Abstract
As-synthesized oleic amido propyl betaine surfactant mixture was developed through a slight modification of a conventional two-step betaine synthesis process of amidation and quaternization reactions. This method is a “direct formulating through synthesis” to achieve a targeted interfacial property (interfacial tension or IFT) of the as-synthesized surfactant. Oil–water IFT was measured in the crude oil–seawater system at 96 °C. The result showed that the as-synthesized surfactant was able to reduce crude oil–seawater IFT to the ultra-low level (<0.01 mN/m). As the finding emerged, the investigation was conducted to identify the elements that would bring the characteristic of ultra-low IFT. The characterization of the surfactant using FTIR, TG-IR, and HPLC suggested that unreacted materials associated with the surfactant remained, such as the carryover of a fatty amide from the intermediate process, residues of N, N trimethylene dimethylamine and sodium chloride as a by-product, and the important newly formed sodium oleate compound that was inadvertently generated via the reaction. The performance of the as-synthesized in seawater condition has been verified and the surface tension plot shows the lowest surface tension point at 0.05 wt.% concentration before developing a plateau region at higher surfactant concentration, indicating that the formation of surfactant micelles has been interrupted by the presence of other components in the solution. The dynamic IFT test performed on the as-synthesized product revealed that it was still able to reduce the crude oil–seawater IFT to an ultra-low level, despite the multiple undesirable components in the surfactant. IFT as low as 3.4 × 10−4 mN/m for the specific seawater and crude oil composition was obtained at a temperature of 96 °C.
Highlights
Surfactant is known for its function to reduce the surface or interfacial energy between two immiscible phases
The hydrophobic part of the amine may participate in functional groups, such as carbonyl from the amide group and carboxylate, attributed to the oleic the formation of micelles together with the surfactant to replace some of the water molecules at the amido betaine surfactant as well as sodium oleate, confirmed through the High Performance Liquid Chromatography (HPLC) method
The presence of inorganic salt (NaCl) as a suggested that the final product had a mixture of oleic amido betaine surfactant, long chain amide by-product added up to the salinity concentration, it influenced the reduction in Interfacial Tension (IFT) by intermediate, some unreacted sodium chloroacetate and a significant presence of sodium oleate accelerating the migration of the surfactant molecules to the interface and helped the partitioning of evolved from the hydrolysis reaction of the fatty amide with water at high temperature and basic condition
Summary
Surfactant is known for its function to reduce the surface or interfacial energy between two immiscible phases. Whereas for liquids with weaker molecular attractive interactions such as apolar hydrocarbons, the surface tension is typically around 20–30 mN/m [2]. The polarity difference is the main factor for the two liquids to become immiscible and to have high. The two liquids with different polarities may become miscible if the interfacial energy between the two phases is low enough. The surfactant with amphiphilic properties can practically reduce the interfacial tension according to the preference of the head and tail polarity by adsorbing at liquid–liquid interface to reduce the interfacial energy. Given the right factors and mechanisms, the interfacial tension of the liquid–liquid phases can be reduced to super low, usually called ultra-low Interfacial Tension (IFT) with a value less than
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