Multiphase fluid-rock interactions and flow behaviors in shale nanopores: A comprehensive review

IF 10.8 1区 地球科学 Q1 GEOSCIENCES, MULTIDISCIPLINARY Earth-Science Reviews Pub Date : 2024-08-03 DOI:10.1016/j.earscirev.2024.104884
Jianchao Cai, Xinghe Jiao, Han Wang, Wu He, Yuxuan Xia
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Abstract

The complicated flow behaviors of multiphase fluids in shale reservoirs are significantly influenced by fluid-fluid and fluid-rock interactions due to the non-negligible intermolecular forces at the nanoscale, which is crucial for the effective development and efficient extraction of shale oil. The complexity of multiphase fluid distribution and flow behaviors in shale reservoirs is further increased by low porosity, low permeability, poor connectivity, high inhomogeneity, and multi-component minerals, making the development process more challenging. Molecular dynamics simulation is widely to precisely capture the intermolecular forces and effectively explain the complex distribution and flow behaviors of these fluids under fluid-fluid and fluid-rock interaction forces. In this review, the characteristics of mineral composition, pore structure, porosity, permeability, and fluid types are first elaborated to illustrate the particularity of shale reservoirs and fluids compared to conventional scale reservoirs. The results show that shale minerals are composed of inorganic and organic matter with extremely low porosity and permeability, and nanoscale pore size, in which the complicated oil-water-CO2 multiphase fluid types are caused by the primary underground water, fracturing water and injected CO2. The research progress of molecular simulation on the fluid-fluid and fluid-rock interaction mechanisms and on multiphase shale fluids flow behaviors are then reviewed in detail. The strong intermolecular interaction forces can result in the different occurrence states of fluids, the fluid-fluid interfacial slip, the fluid-rock boundary slip and heterogeneous fluid viscosity/density, significantly exacerbating the complexity of fluids flow. Meanwhile, the injected CO2 in the formation becomes a supercritical state with high diffusivity and strong solubility, and causes oil expansion, density and viscosity reduction, interfacial tension reduction, wettability alteration and molecular diffusion, which effectively replaces adsorbed hydrocarbon components by competitive adsorption behaviors, and promotes oil flow. The challenges and outlook of molecular simulation research and upscaling applications are finally discussed. This review aims to provide a microscopic understanding of the distribution characteristics and flow behaviors of multiphase shale fluids in nanoconfined space for both unconventional oil and gas researchers and industry professionals.

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页岩纳米孔中的多相流体-岩石相互作用和流动行为:全面综述
由于纳米尺度的分子间作用力不可忽略,页岩储层中多相流体的复杂流动行为受到流体-流体和流体-岩石相互作用的显著影响,这对页岩油的有效开发和高效开采至关重要。页岩储层中多相流体分布和流动行为的复杂性因低孔隙度、低渗透率、连通性差、高非均质性和多组分矿物而进一步增加,使开发过程更具挑战性。分子动力学模拟可以精确捕捉分子间作用力,有效解释这些流体在流体-流体和流体-岩石相互作用力下的复杂分布和流动行为。本综述首先阐述了页岩储层的矿物组成、孔隙结构、孔隙度、渗透率和流体类型等特征,以说明页岩储层和流体与常规规模储层相比的特殊性。结果表明,页岩矿物由无机物和有机物组成,孔隙度和渗透率极低,孔隙尺寸达到纳米级,其中复杂的油-水-CO2 多相流体类型是由原生地下水、压裂水和注入的 CO2 引起的。随后详细介绍了分子模拟在流体-流体、流体-岩石相互作用机理以及页岩流体多相流动行为方面的研究进展。强烈的分子间相互作用力会导致流体的不同发生状态、流体-流体界面滑移、流体-岩石边界滑移以及流体粘度/密度的异质性,大大加剧了流体流动的复杂性。同时,注入的二氧化碳在地层中成为高扩散性、强溶解性的超临界状态,引起油膨胀、密度和粘度降低、界面张力降低、润湿性改变和分子扩散,通过竞争吸附行为有效取代吸附的烃组分,促进油流动。最后讨论了分子模拟研究和升级应用所面临的挑战和前景。本综述旨在为非常规油气研究人员和业内专业人士提供一个从微观角度理解多相页岩流体在纳米封闭空间中的分布特征和流动行为的途径。
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来源期刊
Earth-Science Reviews
Earth-Science Reviews 地学-地球科学综合
CiteScore
21.70
自引率
5.80%
发文量
294
审稿时长
15.1 weeks
期刊介绍: Covering a much wider field than the usual specialist journals, Earth Science Reviews publishes review articles dealing with all aspects of Earth Sciences, and is an important vehicle for allowing readers to see their particular interest related to the Earth Sciences as a whole.
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