Salinity-Dependent Adhesion Response Properties of Aluminosilicate (K-Feldspar) Surfaces

Research output: Contribution to journalJournal articleResearchpeer-review

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Salinity-Dependent Adhesion Response Properties of Aluminosilicate (K-Feldspar) Surfaces. / Lorenz, Bärbel; Ceccato, Marcel; Andersson, Martin Peter; Dobberschütz, Sören; Rodriguez Blanco, Juan Diego; Dalby, Kim Nicole; Hassenkam, Tue; Stipp, Susan Louise Svane.

In: Energy and Fuels, Vol. 31, No. 5, 2017, p. 4670-4680.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Lorenz, B, Ceccato, M, Andersson, MP, Dobberschütz, S, Rodriguez Blanco, JD, Dalby, KN, Hassenkam, T & Stipp, SLS 2017, 'Salinity-Dependent Adhesion Response Properties of Aluminosilicate (K-Feldspar) Surfaces', Energy and Fuels, vol. 31, no. 5, pp. 4670-4680. https://doi.org/10.1021/acs.energyfuels.6b02969

APA

Lorenz, B., Ceccato, M., Andersson, M. P., Dobberschütz, S., Rodriguez Blanco, J. D., Dalby, K. N., Hassenkam, T., & Stipp, S. L. S. (2017). Salinity-Dependent Adhesion Response Properties of Aluminosilicate (K-Feldspar) Surfaces. Energy and Fuels, 31(5), 4670-4680. https://doi.org/10.1021/acs.energyfuels.6b02969

Vancouver

Lorenz B, Ceccato M, Andersson MP, Dobberschütz S, Rodriguez Blanco JD, Dalby KN et al. Salinity-Dependent Adhesion Response Properties of Aluminosilicate (K-Feldspar) Surfaces. Energy and Fuels. 2017;31(5):4670-4680. https://doi.org/10.1021/acs.energyfuels.6b02969

Author

Lorenz, Bärbel ; Ceccato, Marcel ; Andersson, Martin Peter ; Dobberschütz, Sören ; Rodriguez Blanco, Juan Diego ; Dalby, Kim Nicole ; Hassenkam, Tue ; Stipp, Susan Louise Svane. / Salinity-Dependent Adhesion Response Properties of Aluminosilicate (K-Feldspar) Surfaces. In: Energy and Fuels. 2017 ; Vol. 31, No. 5. pp. 4670-4680.

Bibtex

@article{58ec5ff180bc430ca1f0dfa4a00a6d2f,
title = "Salinity-Dependent Adhesion Response Properties of Aluminosilicate (K-Feldspar) Surfaces",
abstract = "Flooding sandstone oil reservoirs with low salinity water can lead to a significant increase in oil recovery, a phenomenon called {"}the low salinity effect{"}. Although there are many factors that contribute to this response, the surface tension on the pore walls is an important one. Sandstone is composed predominantly of quartz with some clay, but feldspar grains are often also present. While the wettability of quartz and clay surfaces has been thoroughly investigated, little is known about the adhesion properties of feldspar. We explored the interaction of model oil compounds, molecules that terminate with carboxyl, -COO(H), and alkyl, -CH3, with freshly cleaved, museum quality perthitic microcline, KxNa(1-x)AlSi3O8, a K-feldspar. Microcline is a member of the orthoclase family, a type of feldspar that weathers more slowly than the plagioclase series, and thus is more likely to be preserved in well sorted sandstone. Adhesion forces, measured with the chemical force mapping (CFM) mode of atomic force microscopy (AFM), showed a low salinity effect on the fresh feldspar surfaces. Adhesion force, measured with -COO(H)-functionalized tips, was 60% lower in artificial low salinity seawater (LS, ∼1500 ppm total dissolved solids) than in the high salinity solution, artificial seawater (HS, ASW, ∼35 600 ppm). Adhesion with the -CH3 tips was as much as 30% lower in LS than in HS. Density functional theory calculations indicated that the low salinity response resulted from expansion of the electric double layer and that contributions from cation bridging are of less importance. Adventitious carbon, that is, organic material that is inherent on all mineral surfaces exposed to air or water, can enhance nonpolar component adhesion by serving as anchor points.",
author = "B{\"a}rbel Lorenz and Marcel Ceccato and Andersson, {Martin Peter} and S{\"o}ren Dobbersch{\"u}tz and {Rodriguez Blanco}, {Juan Diego} and Dalby, {Kim Nicole} and Tue Hassenkam and Stipp, {Susan Louise Svane}",
year = "2017",
doi = "10.1021/acs.energyfuels.6b02969",
language = "English",
volume = "31",
pages = "4670--4680",
journal = "Energy & Fuels",
issn = "0887-0624",
publisher = "American Chemical Society",
number = "5",

}

RIS

TY - JOUR

T1 - Salinity-Dependent Adhesion Response Properties of Aluminosilicate (K-Feldspar) Surfaces

AU - Lorenz, Bärbel

AU - Ceccato, Marcel

AU - Andersson, Martin Peter

AU - Dobberschütz, Sören

AU - Rodriguez Blanco, Juan Diego

AU - Dalby, Kim Nicole

AU - Hassenkam, Tue

AU - Stipp, Susan Louise Svane

PY - 2017

Y1 - 2017

N2 - Flooding sandstone oil reservoirs with low salinity water can lead to a significant increase in oil recovery, a phenomenon called "the low salinity effect". Although there are many factors that contribute to this response, the surface tension on the pore walls is an important one. Sandstone is composed predominantly of quartz with some clay, but feldspar grains are often also present. While the wettability of quartz and clay surfaces has been thoroughly investigated, little is known about the adhesion properties of feldspar. We explored the interaction of model oil compounds, molecules that terminate with carboxyl, -COO(H), and alkyl, -CH3, with freshly cleaved, museum quality perthitic microcline, KxNa(1-x)AlSi3O8, a K-feldspar. Microcline is a member of the orthoclase family, a type of feldspar that weathers more slowly than the plagioclase series, and thus is more likely to be preserved in well sorted sandstone. Adhesion forces, measured with the chemical force mapping (CFM) mode of atomic force microscopy (AFM), showed a low salinity effect on the fresh feldspar surfaces. Adhesion force, measured with -COO(H)-functionalized tips, was 60% lower in artificial low salinity seawater (LS, ∼1500 ppm total dissolved solids) than in the high salinity solution, artificial seawater (HS, ASW, ∼35 600 ppm). Adhesion with the -CH3 tips was as much as 30% lower in LS than in HS. Density functional theory calculations indicated that the low salinity response resulted from expansion of the electric double layer and that contributions from cation bridging are of less importance. Adventitious carbon, that is, organic material that is inherent on all mineral surfaces exposed to air or water, can enhance nonpolar component adhesion by serving as anchor points.

AB - Flooding sandstone oil reservoirs with low salinity water can lead to a significant increase in oil recovery, a phenomenon called "the low salinity effect". Although there are many factors that contribute to this response, the surface tension on the pore walls is an important one. Sandstone is composed predominantly of quartz with some clay, but feldspar grains are often also present. While the wettability of quartz and clay surfaces has been thoroughly investigated, little is known about the adhesion properties of feldspar. We explored the interaction of model oil compounds, molecules that terminate with carboxyl, -COO(H), and alkyl, -CH3, with freshly cleaved, museum quality perthitic microcline, KxNa(1-x)AlSi3O8, a K-feldspar. Microcline is a member of the orthoclase family, a type of feldspar that weathers more slowly than the plagioclase series, and thus is more likely to be preserved in well sorted sandstone. Adhesion forces, measured with the chemical force mapping (CFM) mode of atomic force microscopy (AFM), showed a low salinity effect on the fresh feldspar surfaces. Adhesion force, measured with -COO(H)-functionalized tips, was 60% lower in artificial low salinity seawater (LS, ∼1500 ppm total dissolved solids) than in the high salinity solution, artificial seawater (HS, ASW, ∼35 600 ppm). Adhesion with the -CH3 tips was as much as 30% lower in LS than in HS. Density functional theory calculations indicated that the low salinity response resulted from expansion of the electric double layer and that contributions from cation bridging are of less importance. Adventitious carbon, that is, organic material that is inherent on all mineral surfaces exposed to air or water, can enhance nonpolar component adhesion by serving as anchor points.

U2 - 10.1021/acs.energyfuels.6b02969

DO - 10.1021/acs.energyfuels.6b02969

M3 - Journal article

AN - SCOPUS:85020507683

VL - 31

SP - 4670

EP - 4680

JO - Energy & Fuels

JF - Energy & Fuels

SN - 0887-0624

IS - 5

ER -

ID: 180786492