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Pore-scale simulation of three-phase displacement in 3D porous media using advanced LBM: insights into CO2 enhanced oil recovery and storage

Yue Sun, Hang Yu, Zhaopeng Ren, Bo Yang, Zhongbei Li, Cuiping Xu

2025Computers and Geotechnics9 citationsDOIOpen Access PDF

Abstract

Carbon dioxide enhanced oil recovery (CO 2 -EOR) is a promising technology that simultaneously increases oil production and facilitates CO 2 sequestration, addressing energy and environmental challenges. This study develops an advanced multiphase lattice Boltzmann model to simulate CO 2 -water–oil displacement in three-dimensional porous media, incorporating realistic fluid properties and dynamic interfacial behaviors. By systematically analyzing the effects of water saturation (S w ), wettability (θ), and capillary number (Ca), the study reveals critical insights into optimizing oil recovery and CO 2 storage efficiency. Results demonstrate that at lower water saturation (S w = 0.4), enhanced oil phase connectivity leads to maximum oil recovery efficiency of 33.5 %, while higher water saturation (S w = 0.8) facilitates CO 2 storage, achieving a storage efficiency of 64.1 %. Wettability exhibits a dual regulatory effect: water-wet conditions maximize oil recovery, whereas oil-wet conditions enhance CO 2 storage efficiency. Furthermore, increasing the Ca from −3.2 to −2.2 significantly improves oil recovery and CO 2 storage efficiency, highlighting the importance of viscous forces in overcoming capillary barriers. The study introduces a novel Ca-θ-S o /S g color diagram, allowing precise quantification of oil recovery and CO 2 storage efficiencies across varying wettability and Ca conditions. A binomial empirical formula for the color diagram enables rapid estimation of efficiencies, with R 2 values exceeding 0.92. Notably, the nonlinear relationship between oil recovery and CO 2 storage efficiency underscores the complex interplay of multiphase flow mechanisms. This work provides a robust theoretical framework and practical tools for reservoir engineering, offering actionable strategies for optimizing CO 2 injection schemes and enhancing geological CO 2 storage. These findings advance the understanding of multiphase displacement dynamics and establish a foundation for the further development of CO 2 -EOR and storage technologies.

Topics & Concepts

Porous mediumDisplacement (psychology)Scale (ratio)Enhanced oil recoveryPorosityMaterials sciencePetroleum engineeringPhase (matter)Geotechnical engineeringGeologyPhysicsPsychologyQuantum mechanicsPsychotherapistEnhanced Oil Recovery TechniquesLattice Boltzmann Simulation StudiesHydraulic Fracturing and Reservoir Analysis
Pore-scale simulation of three-phase displacement in 3D porous media using advanced LBM: insights into CO2 enhanced oil recovery and storage | Litcius