compromise energy efficiency and poor tolerance for polyvalent metal ions that complicates applications involving mineral resources. Here we use ion transport modeling to guide the design of a system that uses a simple porous separator instead of IEMs. Using H2 redox reactions for H+/OH– production, we demonstrate acid-base production at useful concentrations in the presence of polyvalent impurities with lower energy demand and higher current density than reported IEM-based systems. Cells can be stacked by combining H2 electrodes into a bipolar gas diffusion electrode, which recirculates H2 with near-unity efficiency. We show that the cell outputs extract alkalinity from olivine and serpentine as Mg(OH)2 and Mg3Si2O6(OH)2, which remove CO2 from ambient air to form Mg carbonates. These studies establish the principles for membrane-free electrochemical acid-base production, enabling closed-loop resource recovery and material processing powered by renewable electricity.

Suggested Citation

  • Benjamin P. Charnay & Yuxuan Chen & Jason W. Misleh & J. Gage Wright & Rishi G. Agarwal & Ethan R. Sauvé & Wei Lun Toh & Yogesh Surendranath & Matthew W. Kanan, 2025. "Membrane-free electrochemical production of acid and base solutions capable of processing ultramafic rocks," Nature Communications, Nature, vol. 16(1), pages 1-12, December.
    • Handle: RePEc:nat:natcom:v:16:y:2025:i:1:d:10.1038_s41467-025-64595-5
    DOI: 10.1038/s41467-025-64595-5
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    References listed on IDEAS

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    1. Ibadillah A. Digdaya & Ian Sullivan & Meng Lin & Lihao Han & Wen-Hui Cheng & Harry A. Atwater & Chengxiang Xiang, 2020. "A direct coupled electrochemical system for capture and conversion of CO2 from oceanwater," Nature Communications, Nature, vol. 11(1), pages 1-10, December.
    2. Sarah Deutz & André Bardow, 2021. "Life-cycle assessment of an industrial direct air capture process based on temperature–vacuum swing adsorption," Nature Energy, Nature, vol. 6(2), pages 203-213, February.
    3. Shijian Jin & Min Wu & Yan Jing & Roy G. Gordon & Michael J. Aziz, 2022. "Low energy carbon capture via electrochemically induced pH swing with electrochemical rebalancing," Nature Communications, Nature, vol. 13(1), pages 1-11, December.
    4. Yuxuan Chen & Matthew W. Kanan, 2025. "Thermal Ca2+/Mg2+ exchange reactions to synthesize CO2 removal materials," Nature, Nature, vol. 638(8052), pages 972-979, February.
    5. Peng Zhu & Zhen-Yu Wu & Ahmad Elgazzar & Changxin Dong & Tae-Ung Wi & Feng-Yang Chen & Yang Xia & Yuge Feng & Mohsen Shakouri & Jung Yoon (Timothy) Kim & Zhiwei Fang & T. Alan Hatton & Haotian Wang, 2023. "Continuous carbon capture in an electrochemical solid-electrolyte reactor," Nature, Nature, vol. 618(7967), pages 959-966, June.
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