A novel dual-heterogeneous-structure ultralight steel with high strength and large ductility

A dual-heterogeneous structure with bimodal grain size distributions of both austenite and B2 phase was developed in a novel ultralight steel by a simple rolling and annealing process. Tensile test results show that the steel annealed at 900 degrees C (denoted as A900) exhibited the superb synergy of a high specific yield strength of 160.3 MPa g cm-3, a high tensile strength of 1300 MPa, a large ductility of 39.3% and a persistently high work hardening rate, which can be mainly attributed to the heterogeneous structures caused multi-level deformation mechanisms. Detailed microstructural analysis of the deformed A900 samples unveils that with an increase of strain, the plastic deformation of individual austenite grains was governed by different factors, i.e., grain size and Schmid factor (SF) at 4.2% and 9% strains and local stress at 25% strain, while the deformation of individual B2 grains was mainly regulated by grain size at 4.2%, grain size and SF at 9% strain and local stress in the late deformation stage, which leads to the consistently high work hardening rate and large elongation. In addition, owing to the hardness difference, a high density of geometrically necessary dislocations was observed near the interfaces of austenite/B2, which also contribute to the consistently high heterogeneous deformation-induced strengthening effect and thus the outstanding mechanical properties. The present work sheds light on the dual-heterogeneous structure of the ultralight steel that can be feasibly employed, and it could guide the opti-mization of mechanical performance of a wide range of alloys for lightweight engineering.

Automated summary

A dual-heterogeneous structure with bimodal grain size distributions of both austenite and B2 phase was developed in a novel ultralight steel through a simple rolling and annealing process. The steel exhibited superb mechanical properties, including high strength and ductility, attributed to the heterogeneous structures caused by multi-level deformation mechanisms. The microstructural analysis revealed the different factors governing the plastic deformation of austenite and B2 grains, leading to a consistently high work hardening rate and large elongation. The presence of geometrically necessary dislocations near the austenite/B2 interfaces also contributed to the outstanding mechanical properties. This work sheds light on the potential of the dual-heterogeneous structure for lightweight engineering.