Design of 2D materials for selective adsorption: A comparison between Monte Carlo simulations and direct numerical integration

Huan Xiang; Xiaolei Fan; Flor R. Siperstein

doi:10.1039/c8me00024g

Design of 2D materials for selective adsorption: A comparison between Monte Carlo simulations and direct numerical integration

Huan Xiang, Xiaolei Fan, Flor R. Siperstein

Research output: Journal Publication › Article › peer-review

5 Citations (Scopus)

Abstract

Understanding the behaviour of fluids in confinement is essential to predict adsorption selectivity and develop adsorbents that can address challenging separations, such as ethane/ethylene mixtures. In this work we show that adsorption selectivity for an ethane/ethylene mixture can be predicted from direct numerical integration of the solid-fluid interaction potential because fluid-fluid interactions are negligible when compared to solid-fluid interactions, and adsorption sites are indistinguishable in pure component and mixture simulations. We present a comprehensive analysis of the density and orientation distributions in the pores as a function of pore size and pressure, providing tools that can be used for the design of 2D materials for the selective adsorption of gases.

Original language	English
Pages (from-to)	636-644
Number of pages	9
Journal	Molecular Systems Design and Engineering
Volume	3
Issue number	4
DOIs	https://doi.org/10.1039/c8me00024g
Publication status	Published - Aug 2018
Externally published	Yes

ASJC Scopus subject areas

Chemistry (miscellaneous)
Chemical Engineering (miscellaneous)
Biomedical Engineering
Energy Engineering and Power Technology
Process Chemistry and Technology
Industrial and Manufacturing Engineering
Materials Chemistry

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10.1039/c8me00024g

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abstract = "Understanding the behaviour of fluids in confinement is essential to predict adsorption selectivity and develop adsorbents that can address challenging separations, such as ethane/ethylene mixtures. In this work we show that adsorption selectivity for an ethane/ethylene mixture can be predicted from direct numerical integration of the solid-fluid interaction potential because fluid-fluid interactions are negligible when compared to solid-fluid interactions, and adsorption sites are indistinguishable in pure component and mixture simulations. We present a comprehensive analysis of the density and orientation distributions in the pores as a function of pore size and pressure, providing tools that can be used for the design of 2D materials for the selective adsorption of gases.",

author = "Huan Xiang and Xiaolei Fan and Siperstein, {Flor R.}",

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AU - Xiang, Huan

AU - Fan, Xiaolei

AU - Siperstein, Flor R.

PY - 2018/8

Y1 - 2018/8

N2 - Understanding the behaviour of fluids in confinement is essential to predict adsorption selectivity and develop adsorbents that can address challenging separations, such as ethane/ethylene mixtures. In this work we show that adsorption selectivity for an ethane/ethylene mixture can be predicted from direct numerical integration of the solid-fluid interaction potential because fluid-fluid interactions are negligible when compared to solid-fluid interactions, and adsorption sites are indistinguishable in pure component and mixture simulations. We present a comprehensive analysis of the density and orientation distributions in the pores as a function of pore size and pressure, providing tools that can be used for the design of 2D materials for the selective adsorption of gases.

AB - Understanding the behaviour of fluids in confinement is essential to predict adsorption selectivity and develop adsorbents that can address challenging separations, such as ethane/ethylene mixtures. In this work we show that adsorption selectivity for an ethane/ethylene mixture can be predicted from direct numerical integration of the solid-fluid interaction potential because fluid-fluid interactions are negligible when compared to solid-fluid interactions, and adsorption sites are indistinguishable in pure component and mixture simulations. We present a comprehensive analysis of the density and orientation distributions in the pores as a function of pore size and pressure, providing tools that can be used for the design of 2D materials for the selective adsorption of gases.

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Design of 2D materials for selective adsorption: A comparison between Monte Carlo simulations and direct numerical integration

Abstract

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