Understanding low-temperature microstructure and mechanical properties of a newly designed ultra-low carbon medium manganese steel

This study examines the relationship between microstructure and low-temperature mechanical properties of newly designed medium manganese steel with ultra-low carbon, low-Ni content. The microstructural features crucial for impact toughness were identified. The study indicated that post-annealing at 650 degrees C for 30 min endowed the steel with superior low-temperature mechanical properties, namely tensile strength of 914 MPa, total elongation of 37.2 %, and impact energy of 187 J at-60 degrees C. With longer intercritical annealing durations, reverted austenite transitioned from a film-like to a blocky morphology, with an increase in both volume fraction and size, accompanied by a substantial decrease in stability. High-stability reverted austenite contributed to sustained work hardening by facilitating a continuous Transformation-Induced Plasticity (TRIP) effect during steel deformation, thereby significantly enhancing the low temperature tensile properties of the steel. Furthermore, enhanced stability of reverted austenite was identified as the pivotal microstructural factor influencing impact toughness.