Molecular Insight into CO 2 Improving Oil Mobility in Shale Inorganic Nanopores Containing Water Films

CO injection into shale reservoirs has been recognized as one of the most promising techniques for enhanced oil recovery and carbon capture, utilization, and storage. However, the omnipresent nanopores and the water films formed near the pore walls affect the understanding of mechanisms of CO regula...

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Bibliographic Details
Published in:Langmuir 2024-08, Vol.40 (33), p.17568-17576
Main Authors: Zhao, Yunlong, Yang, Liqiang, Xiao, Peiwen, Liang, Yunhang, Hua, Xinlong, Tian, Wen, Fang, Wenjing, Liu, Bing
Format: Article
Language:English
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Summary:CO injection into shale reservoirs has been recognized as one of the most promising techniques for enhanced oil recovery and carbon capture, utilization, and storage. However, the omnipresent nanopores and the water films formed near the pore walls affect the understanding of mechanisms of CO regulating crude oil mobility in shale nanopores. In this work, we employ molecular dynamics simulations to study the occurrence and flow of CO and octane ( C ) mixtures in quartz nanopores containing water films, to illustrate the impact mechanisms of CO on C mobility. The results indicate that C exists between water films, and CO is mainly miscible with C in the pore center, and a small portion of it accumulates at the interface between C and the water film. CO significantly decreases the apparent viscosity of C in both the bulk C region and the C -water interface region, improving C fluidity. As the percentage of CO in the CO and C mixtures increases from 0 to 50%, the mean flow velocities of C in the bulk phase region and the C -water interface region increase by 92.85 and 60.64%, respectively. Three major microscopic mechanisms of CO improving C fluidity in quartz nanopores with water films are summarized: (i) CO reduces friction between C and the water film by increasing the angle between C molecules and the plane of the water film; (ii) CO widens the distance between C molecules, causing the volume expansion of C and its viscosity reduction; (iii) CO significantly increases the most probable and average velocities of C molecules, thus improving their mobility. Our results enhance the comprehension of how CO facilitates oil flow in water-bearing shale reservoirs and the exploitation of unconventional oil resources.
ISSN:0743-7463
1520-5827
DOI:10.1021/acs.langmuir.4c01806