ABSTRACT
The role of grain boundary misorientation angle (GBMA) distribution on slip activity in a high-manganese austenitic steel was investigated through experiments and simulations. Crystal plasticity simulations incorporating the GBMA distribution and the corresponding dislocation–grain boundary interactions were conducted. The computational analysis revealed that the number of active slip systems decreased when GBMA distribution was taken into account owing to the larger volume of grain boundary–dislocation interactions. The current results demonstrate that the dislocation–grain boundary interactions significantly contribute to the overall hardening, and the GBMA distribution constitutes a key parameter dictating the slip activity.
Funding
Financial supports by the Turkish Academy of Sciences (TÜBA) within the Outstanding Young Scientist Award Program (GEBİP), and the Scientific and Technological Research Council of Turkey (TÜBİTAK) under grant 112M806 are gratefully acknowledged.