Artículos de revistas
Strain path dependence of anisotropic microstructure evolution on low Stacking Fault Energy F138 steel
Fecha
2017-06Registro en:
de Vincentis, Natalia Soledad; Avalos, Martina Cecilia; Kliauga, A.; Brokmeier, H. G.; Bolmaro, Raul Eduardo; Strain path dependence of anisotropic microstructure evolution on low Stacking Fault Energy F138 steel; Elsevier Science Sa; Materials Science and Engineering A: Structural Materials: Properties, Microstructure and Processing; 698; 6-2017; 1-11
0921-5093
CONICET Digital
CONICET
Autor
de Vincentis, Natalia Soledad
Avalos, Martina Cecilia
Kliauga, A.
Brokmeier, H. G.
Bolmaro, Raul Eduardo
Resumen
Severe Plastic Deformation (SPD) techniques are widely used nowadays because of the mechanical properties improvements caused by grain refinement and development of dislocation arrays. Diffraction techniques can be used to assess the changes registered in the microstructure through these methods. Two sets of samples of F138 austenitic stainless steel were analyzed in this paper: one set was deformed by ECAE up to two pressings at room temperature, and the other set was cold rolled to 70% reduction and annealed at 600, 700, 800 and 900 °C for 1 h. The microstructural changes were determined using X-Ray diffraction and EBSD, combining both, global and local information and characterizing domain sizes, dislocation and stacking fault densities and misorientation degree and distribution caused by the different thermomechanical processing. It was observed that, despite cold rolling and 2 ECAE passes rendered rather similar von Mises deformations, the microstructure through each deformation method was different: 2 ECAE passes seem to be more effective for grain refinement and generation of equiaxed domains than cold rolling. The more significant twin activation observed in the former sample, because of continuous strain path change, may explain the difference, although dislocation densities and mechanical properties did not differ substantially for both deformation methods.