Proton Selective Nanoporous Atomically Thin Graphene Membranes for Vanadium Redox Flow Batteries

Pavan Chaturvedi; Peifu Cheng; Saban M. Hus; Matthew Coupin; An Ping Li; Jamie Warner; Michael S.H. Boutilier; Piran R. Kidambi

doi:10.1002/adma.202510609

Proton Selective Nanoporous Atomically Thin Graphene Membranes for Vanadium Redox Flow Batteries

Pavan Chaturvedi
, Peifu Cheng
, Saban M. Hus
, Matthew Coupin
, An Ping Li
, Jamie Warner
, Michael S.H. Boutilier
, Piran R. Kidambi

Scanning Tunneling Microscopy Group

Research output: Contribution to journal › Article › peer-review

1 Scopus citations

Abstract

Angstrom-scale proton-selective pores in atomically thin 2D materials present fundamentally new opportunities for advancing proton exchange membranes (PEMs). Vanadium Redox Flow Batteries (VRFBs) for grid-scale energy storage require PEMs with high areal proton conductance (>1 S cm⁻²) and minimal vanadium ion (VO²⁺) crossover. However, state-of-the-art Nafion 212 membranes (N212 ≈50 µm thick), suffer from persistent VO²⁺ crossover reducing performance and efficiency. Here, a layered PEM is demonstrated, comprising monolayer CVD graphene with Angstrom-scale proton-selective pores introduced via Ar plasma, integrated with an ultra-thin ≈300 nm polybenzimidazole (PBI) layer and sandwiched between two Nafion 211 (25 µm thick) layers. The layered architecture facilitates scalable membrane fabrication by mitigating defects while processing and facile stacking of graphene layers allows stochastic non-selective defect isolation enabling exceptionally low VO²⁺ crossover (selectivity (H⁺ areal conductance / VO²⁺ permeability) ≈6709 × 10⁶ S min cm⁻⁴), with proton conductance >8 S cm⁻². Systematic transport experiments supported by resistance-based transport modelling elucidate the role of defect size, defect isolation, and sealing, as well as layering/stacking, to enable orders of magnitude (>671× over N212) improvements in selectivity, along with areal proton conductance >8 S cm⁻². This work highlights the potential of atomic-scale proton-selective defect engineering in 2D materials, in conjunction with facile stacking and layering of materials as strategies for scalable, high-performance advances in PEMs for energy, electrochemical, and separation applications beyond VRFBs.

Original language	English
Article number	e10609
Journal	Advanced Materials
Volume	38
Issue number	5
DOIs	https://doi.org/10.1002/adma.202510609
State	Published - Jan 22 2026

Funding

This work was supported in part by NSF CAREER award #1944134 and in part by DOE Early Career Research Program award #DE‐SC002291. STM was supported by the Center for Nanophase Materials Sciences (CNMS), which is a US Department of Energy, Office of Science User Facility at Oak Ridge National Laboratory. The authors acknowledge General Graphene Corporation LLC for providing CVD graphene on Cu foil. The authors also acknnowledge Prof. Bellan's lab at Vanderbilt University for assisting with mechanical testing during the review process. This work was supported in part by NSF CAREER award #1944134 and in part by DOE Early Career Research Program award #DE-SC002291. STM was supported by the Center for Nanophase Materials Sciences (CNMS), which is a US Department of Energy, Office of Science User Facility at Oak Ridge National Laboratory. The authors acknowledge General Graphene Corporation LLC for providing CVD graphene on Cu foil. The authors also acknnowledge Prof. Bellan's lab at Vanderbilt University for assisting with mechanical testing during the review process.

Keywords

CVD graphene
angstrom-scale pores
atomically thin membranes
poly-benzimidazole (PBI)
proton exchange membranes (PEMs)
vanadium redox flow batteries (VRFBs)

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10.1002/adma.202510609

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title = "Proton Selective Nanoporous Atomically Thin Graphene Membranes for Vanadium Redox Flow Batteries",

abstract = "Angstrom-scale proton-selective pores in atomically thin 2D materials present fundamentally new opportunities for advancing proton exchange membranes (PEMs). Vanadium Redox Flow Batteries (VRFBs) for grid-scale energy storage require PEMs with high areal proton conductance (>1 S cm−2) and minimal vanadium ion (VO2+) crossover. However, state-of-the-art Nafion 212 membranes (N212 ≈50 µm thick), suffer from persistent VO2+ crossover reducing performance and efficiency. Here, a layered PEM is demonstrated, comprising monolayer CVD graphene with Angstrom-scale proton-selective pores introduced via Ar plasma, integrated with an ultra-thin ≈300 nm polybenzimidazole (PBI) layer and sandwiched between two Nafion 211 (25 µm thick) layers. The layered architecture facilitates scalable membrane fabrication by mitigating defects while processing and facile stacking of graphene layers allows stochastic non-selective defect isolation enabling exceptionally low VO2+ crossover (selectivity (H+ areal conductance / VO2+ permeability) ≈6709 × 106 S min cm−4), with proton conductance >8 S cm−2. Systematic transport experiments supported by resistance-based transport modelling elucidate the role of defect size, defect isolation, and sealing, as well as layering/stacking, to enable orders of magnitude (>671× over N212) improvements in selectivity, along with areal proton conductance >8 S cm−2. This work highlights the potential of atomic-scale proton-selective defect engineering in 2D materials, in conjunction with facile stacking and layering of materials as strategies for scalable, high-performance advances in PEMs for energy, electrochemical, and separation applications beyond VRFBs.",

keywords = "CVD graphene, angstrom-scale pores, atomically thin membranes, poly-benzimidazole (PBI), proton exchange membranes (PEMs), vanadium redox flow batteries (VRFBs)",

author = "Pavan Chaturvedi and Peifu Cheng and Hus, \{Saban M.\} and Matthew Coupin and Li, \{An Ping\} and Jamie Warner and Boutilier, \{Michael S.H.\} and Kidambi, \{Piran R.\}",

note = "Publisher Copyright: {\textcopyright} 2025 The Author(s). Advanced Materials published by Wiley-VCH GmbH.",

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T1 - Proton Selective Nanoporous Atomically Thin Graphene Membranes for Vanadium Redox Flow Batteries

AU - Chaturvedi, Pavan

AU - Cheng, Peifu

AU - Hus, Saban M.

AU - Coupin, Matthew

AU - Li, An Ping

AU - Warner, Jamie

AU - Boutilier, Michael S.H.

AU - Kidambi, Piran R.

PY - 2026/1/22

Y1 - 2026/1/22

N2 - Angstrom-scale proton-selective pores in atomically thin 2D materials present fundamentally new opportunities for advancing proton exchange membranes (PEMs). Vanadium Redox Flow Batteries (VRFBs) for grid-scale energy storage require PEMs with high areal proton conductance (>1 S cm−2) and minimal vanadium ion (VO2+) crossover. However, state-of-the-art Nafion 212 membranes (N212 ≈50 µm thick), suffer from persistent VO2+ crossover reducing performance and efficiency. Here, a layered PEM is demonstrated, comprising monolayer CVD graphene with Angstrom-scale proton-selective pores introduced via Ar plasma, integrated with an ultra-thin ≈300 nm polybenzimidazole (PBI) layer and sandwiched between two Nafion 211 (25 µm thick) layers. The layered architecture facilitates scalable membrane fabrication by mitigating defects while processing and facile stacking of graphene layers allows stochastic non-selective defect isolation enabling exceptionally low VO2+ crossover (selectivity (H+ areal conductance / VO2+ permeability) ≈6709 × 106 S min cm−4), with proton conductance >8 S cm−2. Systematic transport experiments supported by resistance-based transport modelling elucidate the role of defect size, defect isolation, and sealing, as well as layering/stacking, to enable orders of magnitude (>671× over N212) improvements in selectivity, along with areal proton conductance >8 S cm−2. This work highlights the potential of atomic-scale proton-selective defect engineering in 2D materials, in conjunction with facile stacking and layering of materials as strategies for scalable, high-performance advances in PEMs for energy, electrochemical, and separation applications beyond VRFBs.

AB - Angstrom-scale proton-selective pores in atomically thin 2D materials present fundamentally new opportunities for advancing proton exchange membranes (PEMs). Vanadium Redox Flow Batteries (VRFBs) for grid-scale energy storage require PEMs with high areal proton conductance (>1 S cm−2) and minimal vanadium ion (VO2+) crossover. However, state-of-the-art Nafion 212 membranes (N212 ≈50 µm thick), suffer from persistent VO2+ crossover reducing performance and efficiency. Here, a layered PEM is demonstrated, comprising monolayer CVD graphene with Angstrom-scale proton-selective pores introduced via Ar plasma, integrated with an ultra-thin ≈300 nm polybenzimidazole (PBI) layer and sandwiched between two Nafion 211 (25 µm thick) layers. The layered architecture facilitates scalable membrane fabrication by mitigating defects while processing and facile stacking of graphene layers allows stochastic non-selective defect isolation enabling exceptionally low VO2+ crossover (selectivity (H+ areal conductance / VO2+ permeability) ≈6709 × 106 S min cm−4), with proton conductance >8 S cm−2. Systematic transport experiments supported by resistance-based transport modelling elucidate the role of defect size, defect isolation, and sealing, as well as layering/stacking, to enable orders of magnitude (>671× over N212) improvements in selectivity, along with areal proton conductance >8 S cm−2. This work highlights the potential of atomic-scale proton-selective defect engineering in 2D materials, in conjunction with facile stacking and layering of materials as strategies for scalable, high-performance advances in PEMs for energy, electrochemical, and separation applications beyond VRFBs.

KW - CVD graphene

KW - angstrom-scale pores

KW - atomically thin membranes

KW - poly-benzimidazole (PBI)

KW - proton exchange membranes (PEMs)

KW - vanadium redox flow batteries (VRFBs)

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DO - 10.1002/adma.202510609

M3 - Article

AN - SCOPUS:105021605113

SN - 0935-9648

VL - 38

JO - Advanced Materials

JF - Advanced Materials

IS - 5

M1 - e10609

ER -

Proton Selective Nanoporous Atomically Thin Graphene Membranes for Vanadium Redox Flow Batteries

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