Self-diffusion coefficients of methane/n-hexane mixtures at high pressures: An evaluation of the finite-size effect and a comparison of force fields

Thiago J.P. dos Santos; Charlles R.A. Abreu; Bruno A.C. Horta; Frederico W. Tavares

doi:10.1016/j.supflu.2019.104639

Self-diffusion coefficients of methane/n-hexane mixtures at high pressures: An evaluation of the finite-size effect and a comparison of force fields

Thiago J.P. dos Santos, Charlles R.A. Abreu, Bruno A.C. Horta, Frederico W. Tavares

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

18 Scopus citations

Abstract

Mass transport coefficients play an important role in process design and in compositional grading of oil reservoirs. As experimental measurements of these properties can be costly and hazardous, Molecular Dynamics simulations emerge as an alternative approach. In this work, we used Molecular Dynamics to calculate the self-diffusion coefficients of methane/n-hexane mixtures at different conditions, in both liquid and supercritical phases. We evaluated how the finite box size and the choice of the force field affect the calculated properties at high pressures. Results show a strong dependency between self-diffusion and the simulation box size. The Yeh-Hummer analytical correction [J. Phys. Chem. B, 108, 15873 (2004)] can attenuate this effect, but sometimes makes the results depart from experimental data due to issues concerning the force fields. We have also found that different all-atom and united-atom models can produce biased results due to caging effects and to different dihedral configurations of the n-alkane.

Original language	English
Article number	104639
Journal	Journal of Supercritical Fluids
Volume	155
DOIs	https://doi.org/10.1016/j.supflu.2019.104639
State	Published - Jan 2020
Externally published	Yes

Funding

We are grateful for the financial support provided by CAPES (finance code 001), by Petrobras (project code CENPES 20934-6), by CNPq and by FAPERJ. We are also grateful for the computational resources provided by the Lobo Carneiro Supercomputer Facility at the Federal University of Rio de Janeiro, Brazil. We are grateful for the financial support provided by CAPES (finance code 001), by Petrobras (project code CENPES 20934-6), by CNPq and by FAPERJ . We are also grateful for the computational resources provided by the Lobo Carneiro Supercomputer Facility at the Federal University of Rio de Janeiro, Brazil.

Keywords

Force fields
Molecular dynamics simulations
N-alkanes
Self-diffusion

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10.1016/j.supflu.2019.104639

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title = "Self-diffusion coefficients of methane/n-hexane mixtures at high pressures: An evaluation of the finite-size effect and a comparison of force fields",

abstract = "Mass transport coefficients play an important role in process design and in compositional grading of oil reservoirs. As experimental measurements of these properties can be costly and hazardous, Molecular Dynamics simulations emerge as an alternative approach. In this work, we used Molecular Dynamics to calculate the self-diffusion coefficients of methane/n-hexane mixtures at different conditions, in both liquid and supercritical phases. We evaluated how the finite box size and the choice of the force field affect the calculated properties at high pressures. Results show a strong dependency between self-diffusion and the simulation box size. The Yeh-Hummer analytical correction [J. Phys. Chem. B, 108, 15873 (2004)] can attenuate this effect, but sometimes makes the results depart from experimental data due to issues concerning the force fields. We have also found that different all-atom and united-atom models can produce biased results due to caging effects and to different dihedral configurations of the n-alkane.",

keywords = "Force fields, Molecular dynamics simulations, N-alkanes, Self-diffusion",

author = "\{dos Santos\}, \{Thiago J.P.\} and Abreu, \{Charlles R.A.\} and Horta, \{Bruno A.C.\} and Tavares, \{Frederico W.\}",

note = "Publisher Copyright: {\textcopyright} 2019 Elsevier B.V.",

year = "2020",

month = jan,

doi = "10.1016/j.supflu.2019.104639",

language = "English",

volume = "155",

journal = "Journal of Supercritical Fluids",

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T1 - Self-diffusion coefficients of methane/n-hexane mixtures at high pressures

T2 - An evaluation of the finite-size effect and a comparison of force fields

AU - dos Santos, Thiago J.P.

AU - Abreu, Charlles R.A.

AU - Horta, Bruno A.C.

AU - Tavares, Frederico W.

PY - 2020/1

Y1 - 2020/1

N2 - Mass transport coefficients play an important role in process design and in compositional grading of oil reservoirs. As experimental measurements of these properties can be costly and hazardous, Molecular Dynamics simulations emerge as an alternative approach. In this work, we used Molecular Dynamics to calculate the self-diffusion coefficients of methane/n-hexane mixtures at different conditions, in both liquid and supercritical phases. We evaluated how the finite box size and the choice of the force field affect the calculated properties at high pressures. Results show a strong dependency between self-diffusion and the simulation box size. The Yeh-Hummer analytical correction [J. Phys. Chem. B, 108, 15873 (2004)] can attenuate this effect, but sometimes makes the results depart from experimental data due to issues concerning the force fields. We have also found that different all-atom and united-atom models can produce biased results due to caging effects and to different dihedral configurations of the n-alkane.

AB - Mass transport coefficients play an important role in process design and in compositional grading of oil reservoirs. As experimental measurements of these properties can be costly and hazardous, Molecular Dynamics simulations emerge as an alternative approach. In this work, we used Molecular Dynamics to calculate the self-diffusion coefficients of methane/n-hexane mixtures at different conditions, in both liquid and supercritical phases. We evaluated how the finite box size and the choice of the force field affect the calculated properties at high pressures. Results show a strong dependency between self-diffusion and the simulation box size. The Yeh-Hummer analytical correction [J. Phys. Chem. B, 108, 15873 (2004)] can attenuate this effect, but sometimes makes the results depart from experimental data due to issues concerning the force fields. We have also found that different all-atom and united-atom models can produce biased results due to caging effects and to different dihedral configurations of the n-alkane.

KW - Force fields

KW - Molecular dynamics simulations

KW - N-alkanes

KW - Self-diffusion

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DO - 10.1016/j.supflu.2019.104639

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VL - 155

JO - Journal of Supercritical Fluids

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ER -

Self-diffusion coefficients of methane/n-hexane mixtures at high pressures: An evaluation of the finite-size effect and a comparison of force fields

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Keywords

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