Effect of Rigidity and Parabolic Irregularity on Love Wave Propagation in Transversely Isotropic Fluid-Saturated Porous Layer Lying over a Nonhomogenous Half-Space

IF 0.6 4区工程技术 Q4 MECHANICS

Mechanics of Solids Pub Date : 2024-09-12 DOI:10.1134/S0025654424602702

Abhilasha Saini, Ravinder Kumar

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Abstract

This study investigates the behaviour of Love wave propagation within a transversely isotropic fluid saturated porous layer (TIFSPL) with rigid boundary, situated over a nonhomogeneous elastic half space. An irregularity in the shape of parabola is considered at the interface of porous layer and half space. The displacement vector and dispersion equation for propagation of Loves waves has been derived by applying Biot’s theory of elasticity, perturbation method, and Fourier Transformation method. The numerical results have been carried out to illustrate the variation of dimensionless phase velocity against dimensionless wavenumber with the help of MATLAB graphical routines for different values of inhomogeneity parameters and the ratio of depth of irregularity to the layer’s height. It has been observed that the derived dispersion equation for Love waves is affected by rigidity, wavenumber, depth of irregularity, height of layer, size and shape of irregularity, and inhomogeneity parameter. The findings from this study holds a significant importance in the field of seismology, geophysics and earthquake engineering.

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刚性和抛物线不规则性对横向各向同性流体饱和多孔层在非均质半空间上的爱波传播的影响

摘要本研究探讨了位于非均质弹性半空间上、具有刚性边界的横向各向同性流体饱和多孔层（TIFSPL）内的爱波传播行为。在多孔层和半空间的界面上考虑了抛物线形状的不规则性。通过应用 Biot 弹性理论、扰动法和傅里叶变换法，推导出了洛夫斯波传播的位移矢量和频散方程。在 MATLAB 图形例程的帮助下，针对不同的非均质性参数值和不规则深度与层高之比，对无量纲相位速度与无量纲波数的变化进行了数值计算。结果表明，推导出的爱波频散方程受刚度、波长、不规则深度、层高、不规则大小和形状以及不均匀参数的影响。这项研究的结果在地震学、地球物理学和地震工程学领域具有重要意义。

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

Mechanics of Solids 医学-力学

CiteScore

1.20

自引率

42.90%

发文量

112

审稿时长

6-12 weeks

期刊介绍： Mechanics of Solids publishes articles in the general areas of dynamics of particles and rigid bodies and the mechanics of deformable solids. The journal has a goal of being a comprehensive record of up-to-the-minute research results. The journal coverage is vibration of discrete and continuous systems; stability and optimization of mechanical systems; automatic control theory; dynamics of multiple body systems; elasticity, viscoelasticity and plasticity; mechanics of composite materials; theory of structures and structural stability; wave propagation and impact of solids; fracture mechanics; micromechanics of solids; mechanics of granular and geological materials; structure-fluid interaction; mechanical behavior of materials; gyroscopes and navigation systems; and nanomechanics. Most of the articles in the journal are theoretical and analytical. They present a blend of basic mechanics theory with analysis of contemporary technological problems.