On linear non-local thermo-viscoelastic waves in fluids

IF 1 Q4 MECHANICS

Mathematics and Mechanics of Complex Systems Pub Date : 2018-10-01 DOI:10.2140/MEMOCS.2018.6.321

J. Goddard

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引用次数: 2

Abstract

The following is an elaboration on the linear non-local model of viscoelastic fluids proposed in a previous work (Goddard, 2010, Int. J. Eng. Sci. 48, 1279). As a recapitulation of that work, the basic theory is presented in terms of the temporal frequency and spatial wave number in the Laplace-Fourier domain. Taylor-series expansions in these variables provides a weakly non-local theory in spatio-temporal gradients that is more comprehensive than the “bi-velocity” model of Brenner. The linearized Chapman-Enskog kinetic theory is shown to provide a confirmation of the more general theory, from which one can reconstruct a fully non-local integral model. Following the work of Davis and Brenner (2012, J. Acoust. Soc. Am. 132, 2963). the general theory is employed to derive dispersion relations for acoustic, thermal and shear-wave propagation in compressible viscoelastic fluids. At Burnett order the Chapman-Enskog theory gives a cubic polynomial in wave number squared which reduces in the dissipative quasi-static limit to a quadratic like that given by the classical Navier-Stokes-Fourier model and the bi-velocity modification of that model. With minor modification, the present analysis applies to viscoelastic shear and dilatational wave propagation in solids with higher-gradient and Cosserat effects, where it may, for example, find application to the field of rotational seismology.

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流体中的线性非局部热粘弹性波

以下是对先前工作中提出的粘弹性流体线性非局部模型的阐述(Goddard, 2010, Int. 1)。j·英格。科学学报，48,1279)。作为这项工作的重述，基本理论是在拉普拉斯-傅立叶域中的时间频率和空间波数提出的。这些变量的泰勒级数展开提供了一个时空梯度的弱非局部理论，比Brenner的“双速度”模型更全面。线性化的Chapman-Enskog动力学理论证实了更一般的理论，由此可以重建一个完全非局部积分模型。在Davis和Brenner(2012)的研究之后，J. Acoust。Soc。Am. 132, 2963)。利用一般理论推导了可压缩粘弹性流体中声波、热波和剪切波传播的色散关系。在Burnett阶，Chapman-Enskog理论给出了波数平方的三次多项式，它将耗散的准静态极限简化为二次多项式，类似于经典的Navier-Stokes-Fourier模型和该模型的双速度修正。稍加修改，本分析适用于具有更高梯度和coserat效应的固体中的粘弹性剪切和膨胀波传播，例如，它可以应用于旋转地震学领域。

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

Mathematics and Mechanics of Complex Systems MECHANICS-

CiteScore

3.00

自引率

5.30%

发文量

期刊介绍： MEMOCS is a publication of the International Research Center for the Mathematics and Mechanics of Complex Systems. It publishes articles from diverse scientific fields with a specific emphasis on mechanics. Articles must rely on the application or development of rigorous mathematical methods. The journal intends to foster a multidisciplinary approach to knowledge firmly based on mathematical foundations. It will serve as a forum where scientists from different disciplines meet to share a common, rational vision of science and technology. It intends to support and divulge research whose primary goal is to develop mathematical methods and tools for the study of complexity. The journal will also foster and publish original research in related areas of mathematics of proven applicability, such as variational methods, numerical methods, and optimization techniques. Besides their intrinsic interest, such treatments can become heuristic and epistemological tools for further investigations, and provide methods for deriving predictions from postulated theories. Papers focusing on and clarifying aspects of the history of mathematics and science are also welcome. All methodologies and points of view, if rigorously applied, will be considered.