A study on the bio-based surfactant sodium cocoyl alaninate as a foaming agent for enhanced oil recovery in high-salt oil reservoirs

Hongda Hao; Hongze Wu; Haoyu Diao; Yixin Zhang; Shuo Yang; Song Deng; Qiu Li; Xiaopeng Yan; Mingguo Peng; Ming Qu; Xinyu Li; Jiaming Xu; Erlong Yang

doi:10.1039/d3ra07840j

A study on the bio-based surfactant sodium cocoyl alaninate as a foaming agent for enhanced oil recovery in high-salt oil reservoirs

RSC Adv. 2024 Jan 31;14(7):4369-4381. doi: 10.1039/d3ra07840j.

Authors

Hongda Hao¹, Hongze Wu¹, Haoyu Diao², Yixin Zhang¹, Shuo Yang¹, Song Deng¹, Qiu Li¹, Xiaopeng Yan¹, Mingguo Peng¹, Ming Qu³, Xinyu Li⁴, Jiaming Xu⁴, Erlong Yang⁵

Affiliations

¹ School of Petroleum and Natural Gas Engineering, School of Energy, Changzhou University Changzhou 213164 China dengsong@cczu.edu.cn +86 15261180955.
² CNPC Engineering Technology Research and Development Co. Ltd Beijing 100083 China.
³ Sanya Offshore Oil & Gas Research Institute, Northeast Petroleum University Sangya 572024 China.
⁴ China Yangtze Power Co. Ltd Yichang 443000 China.
⁵ School of Petroleum Engineering, Northeast Petroleum University Daqing 163318 China.

Abstract

Environmental awareness is receiving increasing attention in the petroleum industry, especially when associated with chemical agents applied in enhanced oil recovery (EOR) technology. The bio-based surfactant sodium cocoyl alaninate (SCA) is environmentally friendly and can be easily biodegraded, which makes it a promising alternative to traditional surfactants. Herein, the SCA surfactant is proposed as a foaming agent for enhanced oil recovery. Laboratory investigations on the surfactant concentration, foaming performance, microbubble characterization, interfacial tension, and foam-flooding of the traditional surfactants SDS and OP-10 have been conducted. In particular, the anti-salt abilities of these three surfactants have been studied, taking into consideration the reservoir conditions at Bohai Bay Basin, China. The results show that concentrations of 0.20 wt%, 0.20 wt% and 0.50 wt% for SCA, SDS and OP-10, respectively, can achieve optimum foaming ability and foaming stability under formation salinity conditions, and 0.20 wt% SCA achieved the best foaming ability and stability compared to 0.20 wt% SDS and 0.50 wt% OP-10. Sodium fatty acid groups and amino acid groups present in the SCA molecular structure have high surface activities under different salinity conditions, making SCA an excellent anti-salt surfactant for enhanced oil recovery. The microstructure analysis results showed that most of the SCA bubbles were smaller in size, with an average diameter of about 150 μm, and the distribution of SCA bubbles was more uniform, which can reduce the risk of foam coalescence and breakdown. The IFT value of the SCA/oil system was measured to be 0.157 mN m^-1 at 101.5 °C, which was the lowest. A lower IFT can make liquid molecules more evenly distributed on the surface, and enhance the elasticity of the foam film. Core-flooding experimental results showed that a 0.30 PV SCA foam and secondary waterflooding can enhance oil recovery by more than 15% after primary waterflooding, which can reduce the mobility ratio from 3.7711 to 1.0211. The more viscous SCA foam caused a greater flow resistance, and effectively reduced the successive water fingering, leading to a more stable driving process to fully displace the remaining oil within the porous media. The bio-based surfactant SCA proposed in this paper has the potential for application in enhanced oil recovery in similar high-salt oil reservoirs.