Issue 55, 2022, Issue in Progress

Data-driven prediction of in situ CO2 foam strength for enhanced oil recovery and carbon sequestration

Abstract

Carbon dioxide foam injection is a promising enhanced oil recovery (EOR) method, being at the same time an efficient carbon storage technology. The strength of CO2 foam under reservoir conditions plays a crucial role in predicting the EOR and sequestration performance, yet, controlling the strength of the foam is challenging due to the complex physics of foams and their sensitivity to operational conditions and reservoir parameters. Data-driven approaches for complex fluids such as foams can be an alternative method to the time-consuming experimental and conventional modeling techniques, which often fail to accurately describe the effect of all important related parameters. In this study, machine learning (ML) models were constructed to predict the oil-free CO2 foam apparent viscosity in the bulk phase and sandstone formations. Based on previous experimental data on various operational and reservoir conditions, predictive models were developed by employing six ML algorithms. Among the applied algorithms, neural network algorithms provided the most precise predictions for bulk and porous media. The established models were then used to compute the critical foam quality under different conditions and determine the maximum apparent foam viscosity, effectively controlling CO2 mobility to co-optimize EOR and CO2 sequestration.

Graphical abstract: Data-driven prediction of in situ CO2 foam strength for enhanced oil recovery and carbon sequestration

Supplementary files

Article information

Article type
Paper
Submitted
16 Sep 2022
Accepted
25 Nov 2022
First published
14 Dec 2022
This article is Open Access
Creative Commons BY license

RSC Adv., 2022,12, 35703-35711

Data-driven prediction of in situ CO2 foam strength for enhanced oil recovery and carbon sequestration

J. Iskandarov, G. S. Fanourgakis, S. Ahmed, W. Alameri, G. E. Froudakis and G. N. Karanikolos, RSC Adv., 2022, 12, 35703 DOI: 10.1039/D2RA05841C

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