The effects of pore structure on wave dispersion and attenuation due to squirt flow: A dynamic stress-strain simulation on a simple digital pore-crack model

IF 3 2区 地球科学 Q1 GEOCHEMISTRY & GEOPHYSICS Geophysics Pub Date : 2024-04-05 DOI:10.1190/geo2023-0521.1
Zhifang Yang, Hong Cao, Luanxiao Zhao, Xinfei Yan, Yirong Wang, Wei Zhu
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Abstract

Squirt flow, a phenomenon typically observed in porous cracked rocks, occurs due to the contrasting compressibility between the pores and cracks, leading to the pore pressure diffusion and dissipation of wave energy. Understanding the influence of pore structure on wave dispersion and attenuation signatures due to squirt flow is essential for interpreting seismic and sonic logging data in various fields of earth and energy sciences, such as hydrocarbon exploration, geothermal energy exploitation, and CO2 sequestration. In this study, we construct a simple digital pore-crack model with varying pore structures and use a dynamic stress-strain simulation approach to characterize wave dispersion and attenuation signatures due to squirt flow. Numerical simulation suggests that, in addition to the commonly considered parameters such as porosity, crack density, and crack aspect ratio, additional pore structure parameters, such as pore size, pore aspect ratio, crack orientation, crack length, and crack width, significantly affect the wave dispersion and attenuation signatures. Increasing the pore size leads to the pronounced enhancement of attenuation magnitude and a decrease in characteristic frequency. We demonstrate that variations in crack length have a pronounced impact on attenuation magnitude, whereas crack width is decisive in controlling the characteristic frequency. Furthermore, it is found that the saturation paths (the gas filling the pore first or gas filling the crack first) considerably affect the velocity-saturation and attenuation-saturation relationship, suggesting that the coupling effects of pore structure and fluid distribution complicate the fluid pressure diffusion and wave attenuation behaviors. The presented results offer insights for deciphering pore structure parameters using attenuation- or dissipation-related seismic attributes.
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孔隙结构对喷射流引起的波扩散和衰减的影响:简单数字孔隙裂缝模型的动态应力应变模拟
喷流是在多孔裂隙岩中观察到的一种典型现象,发生的原因是孔隙和裂隙之间的可压缩性不同,导致孔隙压力扩散和波能耗散。在油气勘探、地热能开发和二氧化碳封存等地球和能源科学的各个领域,了解孔隙结构对喷流引起的波扩散和衰减特征的影响,对于解释地震和声波测井数据至关重要。在本研究中,我们构建了一个具有不同孔隙结构的简单数字孔隙裂缝模型,并使用动态应力应变模拟方法来描述喷流引起的波扩散和衰减特征。数值模拟表明,除了通常考虑的孔隙率、裂缝密度和裂缝长宽比等参数外,孔隙结构的其他参数,如孔隙尺寸、孔隙长宽比、裂缝方向、裂缝长度和裂缝宽度等,也会对波浪频散和衰减特征产生显著影响。增大孔隙尺寸会明显增强衰减幅度,降低特征频率。我们证明,裂纹长度的变化对衰减幅度有明显影响,而裂纹宽度则对控制特征频率起着决定性作用。此外,我们还发现饱和路径(气体先充满孔隙或气体先充满裂缝)在很大程度上影响着速度-饱和度和衰减-饱和度关系,这表明孔隙结构和流体分布的耦合效应使流体压力扩散和波衰减行为变得复杂。这些结果为利用与衰减或耗散相关的地震属性解读孔隙结构参数提供了启示。
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来源期刊
Geophysics
Geophysics 地学-地球化学与地球物理
CiteScore
6.90
自引率
18.20%
发文量
354
审稿时长
3 months
期刊介绍: Geophysics, published by the Society of Exploration Geophysicists since 1936, is an archival journal encompassing all aspects of research, exploration, and education in applied geophysics. Geophysics articles, generally more than 275 per year in six issues, cover the entire spectrum of geophysical methods, including seismology, potential fields, electromagnetics, and borehole measurements. Geophysics, a bimonthly, provides theoretical and mathematical tools needed to reproduce depicted work, encouraging further development and research. Geophysics papers, drawn from industry and academia, undergo a rigorous peer-review process to validate the described methods and conclusions and ensure the highest editorial and production quality. Geophysics editors strongly encourage the use of real data, including actual case histories, to highlight current technology and tutorials to stimulate ideas. Some issues feature a section of solicited papers on a particular subject of current interest. Recent special sections focused on seismic anisotropy, subsalt exploration and development, and microseismic monitoring. The PDF format of each Geophysics paper is the official version of record.
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