Abstract The influence of rolling at 77 K and 293 K to a true strain of 2.66 on the microstructure and texture evolution and mechanical behavior of a TWIP Fe-0.3C-23Mn-1.5Al steel was… Click to show full abstract
Abstract The influence of rolling at 77 K and 293 K to a true strain of 2.66 on the microstructure and texture evolution and mechanical behavior of a TWIP Fe-0.3C-23Mn-1.5Al steel was quantified. The microstructure evolution at both temperatures of deformation was associated with an increase in the dislocation density and extensive twinning, following by the development of a cell structure and shear bands. Rolling at both temperatures was associated with a formation of the Copper-type texture in the beginning of deformation and transition to the Brass-type texture during further rolling. Intensive formation of e-martensite was observed at 77 K. The transformation of twin boundaries into arbitrary high-angle grain boundaries due to interaction with lattice dislocations led to the formation of grains/subgrains with the size of 30–60 nm after cryo-rolling to a strain of 2.66. Rolling at both temperatures resulted in continuous increase of strength of the steel and decrease of ductility. The ultimate tensile strength was 1993 MPa and 1824 MPa after rolling to a true thickness strain of 2.66 at 77 K and 293 K, respectively. Qualitative analysis of contributions of different strengthening mechanisms was performed.
               
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