Variational Models with Eulerian–Lagrangian Formulation Allowing for Material Failure

IF 2.6 1区数学 Q1 MATHEMATICS, APPLIED

Archive for Rational Mechanics and Analysis Pub Date : 2024-12-17 DOI:10.1007/s00205-024-02076-7

Marco Bresciani, Manuel Friedrich, Carlos Mora-Corral

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引用次数: 0

Abstract

We investigate the existence of minimizers of variational models featuring Eulerian–Lagrangian formulations. We consider energy functionals depending on the deformation of a body, defined on its reference configuration, and an Eulerian map defined on the unknown deformed configuration in the actual space. Our existence theory moves beyond the purely elastic setting and accounts for material failure by addressing free-discontinuity problems where both deformations and Eulerian fields are allowed to jump. To do this, we build upon the work of Henao and Mora-Corral regarding the variational modeling of cavitation and fracture in nonlinear elasticity. Two main settings are considered by modeling deformations as Sobolev and SBV-maps, respectively. The regularity of Eulerian maps is specified in each of these two settings according to the geometric and topological properties of the deformed configuration. We present some applications to specific models of liquid crystals, phase transitions, and ferromagnetic elastomers. Effectiveness and limitations of the theory are illustrated by means of explicit examples.

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我们研究了以欧拉-拉格朗日公式为特征的变分模型的最小值存在性。我们考虑的能量函数取决于定义在参考构型上的物体变形，以及定义在实际空间中未知变形构型上的欧拉图。我们的存在理论超越了纯粹的弹性设置，通过解决允许变形和欧拉场跳跃的自由不连续问题来解释材料失效。为此，我们以 Henao 和 Mora-Corral 关于非线性弹性中空化和断裂的变分建模工作为基础。通过将变形分别建模为 Sobolev 映射和 SBV 映射，我们考虑了两种主要情况。在这两种情况下，欧拉图的正则性都是根据变形构型的几何和拓扑特性来确定的。我们介绍了液晶、相变和铁磁弹性体特定模型的一些应用。通过明确的例子说明了该理论的有效性和局限性。

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来源期刊

Archive for Rational Mechanics and Analysis 物理-力学

CiteScore

5.10

自引率

8.00%

发文量

审稿时长

4-8 weeks

期刊介绍： The Archive for Rational Mechanics and Analysis nourishes the discipline of mechanics as a deductive, mathematical science in the classical tradition and promotes analysis, particularly in the context of application. Its purpose is to give rapid and full publication to research of exceptional moment, depth and permanence.