A post mortem analysis of the strain-induced crystallization effects on fatigue of elastomers
B. Ruellan (IPR), Jean-Benoit Le Cam (IPR), E. Robin (LEMMA), I., Jeanneau (IPR), F. Canevet, G. Mauvoisin (LGCGM), D. Loison

TL;DR
This study investigates how strain-induced crystallization affects fatigue crack growth in natural rubber, revealing temperature-dependent crystallization and strain regimes that influence fatigue resistance.
Contribution
It provides a detailed post-mortem analysis of SIC effects on fatigue in NR, identifying temperature and strain conditions that influence crystallization and crack growth.
Findings
Striation formation requires a certain crystallinity level.
No striations observed at 90°C, indicating temperature dependence.
Two strain regimes identified at 23°C, affecting fatigue behavior.
Abstract
Natural rubber (NR) is the most commonly used elastomer in the automotive industry thanks to its outstanding fatigue resistance. Strain-induced crystallization (SIC) is found to play a role of paramount importance in the great crack growth resistance of NR [1]. Typically, NR exhibits a lifetime reinforcement for non-relaxing loadings [2-3]. At the microscopic scale, fatigue striations were observed on the fracture surface of Diabolo samples tested in fatigue. They are the signature of SIC [2,4,5]. In order to provide additional information on the role of SIC in the fatigue crack growth resistance of NR, striations are investigated through post-mortem analysis after fatigue experiments using loading ranging from-0.25 to 0.25. No striation was observed in the case of tests performed at 90{\textdegree}C. This confirms that the formation of striation requires a certain crystallinity level…
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Taxonomy
TopicsElasticity and Material Modeling · Polymer Nanocomposites and Properties · Polymer crystallization and properties
