Percolation without trapping: How Ostwald ripening during two-phase displacement in porous media alters capillary pressure and relative permeability.

IF 2.2 3区物理与天体物理 Q2 PHYSICS, FLUIDS & PLASMAS

Physical Review E Pub Date : 2024-09-01 DOI:10.1103/PhysRevE.110.035105

Ademola Isaac Adebimpe, Sajjad Foroughi, Branko Bijeljic, Martin J Blunt

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引用次数: 0

Abstract

Conventional measurements of two-phase flow in porous media often use completely immiscible fluids, or are performed over time scales of days to weeks. If applied to the study of gas storage and recovery, these measurements do not properly account for Ostwald ripening, significantly overestimating the amount of trapping and hysteresis. When there is transport of dissolved species in the aqueous phase, local capillary equilibrium is achieved: this may take weeks to months on the centimeter-sized samples on which measurements are performed. However, in most subsurface applications where the two phases reside for many years, equilibrium can be achieved. We demonstrate that in this case, two-phase displacement in porous media needs to be modeled as percolation without trapping. A pore network model is used to quantify how to convert measurements of trapped saturation, capillary pressure and relative permeability made ignoring Ostwald ripening to account for this effect. We show that conventional measurements overestimate the amount of capillary trapping by 20-25%.

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无截留的渗流：多孔介质中两相置换过程中的奥斯特瓦尔德熟化如何改变毛细管压力和相对渗透性。

多孔介质中两相流动的传统测量通常使用完全不相溶的流体，或者在数天至数周的时间尺度内进行。如果将这些测量方法应用于气体储存和回收研究，则无法正确考虑奥斯特瓦尔德熟化，从而大大高估了捕集和滞后的量。当水相中存在溶解物种的迁移时，就会实现局部毛细管平衡：在进行测量的厘米大小的样本上，这可能需要数周到数月的时间。不过，在大多数地下应用中，两相驻留多年，就可以达到平衡。我们证明，在这种情况下，多孔介质中的两相位移需要建模为无捕集的渗流。我们使用一个孔隙网络模型来量化如何转换忽略奥斯特瓦尔德熟化的捕集饱和度、毛细管压力和相对渗透率测量值，以考虑这种效应。结果表明，传统测量方法高估了 20-25% 的毛细管截留量。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Physical Review E PHYSICS, FLUIDS & PLASMASPHYSICS, MATHEMAT-PHYSICS, MATHEMATICAL

CiteScore

4.50

自引率

16.70%

发文量

2110

期刊介绍： Physical Review E (PRE), broad and interdisciplinary in scope, focuses on collective phenomena of many-body systems, with statistical physics and nonlinear dynamics as the central themes of the journal. Physical Review E publishes recent developments in biological and soft matter physics including granular materials, colloids, complex fluids, liquid crystals, and polymers. The journal covers fluid dynamics and plasma physics and includes sections on computational and interdisciplinary physics, for example, complex networks.