The competition between H2O and CO2 adhesion at reservoir conditions: A DFT study of simple mineral models and the entropy, ZPE, dispersion and T,P variations

Theis Ivan Sølling; Akin Budi; K. Mogensen

doi:10.1016/j.comptc.2015.09.015

The competition between H₂O and CO₂ adhesion at reservoir conditions: A DFT study of simple mineral models and the entropy, ZPE, dispersion and T,P variations

Theis Ivan Sølling, Akin Budi, K. Mogensen

Kemisk Institut

4 Citationer (Scopus)

Abstract

Density functional theory was applied (B3LYP) to answer whether conditions exist where CO2 adhesion to three different lithologies becomes stronger than H2O adhesion. The answer is that it does not seem to be the case. This is taken to indicate that the reservoirs that we have represented by simple models are prone to CO2 storage. Moreover, we have obtained an overview of the effect of including entropy contributions and zero point vibrational energies in the calculation of the adhesion energies. The consequence of applying simple dispersion and solvent models are also addressed. The study is based around very simplified model systems of calcite, quartz and clays in order address the basic effects. Rather than attempting to obtain quantitative agreement we are observing the qualitative trends. When entropy, ZPE and a continuum model is included the result is smaller binding energies. However, the inclusion of dispersion effects leads to the prediction of a much stronger binding. There is a tendency for the clay model to bind water the strongest, this indicate a potential impact of having clay present in media for capillary trapping of carbon dioxide.

Originalsprog	Engelsk
Tidsskrift	Computational and Theoretical Chemistry
Vol/bind	1073
Sider (fra-til)	55-60
Antal sider	6
ISSN	2210-271X
DOI	https://doi.org/10.1016/j.comptc.2015.09.015
Status	Udgivet - 1 dec. 2015

Emneord

Wettability
Co2 absorption
Storage
Clays

Adgang til dokumentet

10.1016/j.comptc.2015.09.015

Citationsformater

The competition between H₂O and CO₂ adhesion at reservoir conditions : A DFT study of simple mineral models and the entropy, ZPE, dispersion and T,P variations. / Sølling, Theis Ivan; Budi, Akin; Mogensen, K.

I: Computational and Theoretical Chemistry, Bind 1073, 01.12.2015, s. 55-60.

Publikation: Bidrag til tidsskrift › Tidsskriftartikel › Forskning › peer review

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abstract = "Density functional theory was applied (B3LYP) to answer whether conditions exist where CO2 adhesion to three different lithologies becomes stronger than H2O adhesion. The answer is that it does not seem to be the case. This is taken to indicate that the reservoirs that we have represented by simple models are prone to CO2 storage. Moreover, we have obtained an overview of the effect of including entropy contributions and zero point vibrational energies in the calculation of the adhesion energies. The consequence of applying simple dispersion and solvent models are also addressed. The study is based around very simplified model systems of calcite, quartz and clays in order address the basic effects. Rather than attempting to obtain quantitative agreement we are observing the qualitative trends. When entropy, ZPE and a continuum model is included the result is smaller binding energies. However, the inclusion of dispersion effects leads to the prediction of a much stronger binding. There is a tendency for the clay model to bind water the strongest, this indicate a potential impact of having clay present in media for capillary trapping of carbon dioxide.",

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AU - Budi, Akin

AU - Mogensen, K.

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N2 - Density functional theory was applied (B3LYP) to answer whether conditions exist where CO2 adhesion to three different lithologies becomes stronger than H2O adhesion. The answer is that it does not seem to be the case. This is taken to indicate that the reservoirs that we have represented by simple models are prone to CO2 storage. Moreover, we have obtained an overview of the effect of including entropy contributions and zero point vibrational energies in the calculation of the adhesion energies. The consequence of applying simple dispersion and solvent models are also addressed. The study is based around very simplified model systems of calcite, quartz and clays in order address the basic effects. Rather than attempting to obtain quantitative agreement we are observing the qualitative trends. When entropy, ZPE and a continuum model is included the result is smaller binding energies. However, the inclusion of dispersion effects leads to the prediction of a much stronger binding. There is a tendency for the clay model to bind water the strongest, this indicate a potential impact of having clay present in media for capillary trapping of carbon dioxide.

AB - Density functional theory was applied (B3LYP) to answer whether conditions exist where CO2 adhesion to three different lithologies becomes stronger than H2O adhesion. The answer is that it does not seem to be the case. This is taken to indicate that the reservoirs that we have represented by simple models are prone to CO2 storage. Moreover, we have obtained an overview of the effect of including entropy contributions and zero point vibrational energies in the calculation of the adhesion energies. The consequence of applying simple dispersion and solvent models are also addressed. The study is based around very simplified model systems of calcite, quartz and clays in order address the basic effects. Rather than attempting to obtain quantitative agreement we are observing the qualitative trends. When entropy, ZPE and a continuum model is included the result is smaller binding energies. However, the inclusion of dispersion effects leads to the prediction of a much stronger binding. There is a tendency for the clay model to bind water the strongest, this indicate a potential impact of having clay present in media for capillary trapping of carbon dioxide.

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KW - Wettability

KW - CO2 absorption

KW - Storage

KW - Clays

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