Abstract
This work is devoted to the influence of NaCl salt concentration on the formation and stability of colloidal gas aphrons (CGA) produced by the anionic surfactant sodium dodecyl sulfate (SDS) and zwitterionic surfactant coco amido propyl betaine (CAPB) in the presence of xanthan gum (XG) as a stabilizer. Dynamic surface tension measurements as well as volume and half-life time of the produced foams are considered for stability analysis. A sharp decrease of the half-life time and volume of the CGAs at NaCl concentrations larger than 20,000 ppm was observed, which was attributed to the precipitation of SDS in the solution. The mentioned SDS precipitation altered the dynamic surface tension behavior, dilational surface elasticity, and turbidity of the solution. The main reason for the precipitation of SDS is the increased Krafft point caused by the addition of salt. However, for the zwitterionic surfactant CAPB, the effects of added NaCl on the interfacial properties required for CGAs production was negligible due to the simultaneous effects on the cationic and anionic head groups in the CAPB leading to negligible changes in the net repulsion forces. Yet, an overall reduction in the half-life time of CGAs with increasing salt concentration, even when we have no precipitation, was observed for both surfactants, which could be explained by the reduction in the ability of XG to increase the viscosity with increasing salt concentration.
Highlights
Colloidal gas aphrons (CGAs) were introduced by Sebba, and refer to a colloidal system of bubbles in the micron-range size
sodium dodecyl sulfate (SDS) is a frequently used surfactant for making CGAs [10,25]
10,000 ppm NaCl, an approximately constant value for the CGA volume could be observed while the half-life time decreases slightly
Summary
Colloidal gas aphrons (CGAs) were introduced by Sebba, and refer to a colloidal system of bubbles in the micron-range size. According to Sebba, each CGA comprises of a gas core encapsulated in a viscous shell formed by two layers of surfactants. CGAs have been frequently used as drilling fluid for depleted fractured formations. Their ability to survive longer at higher pressures in comparison to regular foams as well as easy production and easy handling have made them a suitable choice for drilling engineering [3,4,5,6,7,8,9,10,11]. From the review article [10], it can be seen that many papers have studied the effect of different parameters, including stirring time and speed, surfactant and polymer type, and concentration, etc., on the formation, stability, and performance of CGAs. the influence of salts has not been sufficiently investigated. Many water sources used for making CGAs contain various amounts of salts and during offshore drilling when using sea water, the salinity level may be even higher than 30,000 ppm
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