Effects of Rheological Behavior of Viscoelastic Surfactants on Formation Damage in Carbonate Rocks

Abstract

Viscoelastic surfactants (VES) are used in various oilfield applications such as matrix stimulation and enhanced oil recovery. The loss of surfactants during the propagation of VES could result in a significant reduction in the permeability of the rock (formation damage). The objective of the current work was to identify the effect of rheological behavior of the VES on the formation damage using core-flooding experiments, nuclear magnetic resonance (NMR), and scanning electron microscopy (SEM) analysis. A combination of core-flooding, NMR, and SEM techniques was used to quantify and identify the location of formation damage in carbonate core samples. The viscosity and storage modulus strongly depend on the nature and concentration of salts. The viscosity increased by increasing the salt concentration up to a specific point (15 wt% CaCl2) and then starts decreasing. The VES formulations that displayed the maximum and minimum viscosities were used to identify the impact of rheological behavior on formation damage. Core-flooding experiments were performed to assess the formation damage due to high-viscosity and low-viscosity VES formulations. The reduction in the permeability of carbonate rocks reaches more than 90% of the initial permeability. It was found that low-viscosity VES caused more damage compared with high-viscosity VES when they were used at constant concentrations. NMR and core-flooding results revealed that the damage took place both in pore body and pore throat. However, most of the surfactant was retained at the pore throat.