On the energy decomposition in variational phase-field models for brittle fracture under multi-axial stress states

IF 2.2 3区工程技术 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY

International Journal of Fracture Pub Date : 2024-04-22 DOI:10.1007/s10704-024-00763-w

F. Vicentini, C. Zolesi, P. Carrara, C. Maurini, L. De Lorenzis

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Abstract

Phase-field models of brittle fracture are typically endowed with a decomposition of the elastic strain energy density in order to realistically describe fracture under multi-axial stress states. In this contribution, we identify the essential requirements for this decomposition to correctly describe both nucleation and propagation of cracks. Discussing the evolution of the elastic domains in the strain and stress spaces as damage evolves, we highlight the links between the nucleation and propagation conditions and the modulation of the elastic energy with the phase-field variable. In light of the identified requirements, we review some of the existing energy decompositions, showcasing their merits and limitations, and conclude that none of them is able to fulfil all requirements. As a partial remedy to this outcome, we propose a new energy decomposition, denoted as star-convex model, which involves a minimal modification of the volumetric-deviatoric decomposition. Predictions of the star-convex model are compared with those of the existing models with different numerical tests encompassing both nucleation and propagation.

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论多轴应力状态下脆性断裂的变分相场模型中的能量分解

脆性断裂的相场模型通常具有弹性应变能密度分解，以便真实地描述多轴应力状态下的断裂。在本文中，我们确定了该分解的基本要求，以正确描述裂纹的成核和扩展。在讨论应变和应力空间中的弹性域随着损伤的发展而演变时，我们强调了成核和扩展条件之间的联系，以及弹性能量与相场变量之间的调制关系。根据已确定的要求，我们回顾了一些现有的能量分解方法，展示了它们的优点和局限性，并得出结论：没有一种能量分解方法能够满足所有要求。作为对这一结果的部分补救，我们提出了一种新的能量分解方法，称为星凸模型，它涉及对体积-偏差分解方法的最小修改。星凸模型的预测结果与现有模型的预测结果进行了比较，并进行了包括成核和传播在内的不同数值测试。

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来源期刊

International Journal of Fracture 物理-材料科学：综合

CiteScore

4.80

自引率

8.00%

发文量

审稿时长

13.5 months

期刊介绍： The International Journal of Fracture is an outlet for original analytical, numerical and experimental contributions which provide improved understanding of the mechanisms of micro and macro fracture in all materials, and their engineering implications. The Journal is pleased to receive papers from engineers and scientists working in various aspects of fracture. Contributions emphasizing empirical correlations, unanalyzed experimental results or routine numerical computations, while representing important necessary aspects of certain fatigue, strength, and fracture analyses, will normally be discouraged; occasional review papers in these as well as other areas are welcomed. Innovative and in-depth engineering applications of fracture theory are also encouraged. In addition, the Journal welcomes, for rapid publication, Brief Notes in Fracture and Micromechanics which serve the Journal''s Objective. Brief Notes include: Brief presentation of a new idea, concept or method; new experimental observations or methods of significance; short notes of quality that do not amount to full length papers; discussion of previously published work in the Journal, and Brief Notes Errata.