%P 3961-3969 %T Performance of surfactant blend formulations for controlling gas mobility and foam propagation under reservoir conditions %I Springer Science and Business Media Deutschland GmbH %A M.K. Memon %A K.A. Elraies %A M.I.A. Al-Mossawy %V 10 %D 2020 %R 10.1007/s13202-020-00996-0 %N 8 %O cited By 2 %L scholars12429 %J Journal of Petroleum Exploration and Production Technology %X The use of surfactant is one of the possible solutions to minimize the mobility of gases and improve the sweep efficiency, but the main problem with this process is its stability in the presence of injection water and crude oil under reservoir conditions. In this study, the three types of surfactant anionic, nonionic and amphoteric are examined in the presence of brine salinity at 96 °C and 1400 psia. To access the potential blended surfactant solutions as gas mobility control, laboratory test including aqueous stability, interfacial tension (IFT) and mobility reduction factor (MRF) were performed. The purpose of MRF is to evaluate the blocking effect of selected optimum surfactant solutions. Based on experimental results, no precipitation was observed by testing the surfactant solutions at reservoir temperature of 96 °C. The tested surfactant solutions reduced the IFT between crude oil and brine. The effectiveness and strength of surfactant solutions without crude oil under reservoir conditions were evaluated. A high value of differential pressure demonstrates that the strong foam was generated inside a core that resulted in delay in breakthrough time and reduction in the gas mobility. High mobility reduction factor result was measured by the solution of blended surfactant 0.6AOS + 0.6CA406H. Mobility reduction factor of other tested surfactant solutions was found low due to less generated foam by using CO2 under reservoir conditions. The result of these tested surfactant solutions can provide the better understanding of the mechanisms behind generated foam stability and guideline for their implementation as gas mobility control during the process of surfactant alternating gas injection. © 2020, The Author(s). %K Crude oil; Foam control; Gases; Magnetorheological fluids; Petroleum reservoir engineering; Process control, Aqueous stability; Breakthrough time; Differential pressures; Mobility reduction; Reservoir conditions; Reservoir temperatures; Surfactant blends; Surfactant solution, Amphoteric surfactants