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Proton and Li-Ion Permeation through Graphene with Eight-Atom-Ring Defects

E. Griffin, Lucas Mogg, Guang‐Ping Hao, K. Gopinadhan, Cihan Bacaksız, Guillermo López‐Polín, Tianya Zhou, Victor Guarochico, Junhao Cai, Christof Neumann, Andreas Winter, Michael J. Mohn, Jong Hak Lee, Junhao Lin, Ute Kaiser, I. V. Grigorieva, Kazu Suenaga, Barbaros Özyilmaz, Huimin Cheng, Wencai Ren, Andrey Turchanin, F. M. Peeters, A. K. Geǐm, M. Lozada-Hidalgo

2020ACS Nano96 citationsDOIOpen Access PDF

Abstract

Defect-free graphene is impermeable to gases and liquids but highly permeable to thermal protons. Atomic-scale defects such as vacancies, grain boundaries, and Stone-Wales defects are predicted to enhance graphene's proton permeability and may even allow small ions through, whereas larger species such as gas molecules should remain blocked. These expectations have so far remained untested in experiment. Here, we show that atomically thin carbon films with a high density of atomic-scale defects continue blocking all molecular transport, but their proton permeability becomes ∼1000 times higher than that of defect-free graphene. Lithium ions can also permeate through such disordered graphene. The enhanced proton and ion permeability is attributed to a high density of eight-carbon-atom rings. The latter pose approximately twice lower energy barriers for incoming protons compared to that of the six-atom rings of graphene and a relatively low barrier of ∼0.6 eV for Li ions. Our findings suggest that disordered graphene could be of interest as membranes and protective barriers in various Li-ion and hydrogen technologies.

Topics & Concepts

GrapheneMaterials scienceIonProtonPermeationChemical physicsHydrogenGrain boundaryAtom (system on chip)Carbon fibersMembraneNanotechnologyChemistryMicrostructureOrganic chemistryComposite materialComposite numberEmbedded systemQuantum mechanicsPhysicsBiochemistryComputer scienceAdvancements in Battery MaterialsGraphene research and applicationsAdvanced Battery Technologies Research
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