4.7 Article

Non-affine dissipation in polymer fracture

Journal

EXTREME MECHANICS LETTERS
Volume 59, Issue -, Pages -

Publisher

ELSEVIER
DOI: 10.1016/j.eml.2023.101955

Keywords

Viscoelasticity; Polymer; Fracture energy; Non-affine deformation; Threshold

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Viscoelasticity is a universal property in most soft solids and is often considered a major mechanism of toughening in polymeric materials. However, this study shows that there is a significant amount of energy dissipation due to non-affine deformation near the crack tip, which is attributed to the rearrangement and mutual sliding of neighboring chains caused by the rupture of a polymer chain. Various methods of reducing inter-chain friction can mitigate this non-affine dissipation, while making an elastomer more elastic can enhance it. The identification of this non-affine dissipation mechanism has implications for the development of new soft materials with both excellent elasticity and fracture toughness.
Viscoelasticity is a universal property in most soft solids. Specifically, for the fracture of polymeric materials, viscoelasticity has often been regarded as a major mechanism of toughening, and the excess fracture energy beyond the intrinsic value correlated to the stress-strain hysteresis, which is commonly used to characterize viscoelasticity in the framework of continuum mechanics. Through systematically planned experiments, the current study shows that a noticeable package of energy dissipation exists besides that associated with the hysteretic deformation. This package of energy is attributed to the highly non-affine deformation near the crack tip - the rearrangement and mutual sliding of the neighboring chains caused by the rupture of a polymer chain, which are insignificant in samples under homogeneous deformation. Various means of inter-chain-friction reduction, e.g., by applying lateral stretches, diluting the chains with solvent, or subject the material to dynamic or static fatigue, can mitigate the effect of non-affine dissipation, and bring the fracture energy down to the intrinsic threshold. In contrast, by making an elastomer more elastic, e.g., by training through cyclic loading, the non-affine dissipation remains effective, and the limiting fracture energy is significantly higher than the threshold even when the hysteresis is negligible. The identification of the non-affine-dissipation mechanism paves the way to the development of new soft materials with both excellent elasticity and significant fracture toughness.& COPY; 2023 Elsevier Ltd. All rights reserved.

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