Mechanochemistry unveils stress transfer during sacrificial bond fracture of tough multiple network elastomers
Yinjun Chen, Gabriel E. Sanoja, Costantino Creton
Abstract
activated SP) fluorescence by confocal microscopy shows that such microcrack formation is also active at the crack tip even for materials that do not exhibit macroscopic necking. Additionally, we demonstrate that when the ethyl acrylate monomer is replaced by hexyl methacrylate in the first network, preventing molecular connections between the two networks, the stress transmission is less efficient. This study outlines the different roles played by these multiple networks in the onset of fracture and provides molecular insights for the construction of molecular models of fracture of elastomers.
Topics & Concepts
MechanochemistryElastomerMaterials scienceFracture (geology)Stress (linguistics)Composite materialPolymer scienceNanotechnologyPhilosophyLinguisticsPolymer Nanocomposites and PropertiesPolymer composites and self-healingTribology and Wear Analysis