AI Article Synopsis
- * IAA has a higher oxygen content and larger size than INAA, which translates to better stabilization properties at the oil-water interface, with IAA showing superior performance at lower concentrations.
- * The research uses advanced techniques to analyze the compositions, behaviors, and interactions of these asphaltene subfractions, offering new insights into their roles in emulsion stabilization processes.
Article Abstract
Hypothesis: Asphaltenes subfractions with distinct interfacial behaviors may play different roles in stabilizing oil-water emulsions.
Experiments: In this work, whole asphaltenes were separated into interfacially active asphaltenes (IAA) and interfacially non-active asphaltenes (INAA). Employing advanced nanomechanical techniques, we have explored the compositions, morphologies, sizes, adsorption, and interfacial behaviors of IAA and INAA.
Findings: IAA exhibits a high and unevenly distributed oxygen content, distinguishing it from INAA. In toluene, the diameters of IAA and INAA are about 60 nm and 6 nm, respectively. When adsorbed irreversibly on mica surfaces, the thickness of the IAA and INAA film was measured at ∼5.5 nm or 1 nm, respectively; while in a toluene solution, the film thickness reached ∼46 nm and 3.1 nm for IAA and INAA, respectively. IAA demonstrates superior interfacial activity, and elastic/viscous moduli compared to INAA at the water-toluene interface. Quantified surface force measurements reveal that IAA stabilizes water droplets in toluene at a concentration of only 10 mg/L, while INAA requires a higher concentration of 100 mg/L. This work provides the first comprehensive investigation into the adsorption and interfacial behaviors of asphaltene subfractions and provides useful insights into the asphaltenes-stabilization mechanism of emulsions.
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| http://dx.doi.org/10.1016/j.jcis.2024.06.233 | DOI Listing |
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