Subnanometer Vacancy Defects Introduced on Graphene by Oxygen Gas

Yamada, Yoshio; Murota, Kazumasa; Fujita, Ryo; Kim, Jungpil; Watanabe, A.; Nakamura, Masashi; Sato, Satoshi; Hata, Kenji; Ercius, Peter; Ciston, Jim; Cheng, Song; Kim, Kwanpyo; Regan, William; Gannett, Will; Zettl, A.

doi:10.1021/ja4117268

Cited by 127 publications

(81 citation statements)

References 41 publications

(79 reference statements)

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“…The experimental synthesis of nanoporous graphene has become a subject of tremendous interest [101][102][103]. Achieving highly uniform, subnanometer pores in large-scale sheets of graphene is arguably the most important outstanding goal for the field of NPG membranes, and O'Hern et al have recently produced pores with diameters of (0.40 ± 0.24) nm and densities exceeding 1 × 10 12 cm −2 , while retaining structural integrity of the graphene [8].…”

Section: Discussion and Outlookmentioning

confidence: 99%

Nanoporous graphene as a reverse osmosis membrane: Recent insights from theory and simulation

2015

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We review recent progress in the computational study of graphene as an RO membrane.• We introduce graphene and current knowledge about its mass transport properties. • We examine six key mechanisms that govern salt rejection in graphene. • Molecular dynamics have played a dominant role in the study of graphene membranes. • We suggest a greater role for quantumlevel simulations and macroscale computation.In this review, we examine the potential and the challenges of designing an ultrathin reverse osmosis (RO) membrane from graphene, focusing on the role of computational methods in designing, understanding, and optimizing the relationship between atomic structure and RO performance. In recent years, graphene has emerged as a promising material for improving the performance of RO. Beginning at the atomic scale and extending to the RO plant scale, we review applications of computational research that have explored the structure, properties and potential performance of nanoporous graphene in the context of RO desalination.

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Section: Discussion and Outlookmentioning

confidence: 99%

Nanoporous graphene as a reverse osmosis membrane: Recent insights from theory and simulation

2015

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“…In particular, by opportune thermal treatments in controlled atmosphere it has been shown that Gr and also other 2D materials of interest can be doped, but some drawbacks arising from the environment can come including stress effects . In addition, it has been shown that for metal substrate Gr etching could be started as well as in the case of harsh thermal treatments of Gr on dielectric substrates . In this context, a role of molecular water has been evidenced and its interaction with substrate is of particular concern in activating or contrasting the doping .…”

Section: Introductionmentioning

confidence: 99%

Graphene‐SiO₂ Interaction from Composites to Doping

Armano

Buscarino

Cannas

et al. 2019

Physica Status Solidi (a)

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An overview of the interaction between monolayer graphene and SiO2 dielectric substrate is reported focusing on the effect this latter has on doping and strain induced by thermal treatments in controlled atmosphere. The disentanglement of strain and doping is highlighted and the comparison with another dielectric substrate of Al2O3 evidences the critical role that the substrate has in the electronic properties of graphene. The reported results pave the way for microelectronic devices based on graphene on dielectrics and for Fermi level tuning in composites of graphene and nanoparticles.

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“…Graphene and other two-dimensional materials offer a new class of ultrathin membranes that can have atomically defined nanopores with diameters approaching those of hydrated ions [1][2][3][4][5][6][7] . These nanopores have the smallest possible pore volumes of any ion channel, which, due to ionic dehydration 8 and electrokinetic effects 9 , places them in a novel transport regime and allows membranes to be created that combine selective ionic transport 10 with ultimate permeance [11][12][13] and could lead to separations 14,15 and sensing 16 applications.…”

mentioning

confidence: 99%

Heterogeneous sub-continuum ionic transport in statistically isolated graphene nanopores

et al. 2015

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Graphene and other two-dimensional materials offer a new class of ultrathin membranes that can have atomically defined nanopores with diameters approaching those of hydrated ions. These nanopores have the smallest possible pore volumes of any ion channel, which, due to ionic dehydration and electrokinetic effects, places them in a novel transport regime and allows membranes to be created that combine selective ionic transport with ultimate permeance and could lead to separations and sensing applications. However, experimental characterization and understanding of sub-continuum ionic transport in nanopores below 2 nm is limited. Here we show that isolated sub-2 nm pores in graphene exhibit, in contrast to larger pores, diverse transport behaviours consistent with ion transport over a free-energy barrier arising from ion dehydration and electrostatic interactions. Current-voltage measurements reveal that the conductance of graphene nanopores spans three orders of magnitude and that they display distinct linear, voltage-activated or rectified current-voltage characteristics and different cation-selectivity profiles. In rare cases, rapid, voltage-dependent stochastic switching is observed, consistent with the presence of a dissociable group in the pore vicinity. A modified Nernst-Planck model incorporating ion hydration and electrostatic effects quantitatively matches the observed behaviours.

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Subnanometer Vacancy Defects Introduced on Graphene by Oxygen Gas

Cited by 127 publications

References 41 publications

Nanoporous graphene as a reverse osmosis membrane: Recent insights from theory and simulation

Nanoporous graphene as a reverse osmosis membrane: Recent insights from theory and simulation

Graphene‐SiO₂ Interaction from Composites to Doping

Heterogeneous sub-continuum ionic transport in statistically isolated graphene nanopores

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Subnanometer Vacancy Defects Introduced on Graphene by Oxygen Gas

Cited by 127 publications

References 41 publications

Nanoporous graphene as a reverse osmosis membrane: Recent insights from theory and simulation

Nanoporous graphene as a reverse osmosis membrane: Recent insights from theory and simulation

Graphene‐SiO2 Interaction from Composites to Doping

Heterogeneous sub-continuum ionic transport in statistically isolated graphene nanopores

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Product

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Graphene‐SiO₂ Interaction from Composites to Doping