Effects of petroleum resins on asphaltene aggregation and water-in-oil emulsion formation

• Published in: Colloids and surfaces. A, Physicochemical and engineering aspects Vol. 220; no. 1; pp. 9 - 27
• Main Authors: Spiecker, P.Matthew, Gawrys, Keith L, Trail, Chad B, Kilpatrick, Peter K
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 30.06.2003
• Subjects: Asphaltenes; Emulsion stability; Resins; Small-angle neutron scattering; Asphaltenes; Small-angle neutron scattering; Resins; Emulsion stability
• ISSN: 0927-7757; 1873-4359
• DOI: 10.1016/S0927-7757(03)00079-7

Asphaltenes from four crude oils were fractionated by precipitation in mixtures of heptane and toluene. Solubility profiles generated in the presence of resins (1:1 mass ratio) indicated the onset of asphaltene precipitation occurred at lower toluene volume fractions (0.1–0.2) than without resins. Small-angle neutron scattering (SANS) was performed on solutions of asphaltene fractions in mixtures of heptane and toluene with added resins to determine aggregate sizes. Water-in-oil emulsions of asphaltene–resin solutions were prepared and separated by a centrifuge method to determine the vol.% water resolved. In general, the addition of resins to asphaltenes reduced the aggregate size by disrupting the π–π and polar bonding interactions between asphaltene monomers. Interaction of resins with asphaltenic aggregates rendered the aggregates less interfacially active and thus reduced emulsion stability. The smallest aggregate sizes observed and the weakest emulsion stability at high resin to asphaltene (R/A) ratios presumably corresponded to asphaltenic monomers or small oligomers strongly interacting with resin molecules. It was often observed that, in the absence of resins, the more polar or higher molecular weight asphaltenes were insoluble in solutions of heptane and toluene. The addition of resins dissolved these insolubles and aggregate size by SANS increased until the solubility limit was reached. This corresponded approximately to the point of maximum emulsion stability. Asphaltene chemistry plays a vital role in dictating emulsion stability. The most polar species typically required significantly higher resin concentrations to disrupt asphaltene interactions and completely destabilize emulsions. Aggregation and film formation are likely driven by polar heteroatom interactions, such as hydrogen bonding, which allow asphaltenes to absorb, consolidate, and form cohesive films at the oil–water interface.