Phase-field simulation and coupled criterion link echelon cracks to internal length in antiplane shear
Gergely Molnár, Aurélien Doitrand, Véronique Lazarus
Abstract
This paper provides a comprehensive numerical analysis of daughter crack localization in pure antiplane shear. Although antiplane shear fracture is important in various industrial applications, understanding the morphology of the resulting fragmentation remains challenging. The paper develops innovative phase-field models to induce the facets using a small spatial variation in the toughness field and examines the impact of numerical and material parameters on the newly formed daughter cracks’ shape and spacing. Through meticulous comparison to the coupled criterion, the paper reveals a compelling connection between the internal length-scale of damage regularization , Irwin’s length and the facet crack spacing. Furthermore, the effect of Poisson’s ratio on the crack form and spacing is investigated: the results reveal a significant influence and showcase comparable initiation distances between the numerical simulations and experimental measurements in pure antiplane loading. • Phase-field models reveal daughter crack morphology in pure antiplane shear. • Link found between regularization length, Irwin’s length, and facet crack spacing. • Poisson’s ratio’s impact on crack form and spacing identified. • Comparisons highlight similar initiation distances to experimental measurements.