Pore‐scale modelling of coupled CO2 flow and dissolution in 3D porous media for geological carbon storage

IF 4.6 1区 地球科学 Q2 ENVIRONMENTAL SCIENCES
Yongfei Yang, Jinlei Wang, Jianzhong Wang, Yingwen Li, Hai Sun, Lei Zhang, Junjie Zhong, Kai Zhang, Jun Yao
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Abstract

Abstract Dissolution trapping is one of the crucial trapping mechanisms for geological carbon storage in deep saline aquifers. The injected supercritical CO 2 (scCO 2 ) flow and dissolution processes are coupled and interact with each other. Therefore, we performed direct numerical simulations in three‐dimensional micro‐CT images of sandstones using the volume of fluid and continuous species transfer method. We investigated the coupled scCO 2 flow and dissolution processes at pore‐scale under different rock structures, capillary numbers, and rock wettability conditions. The dynamic evolution of the scCO 2 /brine phase distribution and scCO 2 concentration distribution occurring during the injection period were presented and analyzed. Complicated coupling mechanisms between scCO 2 ‐brine two‐phase flow and interphase mass transfer were also revealed. Our results showed that the scCO 2 dissolution was highly dependent on the local distribution of scCO 2 clusters. The rock with relatively high porosity and permeability would have more capacity for scCO 2 injection resulting in a faster and greater dissolution of scCO 2 in brine. The effect of capillary number on the scCO 2 dissolution process was related to the range of capillary number. The effective upscaled (macro‐scale) mass transfer coefficient ( k A ) during scCO 2 dissolution was evaluated, and the power‐law relationship between k A and Péclet number was obtained. Rock wettability was found to be another factor controlling the scCO 2 dissolution process by affecting the scCO 2 ‐brine interfacial area. Our pore‐scale study provides a deep understanding of the scCO 2 dissolution trapping mechanism, which is important to enhance the prediction of sequestration risk and improve sequestration efficiency.
用于地质碳储存的三维多孔介质中耦合CO2流动和溶解的孔隙尺度模拟
摘要溶蚀圈闭是深咸水层地质碳封存的重要圈闭机制之一。注入超临界co2 (scCO 2)的流动和溶解过程是相互耦合和相互作用的。因此,我们采用流体体积法和连续物种转移法对砂岩的三维微CT图像进行了直接数值模拟。研究了不同岩石结构、毛管数量和岩石润湿性条件下,孔隙尺度下scCO 2的耦合流动和溶解过程。介绍并分析了注入期间scCO 2 /卤水相分布和scCO 2浓度分布的动态演变过程。还揭示了scCO -卤水两相流动与相间传质之间复杂的耦合机制。我们的研究结果表明,scCO 2的溶解高度依赖于scCO 2簇的局部分布。孔隙度和渗透率相对较高的岩石具有更大的scCO注入能力,导致scCO在盐水中的溶解更快、更大。毛细管数对scCO 2溶解过程的影响与毛细管数的范围有关。考察了scCO 2溶解过程中有效上尺度(宏观尺度)传质系数(k A),得到了k A与psamclet数之间的幂律关系。岩石润湿性通过影响scCO -卤水界面面积而成为控制scCO - 2溶解过程的另一个因素。我们的孔尺度研究为深入了解scCO 2的溶解捕获机制提供了依据,这对增强固存风险的预测和提高固存效率具有重要意义。
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来源期刊
Water Resources Research
Water Resources Research 环境科学-湖沼学
CiteScore
8.80
自引率
13.00%
发文量
599
审稿时长
3.5 months
期刊介绍: Water Resources Research (WRR) is an interdisciplinary journal that focuses on hydrology and water resources. It publishes original research in the natural and social sciences of water. It emphasizes the role of water in the Earth system, including physical, chemical, biological, and ecological processes in water resources research and management, including social, policy, and public health implications. It encompasses observational, experimental, theoretical, analytical, numerical, and data-driven approaches that advance the science of water and its management. Submissions are evaluated for their novelty, accuracy, significance, and broader implications of the findings.
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