Heterogeneous deformation in ductile FCC single crystals in biaxial stretching: the influence of slip system interactions

Abstract The heterogeneity of deformation in ductile FCC single crystals is investigated by both numerical simulations and an analytic approach. The constitutive behaviour is based on a generalized storage recovery model and takes into account the interactions between slip systems previously obtained by dislocation dynamics simulations. In biaxial stretching, the simulations show the activation of a large number of slip systems and their localization in mutually excluding zones. As a result, a microstructure of lamellar type is formed in the early stages of the deformation. These numerical results are complemented by a linear stability analysis showing that the heterogeneous deformation pattern is triggered by instability modes of the single crystal. Furthermore, the interaction matrix is playing a key role as the partition is found to originate from slip system interactions. The partition is driven by the strongest interaction, which is in most cases the collinear interaction. A comparison with an experimental study in simple shear yields useful information about how to check the respective strength of some interactions. The collinear interaction is not involved in that case, but its effect can be verified by reproducing the experiment on a crystal with a different orientation.