Molecular Dynamics Investigation of Mineral Surface Wettability in Oil- Water Systems: Implications for Hydrocarbon Reservoir Development
HG Xin and X Zuo and LW Zhu and B Jia, MINERALS, 15, 1194 (2025).
DOI: 10.3390/min15111194
Wettability significantly influences fluid distribution and flow behavior in hydrocarbon reservoirs, yet traditional macroscopic measurements fail to capture the micro- and nanoscale interfacial interactions that govern these processes. This study addresses a critical knowledge gap by employing molecular dynamics simulations to systematically investigate how salinity and mineral composition control wettability at the atomic scale-insights that are experimentally inaccessible yet essential for optimizing enhanced oil recovery strategies. We examined five typical reservoir minerals-kaolinite, montmorillonite, chlorite, quartz, and calcite-along with graphene as a model organic surface. Our findings reveal that while all minerals exhibit hydrophilicity (contact angles below 75 degrees), increasing salinity weakens water wettability, with Ca2+ ions exerting the strongest effect due to their high charge density, which enhances electrostatic attraction with negatively charged mineral surfaces and promotes specific adsorption at the mineral-water interface, thereby displacing water molecules and reducing surface hydrophilicity. In oil- water-mineral systems, we discovered that graphene displays exceptional oleophilicity, with hydrocarbon interaction energies reaching -7043.61 kcal/mol for C18H38, whereas calcite and quartz maintain strong hydrophilicity. Temperature and pressure conditions modulate interfacial behavior distinctly: elevated pressure enhances molecular aggregation, while higher temperature promotes diffusion. Notably, mixed alkane simulations reveal that heavy hydrocarbons preferentially adsorb on mineral surfaces and form highly ordered structures on graphene, with diffusion rates inversely correlating with molecular size. These atomic- scale insights into wettability mechanisms provide fundamental understanding for designing salinity management and wettability alteration strategies in enhanced oil recovery operations.
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