Ion adsorption-induced wetting transition in oil-water-mineral systems
Citations Over TimeTop 1% of 2015 papers
Abstract
The relative wettability of oil and water on solid surfaces is generally governed by a complex competition of molecular interaction forces acting in such three-phase systems. Herein, we experimentally demonstrate how the adsorption of in nature abundant divalent Ca(2+) cations to solid-liquid interfaces induces a macroscopic wetting transition from finite contact angles (≈ 10°) with to near-zero contact angles without divalent cations. We developed a quantitative model based on DLVO theory to demonstrate that this transition, which is observed on model clay surfaces, mica, but not on silica surfaces nor for monovalent K(+) and Na(+) cations is driven by charge reversal of the solid-liquid interface. Small amounts of a polar hydrocarbon, stearic acid, added to the ambient decane synergistically enhance the effect and lead to water contact angles up to 70° in the presence of Ca(2+). Our results imply that it is the removal of divalent cations that makes reservoir rocks more hydrophilic, suggesting a generalizable strategy to control wettability and an explanation for the success of so-called low salinity water flooding, a recent enhanced oil recovery technology.
Related Papers
- → Wetting and superhydrophobic properties of PECVD grown hydrocarbon and fluorinated-hydrocarbon coatings(2010)63 cited
- → Predicting the critical salt concentrations of monovalent and divalent brines to initiate fines migration using DLVO modeling(2022)22 cited
- → WETTING OF ROUGH SURFACES(2004)21 cited
- → A 2-D analytical model for the wetting behavior of various microtextured surfaces(2021)3 cited
- → Contact Angle Hysteresis near a First-Order Wetting Transition(2001)5 cited