Unraveling the Complex Dynamics of Fluid Flow in Porous Media: Effects of Viscosity, Porosity, and Inertia on the Motion of Fluids

IF 3.3 3区数学 Q1 MATHEMATICS, INTERDISCIPLINARY APPLICATIONS

Fractals-Complex Geometry Patterns and Scaling in Nature and Society Pub Date : 2023-10-17 DOI:10.1142/s0218348x23402028

Raghda A. M. Attia, Suleman H. Alfalqi, Jameel F. Alzaidi, Mostafa M. A. Khater

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引用次数: 0

Abstract

This study investigates novel solitary wave solutions of the Gilson–Pickering ([Formula: see text]) equation, which is a model that describes the motion of a fluid in a porous medium. An analytical scheme is applied to construct these solutions, utilizing the extended Khater method in conjunction with the homogenous balance technique. The derived expressions for the solitary wave solutions are exact and are presented in terms of hyperbolic functions. The [Formula: see text] equation is valuable for a wide range of applications, including oil and gas reservoir engineering, groundwater flow, and flow in biological tissues. Additionally, this model is employed to describe the behavior of waves in various physical systems such as fluids and plasmas. Specifically, it models the propagation of dispersive waves in a media that exhibits both dispersion and dissipation. To ensure the accuracy of the constructed solutions, a numerical scheme is employed. The properties of the solitary wave solutions are analyzed, and their physical implications are explored. The results of this investigation reveal a rich variety of solitary wave solutions that exhibit interesting behaviors, including oscillatory and non-oscillatory behavior, which are elucidated through various types of distinct graphs. Consequently, this study provides significant insights into the behavior of fluid flow in porous media and its applications in various fields, including oil and gas reservoir engineering and groundwater flow modeling. The analytical and numerical methods employed in this investigation demonstrate their potential for studying nonlinear evolution equations and their applications in the physical sciences.

查看原文本刊更多论文

揭示多孔介质中流体流动的复杂动力学:粘度、孔隙度和惯性对流体运动的影响

本研究探讨了Gilson-Pickering(公式见原文)方程的新颖孤波解，该方程是描述流体在多孔介质中的运动的模型。利用扩展的Khater方法结合均匀平衡技术，采用一种解析方案来构建这些解。孤立波解的导出表达式是精确的，并以双曲函数的形式表示。[公式:见文本]方程具有广泛的应用价值，包括油气储层工程、地下水流动和生物组织中的流动。此外，该模型还可用于描述各种物理系统(如流体和等离子体)中波的行为。具体地说，它模拟了色散波在同时表现出色散和耗散的介质中的传播。为了保证构造解的准确性，采用了数值格式。分析了孤立波解的性质，并探讨了它们的物理意义。这项研究的结果揭示了各种各样的孤立波解，它们表现出有趣的行为，包括振荡和非振荡行为，这些行为通过各种类型的不同的图来阐明。因此，该研究为研究多孔介质中的流体流动行为及其在各个领域的应用提供了重要的见解，包括油气储层工程和地下水流动建模。本研究中所采用的解析和数值方法证明了它们在研究非线性演化方程及其在物理科学中的应用方面的潜力。

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

Fractals-Complex Geometry Patterns and Scaling in Nature and Society 数学-数学跨学科应用

CiteScore

7.40

自引率

23.40%

发文量

319

审稿时长

>12 weeks

期刊介绍： The investigation of phenomena involving complex geometry, patterns and scaling has gone through a spectacular development and applications in the past decades. For this relatively short time, geometrical and/or temporal scaling have been shown to represent the common aspects of many processes occurring in an unusually diverse range of fields including physics, mathematics, biology, chemistry, economics, engineering and technology, and human behavior. As a rule, the complex nature of a phenomenon is manifested in the underlying intricate geometry which in most of the cases can be described in terms of objects with non-integer (fractal) dimension. In other cases, the distribution of events in time or various other quantities show specific scaling behavior, thus providing a better understanding of the relevant factors determining the given processes. Using fractal geometry and scaling as a language in the related theoretical, numerical and experimental investigations, it has been possible to get a deeper insight into previously intractable problems. Among many others, a better understanding of growth phenomena, turbulence, iterative functions, colloidal aggregation, biological pattern formation, stock markets and inhomogeneous materials has emerged through the application of such concepts as scale invariance, self-affinity and multifractality. The main challenge of the journal devoted exclusively to the above kinds of phenomena lies in its interdisciplinary nature; it is our commitment to bring together the most recent developments in these fields so that a fruitful interaction of various approaches and scientific views on complex spatial and temporal behaviors in both nature and society could take place.