How crack twisting in bouligand structures lead to damage delocalization and toughening

IF 4.3 3区 工程技术 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY Extreme Mechanics Letters Pub Date : 2024-07-05 DOI:10.1016/j.eml.2024.102190
Alvaro Garnica , Emiliano Aparicio , Mehdi Shishehbor , David Kisailus , Eduardo M. Bringa , Pablo D. Zavattieri
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Abstract

Fiber-reinforced composites with Bouligand structure exhibit remarkable mechanical properties due to the intricate arrangement of fibers. In this study, we propose a coarse-graining (CG) model specifically developed to capture the behavior of Bouligand structures. The model incorporates bonded interactions to represent the fibers and employs a double-well potential to describe the non-bonded interactions within the matrix. Using this model, we investigate the fracture mechanics properties of Bouligand structures, with a particular focus on the emergence of helicoidal cracks. Our primary objective is to validate the hypothesis that these twisting cracks, which align with the fiber orientation, contribute to local hardening mechanisms. By hindering the growth of individual cracks, these hardening mechanisms facilitate the nucleation and growth of multiple cracks, thereby promoting a delocalization effect within the material. Through extensive simulations and analysis, we confirm the validity of our hypothesis. The presence of twisting cracks indeed induces local hardening mechanisms, making it more challenging for individual cracks to propagate. This phenomenon effectively spreads the damage, dissipating energy across larger volumes of the material. Consequently, the toughness of these Bouligand structures is enhanced, as this delocalization effect effectively mitigates the concentration of damage. These findings provide valuable insights into the fracture behavior of Bouligand structures and shed light into the underlying mechanisms responsible for their exceptional mechanical performance. Moreover, our CG model offers a practical and efficient approach to studying and understanding the fracture mechanics properties of complex fiber-reinforced composites. The ability to simulate and analyze the behavior of helicoidal cracks within Bouligand structures opens up new avenues for designing and optimizing advanced materials with enhanced toughness and damage resistance.

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双梁结构中的裂纹扭曲如何导致损伤分散和增韧
由于纤维排列错综复杂,具有 Bouligand 结构的纤维增强复合材料表现出卓越的机械性能。在本研究中,我们提出了一种粗粒化(CG)模型,专门用于捕捉 Bouligand 结构的行为。该模型采用键合相互作用来表示纤维,并采用双阱势能来描述基体内的非键合相互作用。利用该模型,我们研究了 Bouligand 结构的断裂力学特性,尤其关注螺旋形裂纹的出现。我们的主要目标是验证以下假设:这些与纤维取向一致的扭曲裂纹有助于局部硬化机制。通过阻碍单个裂纹的生长,这些硬化机制促进了多个裂纹的成核和生长,从而促进了材料内部的分散效应。通过大量的模拟和分析,我们证实了假设的正确性。扭曲裂纹的存在确实诱发了局部硬化机制,使单个裂纹的扩展更具挑战性。这种现象有效地分散了损伤,在材料的更大范围内消散能量。因此,这些 Bouligand 结构的韧性得到了增强,因为这种分散效应有效地缓解了损伤的集中。这些发现为了解 Bouligand 结构的断裂行为提供了宝贵的见解,并揭示了造成其卓越机械性能的内在机制。此外,我们的 CG 模型为研究和了解复杂纤维增强复合材料的断裂力学特性提供了一种实用而高效的方法。模拟和分析 Bouligand 结构中螺旋形裂纹行为的能力为设计和优化具有更高韧性和抗破坏性的先进材料开辟了新的途径。
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来源期刊
Extreme Mechanics Letters
Extreme Mechanics Letters Engineering-Mechanics of Materials
CiteScore
9.20
自引率
4.30%
发文量
179
审稿时长
45 days
期刊介绍: Extreme Mechanics Letters (EML) enables rapid communication of research that highlights the role of mechanics in multi-disciplinary areas across materials science, physics, chemistry, biology, medicine and engineering. Emphasis is on the impact, depth and originality of new concepts, methods and observations at the forefront of applied sciences.
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