On modeling fracture of soft polymers

Soft polymers are ubiquitous materials in nature and as engineering materials with properties varying from rate-independent to rate-dependent depending on the crosslinking mechanisms. Current fracture toughness measures are non-unique for rate-dependent soft materials for varying loading profiles and specimen geometries. Works on modeling fracture in rate-dependent soft polymers are limited to specific pre-cracked geometries. There is no generally agreed-upon model for the fracture of soft polymers. We propose and show that a critical value of stress work $\mathit{W}_{cr}$ obtained from simple homogeneous deformation experiments can be a scalar measure of fracture resistance in soft polymers. We also develop a damage model to predict fracture in soft polymers through a generalized gradient damage framework. The energetic part of $\mathit{W}_{cr}$ is proposed as a damage initiation criterion. The fracture model is demonstrated to work well for both elastomers and viscous soft polymers by comparing model predictions against experimental results for different materials (ethylene propylene diene monomer - EPDM, EPS25 vitrimer, polyborosiloxane), a variety of specimen geometries, and loading conditions. The model is able to predict key physical phenomena and microstructural physical quantities, such as subchain dissociation energy during the fracture of soft polymers.