Shear localization in polycrystalline metal at high-strain rates with dynREamic recrystallization: Crystal plasticity modeling and texture effect

Shear localization is an important failure mode, or even the dominant mode in metals at highstrain rates. However, it is a great challenge to accurately predict the occurrence and evolution of shear localization in metals at the high-strain rate deformation. Here, a dislocation-based crystal plasticity constitutive model with a crucial mechanism of shear instability, namely dynamic recrystallization, was developed. The evolution equations of dislocation density and grain size in the process of dynamic recrystallization were proposed and incorporated into the new constitutive model. The threshold of the stored energy in crystals was used as the criterion for the occurrence of dynamic recrystallization. Dynamic compression of a nanograin Cu-Al alloy was performed using the crystal plasticity finite element method based on the new constitutive model, and good agreement of the numerical prediction with the existing experimental data validates the new constitutive model. The results show dynamic recrystallization can be a more dominant mechanism for the occurrence of shear instability than thermal softening. In addition, dynamic tension and shear of the Cu-Al alloys with five typical textures were also simulated, showing that both loading mode and texture can significantly affect the formation of shear localization. This work is helpful for us to understand the role of microstructural evolution in the formation of shear localization at high-strain rates and to design the microstructure for artificially controlling or preventing the formation of shear localization.

Automated summary

Shear localization in metals at high-strain rates is a significant failure mode, and predicting its occurrence and evolution accurately is a great challenge. A new dislocation-based crystal plasticity constitutive model with dynamic recrystallization as a crucial mechanism of shear instability was developed. The model was validated through numerical prediction and experimental data, showing that dynamic recrystallization can be a dominant mechanism for shear instability. The study also investigated the effects of loading mode and texture on shear localization in Cu-Al alloys. This work is important for understanding microstructural evolution in shear localization formation and designing microstructures to control or prevent shear localization.