Microscale CO2-oil displacement and carbon sequestration mechanisms under heterogeneous wettability conditions

doi:10.7623/syxb202603009

Acta Petrolei Sinica ›› 2026, Vol. 47 ›› Issue (3): 624-640.DOI: 10.7623/syxb202603009

• OIL FIELD DEVELOPMENT • Previous Articles

Microscale CO₂-oil displacement and carbon sequestration mechanisms under heterogeneous wettability conditions

Zhang Yunpeng¹, Wang Bin¹, Li Gensheng¹, Wang Haizhu¹, Zheng Yong², Alexey Cheremisin³, Sergey Stanchits³, Sun Lianhe¹, Ding Boxin¹, Zhang Zhonggang⁴

1. State Key Laboratory of Petroleum Resources and Engineering, China University of Petroleum (Beijing), Beijing 102249, China;
2. Shaanxi Key Laboratory of Lacustrine Shale Gas Accumulation and Exploitation, Shaanxi Xi'an 710075, China;
3. Skolkovo Institute of Science and Technology, Moscow 121205, Russia;
4. China Petroleum Engineering Co., Ltd., Beijing 100101, China

Received:2025-09-05 Revised:2025-12-26 Published:2026-04-09

非均匀润湿条件下CO₂-油微观运移与碳封存机理

张云鹏¹, 王斌¹, 李根生¹, 王海柱¹, 郑永², Alexey Cheremisin³, Sergey Stanchits³, 孙廉贺¹, 丁柏昕¹, 张忠罡⁴

1. 油气资源与工程全国重点实验室, 中国石油大学(北京) 北京 102249;
2. 陕西省陆相页岩气成藏与开发重点实验室陕西西安 710075;
3. 斯科尔科沃科学技术研究院莫斯科 121205;
4. 中国石油集团工程股份有限公司北京 100101

通讯作者: 王斌,男,1991年2月生,2022年获美国路易斯安那州立大学博士学位,现为中国石油大学(北京)教授、博士生导师,主要从事油气藏CO₂完井增产理论与技术研究。Email:bin.wang@cup.edu.cn
作者简介:张云鹏,男,2000年5月生,2022年获西南石油大学学士学位,现为中国石油大学(北京)博士研究生,主要从事CO₂压裂与多相流的数值模拟研究。Email:2024310206@student.cup.edu.cn
基金资助:
国家自然科学基金国际(地区)合作与交流项目(No.W2412078)、国家自然科学基金“双碳”专项(No.52341401)、中国石油大学(北京)科研启动基金项目(2462024YJRC019)和陕西省陆相页岩气成藏与开发重点实验室开放课题项目资助。

Abstract

Abstract: Wettability is a key factor governing the distribution and migration behavior of formation fluids in oil and gas reservoirs, and a thorough understanding of its influence on CO₂-oil two-phase flow mechanisms is of great significance for enhancing tight oil and gas recovery and optimizing carbon sequestration technologies. However, existing studies predominantly relies on the assumption of uniform wettability assumption, failing to adequately capture the complex effects of heterogeneous wettability in real reservoirs. To address this gap, this study, based on the inherent heterogeneity of wettability in natural rocks, constructs a homogeneous porous medium model with randomly distributed wettability. Using computational fluid dynamics (CFD) methods, the microcosmic CO₂-oil flow processes are systematically simulated under varying CO₂ injection velocities, viscosity ratios, and interfacial tension conditions, with the aim of elucidating the effects of heterogeneous wettability on two-phase microscopic seepage characteristics, CO₂ displacement efficiency, and carbon sequestration performance. The results indicate that:(1) Compared with the single-wettability model, the fingering pathways formed during oil displacement by CO₂ flooding are highly correlated with the heterogeneous wettability distribution in porous media, and the oil recovery falls between those obtained in strongly CO₂-wet and strongly oil-wet systems. (2) A moderate increase in injection velocity enhances the dominance of viscous forces, enabling the flow to overcome local capillary resistance induced by wettability heterogeneity. This effectively suppresses capillary fingering, thereby improving sweep efficiency and increasing CO₂ storage capacity. (3) Viscosity-enhanced CO₂ effectively suppresses interfacial instability by reducing the viscosity contrast between the two phases, thereby improving flow continuity and sweep efficiency, and mitigating the effects of heterogeneous wettability. (4) The influence of heterogeneous wettability progressively weakens with decreasing interfacial tension. Under ultra-low interfacial tension conditions, although fluid snap-off is intensified, the sharp reduction in capillary resistance still results in enhanced displacement efficiency during CO₂ flooding. Overall, this study elucidates the mechanisms by which operational parameters regulate multiphase flow behavior under heterogeneous wettability conditions, and provides theoretical guidance and technical support for applications in multiphase flow, CCUS-EOR, and CO₂ fracturing.

Key words: heterogeneous wettability, CO₂ microscopic flow, CO₂ displacement and sequestration, computational fluid dynamics, fingering

摘要： 润湿性是影响油气藏中地层流体分布和运移特征的关键因素,深入理解其对CO₂-油两相流动机制的作用对于提升致密油气开采效率及优化碳封存技术具有重要意义。但现有研究多基于均匀润湿假设,未充分考虑真实储层中非均匀润湿性的复杂影响。鉴于此,基于真实岩石非均匀润湿的特性,构建了润湿性随机分布的均质多孔介质模型,并采用计算流体力学方法,系统模拟不同CO₂注入速度、黏度比和界面张力条件下的CO₂-油微观流动过程,探讨非均匀润湿性对两相微观渗流特征、CO₂驱油效率及碳封存性能的影响,揭示了在非均匀润湿性影响下施工参数对多相渗流的调控机制。研究表明:①与单一润湿性模型相比,CO₂驱替油相时形成的指进路径与多孔介质的非均匀润湿性分布高度相关,油相采收率介于强亲CO₂和强亲油模型之间;②适当提高注入速度增强了黏滞力主导作用,促使流动突破非均匀润湿性产生的局部毛细管阻力,有效抑制毛细管指进现象,从而提升波及效率与CO₂封存量;③增稠CO₂通过缩小两相黏度差异,有效抑制界面不稳定性,提高流动连续性和波及面积,降低非均匀润湿性的影响;④非均匀润湿性影响随界面张力降低而减弱,在超低界面张力下,流体"卡断"加剧,但因毛细管阻力骤降,CO₂驱油效率仍会提高。

关键词: 非均匀润湿性, CO₂微观流动, CO₂驱油与封存, 计算流体力学, 指进

CLC Number:

TE357

Zhang Yunpeng, Wang Bin, Li Gensheng, Wang Haizhu, Zheng Yong, Alexey Cheremisin, Sergey Stanchits, Sun Lianhe, Ding Boxin, Zhang Zhonggang. Microscale CO₂-oil displacement and carbon sequestration mechanisms under heterogeneous wettability conditions[J]. Acta Petrolei Sinica, 2026, 47(3): 624-640.

张云鹏, 王斌, 李根生, 王海柱, 郑永, Alexey Cheremisin, Sergey Stanchits, 孙廉贺, 丁柏昕, 张忠罡. 非均匀润湿条件下CO₂-油微观运移与碳封存机理[J]. 石油学报, 2026, 47(3): 624-640.

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Microscale CO₂-oil displacement and carbon sequestration mechanisms under heterogeneous wettability conditions

非均匀润湿条件下CO₂-油微观运移与碳封存机理

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