In recent years, ionic liquids have received increasing interests as an effective demulsifier due to their characteristics of non-flammability, thermal stability, recyclability, and low vapor pressure. In this study, emulsion formation and types, chemical demulsification system, the application of ionic liquids as a chemical demulsifier, and key factors affecting their performance were comprehensively reviewed. Future challenges and opportunities of ionic liquids application for chemical demulsification were also discussed. The review indicted that the demulsification performance was affected by the type, molecular weight, and concentration of ionic liquids. Moreover, other factors, including the salinity of aqueous phase, temperature, and oil types, could affect the demulsification process. It can be concluded that ionic liquids can be used as a suitable substitute for commercial demulsifiers, but future efforts should be required to develop non-toxic and less expensive ionic liquids with low viscosity, and the demulsification efficiency could be improved through the application of ionic liquids with other methods such as organic solvents.
This research investigated
the performance of dioctyl
sodium sulfosuccinate
(DSS), a double-chain anionic surfactant, in breaking crude oil-in-water
emulsions. The response surface methodology was used to consider the
effect of the DSS concentration, oil concentration, and shaking time
on demulsification efficiency and obtain optimum demulsification conditions.
Further single-factor experiments were conducted to investigate the
effects of salinity, crude oil conditions (fresh and weathered), and
gravity separation settling time. The results showed that DSS efficiently
demulsified stable emulsions under different oil concentrations (500–3000
mg/L) within 15 min shaking time. Increasing DSS concentration to
900 mg/L (critical micelle concentration) increased the demulsification
efficiency to 99%. DSS not only improved the demulsification efficiency
but also did not impede the demulsifier interfacial adsorption at
the oil–water interface due to the presence of the double-chain
structure. The low molecular weight enables the homogeneous distribution
of DSS molecules in the emulsion, leading to a high demulsification
efficiency within 15 min. Analysis of variance results indicated the
importance of considering the interaction of oil concentration and
shaking time in demulsification. DSS could reduce the total extractable
petroleum hydrocarbons in the separated water to <10 mg/L without
gravity separation and could achieve promising demulsification performance
at high salinity (36 g/L) and various concentrations of fresh and
weathered oil. The demulsification mechanism was explained by analyzing
the microscopic images and the transmittance of the emulsion. DSS
could be an efficient double-chain anionic surfactant in demulsifying
stable oil-in-water emulsions.
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