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Differences in water and vapor transport through angstrom-scale pores in atomically thin membranes

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Listed:
  • Peifu Cheng

    (Vanderbilt University)

  • Francesco Fornasiero

    (Lawrence Livermore National Laboratory)

  • Melinda L. Jue

    (Lawrence Livermore National Laboratory)

  • Wonhee Ko

    (Oak Ridge National Laboratory)

  • An-Ping Li

    (Oak Ridge National Laboratory)

  • Juan Carlos Idrobo

    (Oak Ridge National Laboratory
    University of Washington)

  • Michael S. H. Boutilier

    (Western University)

  • Piran R. Kidambi

    (Vanderbilt University
    Vanderbilt University
    Vanderbilt University)

Abstract

The transport of water through nanoscale capillaries/pores plays a prominent role in biology, ionic/molecular separations, water treatment and protective applications. However, the mechanisms of water and vapor transport through nanoscale confinements remain to be fully understood. Angstrom-scale pores (~2.8–6.6 Å) introduced into the atomically thin graphene lattice represent ideal model systems to probe water transport at the molecular-length scale with short pores (aspect ratio ~1–1.9) i.e., pore diameters approach the pore length (~3.4 Å) at the theoretical limit of material thickness. Here, we report on orders of magnitude differences (~80×) between transport of water vapor (~44.2–52.4 g m−2 day−1 Pa−1) and liquid water (0.6–2 g m−2 day−1 Pa−1) through nanopores (~2.8–6.6 Å in diameter) in monolayer graphene and rationalize this difference via a flow resistance model in which liquid water permeation occurs near the continuum regime whereas water vapor transport occurs in the free molecular flow regime. We demonstrate centimeter-scale atomically thin graphene membranes with up to an order of magnitude higher water vapor transport rate (~5.4–6.1 × 104 g m−2 day−1) than most commercially available ultra-breathable protective materials while effectively blocking even sub-nanometer (>0.66 nm) model ions/molecules.

Suggested Citation

  • Peifu Cheng & Francesco Fornasiero & Melinda L. Jue & Wonhee Ko & An-Ping Li & Juan Carlos Idrobo & Michael S. H. Boutilier & Piran R. Kidambi, 2022. "Differences in water and vapor transport through angstrom-scale pores in atomically thin membranes," Nature Communications, Nature, vol. 13(1), pages 1-12, December.
    • Handle: RePEc:nat:natcom:v:13:y:2022:i:1:d:10.1038_s41467-022-34172-1
    DOI: 10.1038/s41467-022-34172-1
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    References listed on IDEAS

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    1. B. Radha & A. Esfandiar & F. C. Wang & A. P. Rooney & K. Gopinadhan & A. Keerthi & A. Mishchenko & A. Janardanan & P. Blake & L. Fumagalli & M. Lozada-Hidalgo & S. Garaj & S. J. Haigh & I. V. Grigorie, 2016. "Molecular transport through capillaries made with atomic-scale precision," Nature, Nature, vol. 538(7624), pages 222-225, October.
    2. Ashok Keerthi & Solleti Goutham & Yi You & Pawin Iamprasertkun & Robert A. W. Dryfe & Andre K. Geim & Boya Radha, 2021. "Water friction in nanofluidic channels made from two-dimensional crystals," Nature Communications, Nature, vol. 12(1), pages 1-8, December.
    3. Qian Yang & P. Z. Sun & L. Fumagalli & Y. V. Stebunov & S. J. Haigh & Z. W. Zhou & I. V. Grigorieva & F. C. Wang & A. K. Geim, 2020. "Capillary condensation under atomic-scale confinement," Nature, Nature, vol. 588(7837), pages 250-253, December.
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    1. Qian Zhang & Bo Gao & Ling Zhang & Xiaopeng Liu & Jixiang Cui & Yijun Cao & Hongbo Zeng & Qun Xu & Xinwei Cui & Lei Jiang, 2023. "Anomalous water molecular gating from atomic-scale graphene capillaries for precise and ultrafast molecular sieving," Nature Communications, Nature, vol. 14(1), pages 1-10, December.

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