Tunable Hydrogen Separation in Porous Graphene Membrane: First-Principle and Molecular Dynamic Simulation

Tao, Yehan; Xue, Qingzhong; Liu, Zilong; Shan, Meixia; Ling, Cuicui; Wu, Tiantian; Li, Xiaofang

doi:10.1021/am4058887

Cited by 165 publications

(127 citation statements)

References 61 publications

(111 reference statements)

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“…Furthermore, strong improvements in the permeance of water, 45 water vapor and oxygen were achieved, as compared to current state- 46 of-the-art membranes [18]. However, the preparation of well-defined 47 pores for very high separation ratios is still challenging, as it requires 48 manipulation of graphene on an atomic scale and sometimes special 49 edge termination [12,19]. 50 Several groups investigated the properties of graphene as mem-51 brane for gas containment, and for corrosion inhibition with various 52 techniques; one example is a micro chamber etched into a SiO 2 53 substrate sealed with transferred graphene that was investigated with 54 atomic force microscopy (AFM) [9].…”

mentioning

confidence: 99%

Keeping argon under a graphene lid—Argon intercalation between graphene and nickel(111)

et al. 2016

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mentioning

confidence: 99%

Keeping argon under a graphene lid—Argon intercalation between graphene and nickel(111)

et al. 2016

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“…All molecular dynamic simulations were performed in an NVT enable to gases [7]. However, several studies have suggested that graphene has the potential to induce highly selective transport by generation of pore defects [8][9][10][11][12][13][14], in which atoms can be removed from the graphene lattice to create pores of specific size and geometry.…”

Section: Simulation Details and Methodsmentioning

confidence: 99%

Nanoporous graphene oxide membrane and its application in molecular sieving

Fatemi¹,

Arabieh²,

Sepehrian³

2015

Carbon letters

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Gas transport through graphene-derived membranes has gained much interest recently due to its promising potential in filtration and separation applications. In this work, we explore Kr-85 gas radionuclide sequestration from natural air in nanoporous graphene oxide membranes in which different sizes and geometries of pores were modeled on the graphene oxide sheet. This was done using atomistic simulations considering mean-squared displacement, diffusion coefficient, number of crossed species of gases through nanoporous graphene oxide, and flow through interlayer galleries. The results showed that the gas features have the densest adsorbed zone in nanoporous graphene oxide, compared with a graphene membrane, and that graphene oxide was more favorable than graphene for Kr separation. The aim of this paper is to show that for the well-defined pore size called P-7, it is possible to separate Kr-85 from a gas mixture containing Kr-85, O 2 and N 2 . The results would benefit the oil industry among others.

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“…Over the past five years, many computational studies have suggested that porous graphene-based membranes with desirable pore geometry could achieve an excellent permeance and selectivity [75,[91][92][93] [84]. In this study, the micrometer-scale membranes with sub-nanometer-sized pores were created via ultraviolet oxidative etching method, and the gas leak experiments indicated that the gas molecules with the kinetic diameter smaller than 3.4 Å were much more permeable than those with the kinetic diameter larger than 3.4 Å. Consequently, the H 2 /CO 2 ideal selectivity was about 1.7, which was likely due to the larger pore size than CO 2 and H 2 molecules.…”

Section: Carbon-based Membranesmentioning

confidence: 99%