具有守恒定律和松弛的非等温粘弹性流动

IF 0.5 4区数学 Q4 MATHEMATICS, APPLIED

Journal of Hyperbolic Differential Equations Pub Date : 2021-04-26 DOI:10.1142/s0219891622500096

S. Boyaval, Mark Dostal'ik

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引用次数: 2

摘要

对于麦克斯韦流体的非等温粘弹性流动，我们提出了一个具有松弛源项的守恒定律系统（即平衡定律）。该系统是使用附加结构变量的超弹性体的多凸面弹性动力学的扩展。它是通过将亥姆霍兹自由能写成体积能量密度（变形梯度det F和温度的行列式的函数[公式：见正文]，如标准完美气体定律或Noble–Abel加筋气体定律）加上F的多凸面应变能量密度函数的和而获得的，[公式：见正文]和在特征时间尺度上弛豫的对称正定结构张量。我们模型的一个特点是，它统一了从超弹性固体到完美流体的各种理想材料，包括具有记忆的流体，如麦克斯韦流体。我们建立了一个严格凸的数学熵来证明系统是对称双曲的。因此，所提出的模型的另一个特点是光滑解的短时存在性和唯一性，它定义了具有以有限速度传播的波的真正因果粘弹性流。在热导体中，我们用能量通量变量的Maxwell–Cattaneo方程来补充系统。该系统仍然是对称双曲型的，并且具有有限速度波的平滑演化仍然是明确定义的。

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Non-isothermal viscoelastic flows with conservation laws and relaxation

We propose a system of conservation laws with relaxation source terms (i.e. balance laws) for non-isothermal viscoelastic flows of Maxwell fluids. The system is an extension of the polyconvex elastodynamics of hyperelastic bodies using additional structure variables. It is obtained by writing the Helmholtz free energy as the sum of a volumetric energy density (function of the determinant of the deformation gradient det F and the temperature [Formula: see text] like the standard perfect-gas law or Noble–Abel stiffened-gas law) plus a polyconvex strain energy density function of F, [Formula: see text] and of symmetric positive-definite structure tensors that relax at a characteristic time scale. One feature of our model is that it unifies various ideal materials ranging from hyperelastic solids to perfect fluids, encompassing fluids with memory like Maxwell fluids. We establish a strictly convex mathematical entropy to show that the system is symmetric-hyperbolic. Another feature of the proposed model is therefore the short-time existence and uniqueness of smooth solutions, which define genuinely causal viscoelastic flows with waves propagating at finite speed. In heat-conductors, we complement the system by a Maxwell–Cattaneo equation for an energy-flux variable. The system is still symmetric-hyperbolic, and smooth evolutions with finite-speed waves remain well-defined.

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来源期刊

Journal of Hyperbolic Differential Equations 数学-物理：数学物理

CiteScore

1.10

自引率

0.00%

发文量

审稿时长

24 months

期刊介绍： This journal publishes original research papers on nonlinear hyperbolic problems and related topics, of mathematical and/or physical interest. Specifically, it invites papers on the theory and numerical analysis of hyperbolic conservation laws and of hyperbolic partial differential equations arising in mathematical physics. The Journal welcomes contributions in: Theory of nonlinear hyperbolic systems of conservation laws, addressing the issues of well-posedness and qualitative behavior of solutions, in one or several space dimensions. Hyperbolic differential equations of mathematical physics, such as the Einstein equations of general relativity, Dirac equations, Maxwell equations, relativistic fluid models, etc. Lorentzian geometry, particularly global geometric and causal theoretic aspects of spacetimes satisfying the Einstein equations. Nonlinear hyperbolic systems arising in continuum physics such as: hyperbolic models of fluid dynamics, mixed models of transonic flows, etc. General problems that are dominated (but not exclusively driven) by finite speed phenomena, such as dissipative and dispersive perturbations of hyperbolic systems, and models from statistical mechanics and other probabilistic models relevant to the derivation of fluid dynamical equations. Convergence analysis of numerical methods for hyperbolic equations: finite difference schemes, finite volumes schemes, etc.