Hydrophobically Modified Polymer-Surfactant Self-Assembly System: A Study of a Self-Thickening Diverting Acid Solution.
Yanna Zhang, Jincai Wang, Hongping Quan, Liping Yi, Yingze Pei, Conghui Xu
Abstract
Open AccessStudying an efficient acid additive is of great significance for acid diversion operations. This study synthesized a hydrophobically modified triblock copolymer ASN (acrylamide-styrene-N-vinylimidazole triblock copolymer, Mn = 0.49 × 105). In the acidic solution, the surfactant octadecyltrimethylammonium chloride (STAC) was used to self-assemble with the polymer. By changing the self-assembly formula, the advantages of the self-assembled acid solution in diverting performance were intuitively observed, and the retarding performance of self-assembled acid solution was evaluated. A rheometer was used to test the temperature resistance, shear resistance, and viscoelasticity of self-assembled acids. The hydrodynamic radius and surface morphology of self-assembled acid were studied by using a dynamic light scattering laser particle size analyzer and environmental scanning electron microscope, and the mechanism of self-assembled acid thickening was explored. The results indicate that at ASN:STAC = 1.0:0.2 (molar ratio), the system achieved peak viscosity (250 ± 10 mPa·s at 100 s- 1), 40% higher than other ratios, while maintaining 85% viscosity retention after rock reaction. Under high-temperature shear conditions at 160 °C and 170 s-1 for 1 h, the self-assembled acidic solution maintained an apparent viscosity of 104 mPa·s. The self-assembled acid solution exhibits excellent temperature and shear resistance, achieving a retardation rate of up to 85% at 110 °C. Mechanistic investigations reveal that HCl consumption and Ca2+ precipitation during acid-rock reactions critically govern the acid-triggered self-thickening behavior of the self-assembled system, inducing viscosity fluctuations exceeding 80%.