Santarossa A, Varela Rosales N, Steinmann P, Moreno-Mateos MA (2026)
Publication Type: Journal article
Publication year: 2026
Book Volume: 212
Pages Range: 106549
Article Number: 106549
DOI: 10.1016/j.jmps.2026.106549
Soft fracture in highly deformable solids involves both geometric and constitutive nonlinearities, necessitating advanced theoretical and computational frameworks for its accurate understanding. Tensile fractures subjected to mixed-mode loading deviate from their original planar shape, resulting in echelon crack patterns. When out-of-plane shear is superimposed, a crack front segments into an array of tilted facets. The physical interpretation of echelon cracks is only marginally understood, and it is typically based on rather limited approaches within Linear Elastic Fracture Mechanics. Here, we investigate mixed-mode I + III fracture within the framework of configurational mechanics. Using the Configurational Force Method, implemented as a post-processing algorithm in a finite-element-based simulation, we compute the configurational forces that act at the crack tip of model fracture geometries prior to propagation. Configurational forces characterize both the magnitude and direction of propagation for maximal energy release rate. Our results reveal the complex interactions between tilted facets and their critical role in shaping the fracture morphology. We also examine the effects of facet coalescence—driven by the growth of the parent crack—where neighboring facets merge into a unified crack front. These findings provide new insights into fracture processes in soft, quasi-brittle materials under mixed-mode loading.
APA:
Santarossa, A., Varela Rosales, N., Steinmann, P., & Moreno-Mateos, M.A. (2026). Configurational forces explain echelon cracks in soft materials. Journal of the Mechanics and Physics of Solids, 212, 106549. https://doi.org/10.1016/j.jmps.2026.106549
MLA:
Santarossa, Angel, et al. "Configurational forces explain echelon cracks in soft materials." Journal of the Mechanics and Physics of Solids 212 (2026): 106549.
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