Recovery mechanisms of shale oil by CO2 injection in organic and inorganic nanopores from molecular perspective

•The static and flow behavior of CO2-nC8 in kerogen and quartz nanopores are studied.•Oil viscosity reduction of CO2 is the dominant EOR mechanism in kerogen nanopores.•CO2 extracts adsorbed nC8 and reduces the slip by competitive adsorption on quartz.•Oil viscosity reduction occurs in quartz nanopo...

Full description

Saved in:
Bibliographic Details
Published in:Journal of molecular liquids 2024-03, Vol.398, p.124276, Article 124276
Main Authors: Zhang, Wei, Dai, Cheng, Chen, Zhiqiang, He, Yingfu, Wang, Sen
Format: Article
Language:English
Subjects:
Carbon dioxide
EOR mechanism
Molecular simulation
Shale oil
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:•The static and flow behavior of CO2-nC8 in kerogen and quartz nanopores are studied.•Oil viscosity reduction of CO2 is the dominant EOR mechanism in kerogen nanopores.•CO2 extracts adsorbed nC8 and reduces the slip by competitive adsorption on quartz.•Oil viscosity reduction occurs in quartz nanopore after CO2 adsorption is saturated. CO2 injection is the feasible method to enhance shale oil recovery and has attracted extensive attention in recent years. Since shale reservoir has omnipresent nanoscale pores, understanding the underlying CO2-EOR mechanisms at the nanoscale is of critical importance. In this work, we study the structural and dynamic properties of CO2/nC8 systems in organic kerogen and inorganic quartz nanopores by molecular dynamic simulation and clarify the dominant EOR mechanisms of CO2 injection in various mineral nanopores. We find a large positive slip velocity occurs when single-phase nC8 flows in quartz nanopore while it is no-slip boundary condition in kerogen nanopore. The CO2-regulated nC8 in quartz nanopore is the joint effect of slip, competitive adsorption and viscosity reduction. In the first stage, CO2 extracts the first adsorption layer of nC8 by competitive adsorption and forms a CO2 film on the quartz surface. The CO2 film reduces the slip velocity between nC8 and quartz surface and weakens the nC8 flow capacity. After CO2 adsorption is saturated, the CO2 mixes with nC8 in all flow regions and the effective viscosity of nC8 starts decreasing at this stage. The flow capacity of nC8 rises dramatically due to the viscosity reduction mechanism of CO2. In kerogen nanopore, it is no-slip boundary condition and CO2 mixes with nC8 in all flow regions directly instead of preferably adsorbed on the surface. Viscosity reduction is the dominant mechanism to affect nC8 flow behavior and nC8 flow capacity is enhanced monotonically as CO2 injection. Our study advances the understanding of the recovery mechanisms of shale oil by CO2 injection on nanoscale and provides the theoretical foundation for the optimization of CO2-EOR in shale oil reservoirs.
ISSN:0167-7322
1873-3166
DOI:10.1016/j.molliq.2024.124276