Modeling and simulations on CO2 storage using graphene

Yung Tsang Chen; Yue Chan

doi:10.4028/www.scientific.net/AMR.1079-1080.95

Modeling and simulations on CO₂ storage using graphene

Yung Tsang Chen, Yue Chan

Department of Civil Engineering

Research output: Journal Publication › Article › peer-review

Abstract

In this paper, we adopt boththe Lennard-Jones potential and the mean field theory to determine themolecular interactions between carbon dioxide and the double layered graphenes.In addition, we employ a modified van der Waals equation which takes into accountthe multi-scale effect in the absorption regime todeduce the gravimetric uptakeof carbon dioxide between graphene sheets. We show that the full absorptionoccurs at rather low external pressure at low temperatures while this happensat roughly 0.2bar at room temperature. The current methodology has the merit ofrapid computational times and producing deductive results in comparison to theusual MD simulations.For graphene sheets of a separation of 10 Å, the maximumgravimetric uptake could reach 13.3 wt.%.

Original language	English
Pages (from-to)	95-98
Number of pages	4
Journal	Advanced Materials Research
Volume	1079-1080
DOIs	https://doi.org/10.4028/www.scientific.net/AMR.1079-1080.95 https://doi.org/10.4028/www.scientific.net/AMR.1079-1080
Publication status	Published - Dec 2014

Keywords

CO2
Graphene
Lennard-Jones Potential
Mean Field Theory
Modeling
Simulation

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Cite this

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title = "Modeling and simulations on CO2 storage using graphene",

abstract = "In this paper, we adopt boththe Lennard-Jones potential and the mean field theory to determine themolecular interactions between carbon dioxide and the double layered graphenes.In addition, we employ a modified van der Waals equation which takes into accountthe multi-scale effect in the absorption regime todeduce the gravimetric uptakeof carbon dioxide between graphene sheets. We show that the full absorptionoccurs at rather low external pressure at low temperatures while this happensat roughly 0.2bar at room temperature. The current methodology has the merit ofrapid computational times and producing deductive results in comparison to theusual MD simulations.For graphene sheets of a separation of 10 {\AA}, the maximumgravimetric uptake could reach 13.3 wt.%.",

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AB - In this paper, we adopt boththe Lennard-Jones potential and the mean field theory to determine themolecular interactions between carbon dioxide and the double layered graphenes.In addition, we employ a modified van der Waals equation which takes into accountthe multi-scale effect in the absorption regime todeduce the gravimetric uptakeof carbon dioxide between graphene sheets. We show that the full absorptionoccurs at rather low external pressure at low temperatures while this happensat roughly 0.2bar at room temperature. The current methodology has the merit ofrapid computational times and producing deductive results in comparison to theusual MD simulations.For graphene sheets of a separation of 10 Å, the maximumgravimetric uptake could reach 13.3 wt.%.

KW - CO2

KW - Graphene

KW - Lennard-Jones Potential

KW - Mean Field Theory

KW - Modeling

KW - Simulation

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VL - 1079-1080

SP - 95

EP - 98

JO - Advanced Materials Research

JF - Advanced Materials Research

ER -

Modeling and simulations on CO2 storage using graphene

Abstract

Keywords

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Modeling and simulations on CO₂ storage using graphene