Litcius/Paper detail

A network model of transient polymers: exploring the micromechanics of nonlinear viscoelasticity

Robert J. Wagner, Ethan Hobbs, Franck J. Vernerey

2021Soft Matter30 citationsDOI

Abstract

a Langevin model, slip-bond dissociation through Eyring's model, and spatiotemporally-dependent bond attachment based on scaling theory. Applying incompressible, uniaxial tension to representative volume elements at a range of constant strain rates and network connectivities, we then compare the mechanical response of these networks to that predicted by the transient network theory. Ultimately, we find that the idealized continuum approach remains suitable for networks with high chain concentrations when deformed at low strain rates, yet the mesoscale model proves necessary for the exploration of localized stochastic events, such as variability of the bond kinetics, or the nucleation of micro-cavities that likely conceive damage and fracture.

Topics & Concepts

MicromechanicsViscoelasticityMesoscopic physicsNonlinear systemTransient (computer programming)Materials scienceMechanicsStatistical physicsComputer scienceClassical mechanicsPhysicsComposite materialCondensed matter physicsComposite numberOperating systemQuantum mechanicsForce Microscopy Techniques and ApplicationsRheology and Fluid Dynamics StudiesCarbon Nanotubes in Composites