Energy-Based Strength Theory for Soft Elastic Membranes

Abstract: In the previous studies by the authors and others, it was demonstrated that there are two possible defect growth modes and a characteristic material length for any soft material. For a pre-existing defect smaller than the material characteristic length, the energy is dissipated all around the defect as it grows and the critical load for the growth is independent of the defect size. For defects larger than the characteristic length, the growth is by cracking and the energy is dissipated along a plane. Thus, the… Show more

“…Blaise et al also constructed a new model to validate the nonlinear elastic response of rubber-like materials [ 36 ]. Pourmodheji et al applied the same energy-based argument to thin film fracture, focusing on the plural growth modes, the first one that gives the maximum critical load based on biaxial tests of natural rubber and styrene-butadiene rubber [ 37 ]. Chen et al reported strain-induced crystallization of natural rubber by biaxial stretching [ 38 ].…”

Calculation of Strain Energy Density Function Using Ogden Model and Mooney–Rivlin Model Based on Biaxial Elongation Experiments of Silicone Rubber

“…Blaise et al also constructed a new model to validate the nonlinear elastic response of rubber-like materials [ 36 ]. Pourmodheji et al applied the same energy-based argument to thin film fracture, focusing on the plural growth modes, the first one that gives the maximum critical load based on biaxial tests of natural rubber and styrene-butadiene rubber [ 37 ]. Chen et al reported strain-induced crystallization of natural rubber by biaxial stretching [ 38 ].…”

Calculation of Strain Energy Density Function Using Ogden Model and Mooney–Rivlin Model Based on Biaxial Elongation Experiments of Silicone Rubber

Failure criterion for highly stretchable elastomers under triaxial loading

Failure of soft dielectric membrane with a hole subjected to mechanical and electric loads