Microstructure-dependent gas adsorption: Accurate predictions of methane uptake in nanoporous carbons

Yungok Ihm; Valentino R. Cooper; Nidia C. Gallego; Cristian I. Contescu; James R. Morris

doi:10.1021/ct400875n

Microstructure-dependent gas adsorption: Accurate predictions of methane uptake in nanoporous carbons

Yungok Ihm
, Valentino R. Cooper
, Nidia C. Gallego
, Cristian I. Contescu
, James R. Morris

Research output: Contribution to journal › Article › peer-review

19 Scopus citations

Abstract

We present a framework for rapidly predicting gas adsorption properties based on van der Waals density functional calculations and thermodynamic modeling. Utilizing this model and experimentally determined pore size distributions, we are able to accurately predict uptakes in five activated carbon materials without empirical potentials or lengthy simulations. Our results demonstrate that materials with smaller pores and higher heats of adsorption can still have poor adsorption characteristics due to relatively low densities of highly adsorbent pores.

Original language	English
Pages (from-to)	1-4
Number of pages	4
Journal	Journal of Chemical Theory and Computation
Volume	10
Issue number	1
DOIs	https://doi.org/10.1021/ct400875n
State	Published - Jan 14 2014

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10.1021/ct400875n

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abstract = "We present a framework for rapidly predicting gas adsorption properties based on van der Waals density functional calculations and thermodynamic modeling. Utilizing this model and experimentally determined pore size distributions, we are able to accurately predict uptakes in five activated carbon materials without empirical potentials or lengthy simulations. Our results demonstrate that materials with smaller pores and higher heats of adsorption can still have poor adsorption characteristics due to relatively low densities of highly adsorbent pores.",

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T2 - Accurate predictions of methane uptake in nanoporous carbons

AU - Ihm, Yungok

AU - Cooper, Valentino R.

AU - Gallego, Nidia C.

AU - Contescu, Cristian I.

AU - Morris, James R.

PY - 2014/1/14

Y1 - 2014/1/14

N2 - We present a framework for rapidly predicting gas adsorption properties based on van der Waals density functional calculations and thermodynamic modeling. Utilizing this model and experimentally determined pore size distributions, we are able to accurately predict uptakes in five activated carbon materials without empirical potentials or lengthy simulations. Our results demonstrate that materials with smaller pores and higher heats of adsorption can still have poor adsorption characteristics due to relatively low densities of highly adsorbent pores.

AB - We present a framework for rapidly predicting gas adsorption properties based on van der Waals density functional calculations and thermodynamic modeling. Utilizing this model and experimentally determined pore size distributions, we are able to accurately predict uptakes in five activated carbon materials without empirical potentials or lengthy simulations. Our results demonstrate that materials with smaller pores and higher heats of adsorption can still have poor adsorption characteristics due to relatively low densities of highly adsorbent pores.

UR - https://www.scopus.com/pages/publications/84892596965

U2 - 10.1021/ct400875n

DO - 10.1021/ct400875n

M3 - Article

AN - SCOPUS:84892596965

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JO - Journal of Chemical Theory and Computation

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Microstructure-dependent gas adsorption: Accurate predictions of methane uptake in nanoporous carbons

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