Mechanisms of damage and fracture of aramid fibers: Focus on the role of microfibril cooperativity in fracture toughness

IF 2.702 Q1 Materials Science
Clotilde Richard, Bruno Bresson, Maxime Bès, Laura Schittecatte, Solène Le Roux, Nizar Didane, François Bataille, Sébastien Joannès, Alba Marcellan
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引用次数: 0

Abstract

Pushing the limits of synthetic polymers in terms of stiffness and strength, aromatic polyamide fibers–like Kevlar®–are used for demanding applications in the form of fiber assemblies as ropes. The unique mechanical performance of aramid fiber is intimately linked to its hierarchical structure and orientation, induced during the spinning process. Surprisingly, after nearly 60 years of heavy use, very little is known about damage mechanisms and rational explanation of such high resistance. We report an experimental investigation of the fiber damage mechanisms at the single fiber scale (diameter ≅ 10 μm) with the aim to establish a link with the microstructure. Damage mechanisms and crack propagation are observed in situ for the first time and unveil a widespread damage over the entire length of the fiber in the form of a network of transverse and longitudinal cracks. These observations make it possible to draw a novel scenario of fracture that mitigates the small strain failure hypothesis. To shed light on the crucial role of microfibril cooperativity in fracture toughness, a slight twist is applied to the single fiber to promote tortuosity and frictional contacts between microfibrils. Statistical fracture analysis demonstrated the beneficial impact of such torsion on early failure events, since lowest fracture stresses are shifted to higher stresses.

Abstract Image

芳纶纤维的损伤和断裂机理:聚焦微纤维协同性在断裂韧性中的作用
芳香族聚酰胺纤维(如Kevlar®)在硬度和强度方面突破了合成聚合物的极限,以纤维组件的形式用作绳索,用于要求苛刻的应用。芳纶纤维独特的力学性能与其在纺丝过程中产生的分级结构和取向密切相关。令人惊讶的是,在将近60岁之后 经过多年的大量使用,人们对这种高阻力的损伤机制和合理解释知之甚少。我们报道了单纤维尺度(直径 ≅ 10 μm),目的是建立与微观结构的联系。首次在现场观察到损伤机制和裂纹扩展,并揭示了在纤维的整个长度上以横向和纵向裂纹网络的形式存在的广泛损伤。这些观察结果使得绘制一个新的断裂场景成为可能,该场景缓解了小应变失效假设。为了阐明微纤维协同性在断裂韧性中的关键作用,对单根纤维施加轻微的扭曲,以促进微纤维之间的弯曲和摩擦接触。统计断裂分析证明了这种扭转对早期失效事件的有益影响,因为最低的断裂应力会转移到更高的应力。
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来源期刊
CiteScore
5.20
自引率
0.00%
发文量
0
审稿时长
1.8 months
期刊介绍: Part A: Polymer Chemistry is devoted to studies in fundamental organic polymer chemistry and physical organic chemistry. This includes all related topics (such as organic, bioorganic, bioinorganic and biological chemistry of monomers, polymers, oligomers and model compounds, inorganic and organometallic chemistry for catalysts, mechanistic studies, supramolecular chemistry aspects relevant to polymer...
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