Fresh considerations regarding time-dependent elastomeric fracture

The fracture behavior of polymers in elastomeric state exhibits rich characteristics. Stretch rate and temperature can independently, as well as in combination, influence how such polymeric networks resist crack initiation and propagation. The strong rate and temperature dependencies of tensile stre...

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Bibliographic Details
Published in:Extreme Mechanics Letters 2025-01, Vol.74, p.102277, Article 102277
Main Authors: Wang, Shi-Qing, Fan, Zehao, Siavoshani, Asal, Wang, Ming-chi, Wang, Junpeng
Format: Article
Language:English
Subjects:
Elastomeric fracture
Elastomeric rupture
Internal clock
Tensile strength
Toughness
Wg number
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Summary:The fracture behavior of polymers in elastomeric state exhibits rich characteristics. Stretch rate and temperature can independently, as well as in combination, influence how such polymeric networks resist crack initiation and propagation. The strong rate and temperature dependencies of tensile strength and toughness in absence of high viscoelasticity, previously shown to occur in Rubber Chem&Tech 96, 530, 2023 and plausibly in J. Polym. Sci. 18, 189, 1955 and 32, 99, 1958 are also observed in rate-sensitive elastomers. This work aims to propose, at a conceptual level, a general understanding of elastomeric fracture by addressing the considerable confusion surrounding the relationship between crack growth rate (vc) and Griffth-Irwin's energy release rate (Gc) in different elastomeric systems. Our fracture tests demonstrate that (a) crack propagation velocity vc varies with the applied loading level produced by either stepwise or continuous stretching, (b) emergent entanglement effectively modifies network structure and the relationship between vc and Gc, and (c) temperature T affects vc at a given load. We conclude that the magnitude of imposed strain, from which Gc may be evaluated, prescribes the level of bond tension in load-bearing network strands and dictates bond dissociation kinetics. Consequently, crack growth rate depends explicitly on loading level (e.g., Gc) and temperature. In the relationship between vc and Gc, vc is the effect and Gc is the cause, contrary to the previous viewpoint.
ISSN:2352-4316
2352-4316
DOI:10.1016/j.eml.2024.102277