Microstructure evolution and mechanical behavior of Fe-Mn-Al-C low-density steel upon aging

This study focuses on the microstructure's evolution upon different aging conditions of a high-strength lowdensity steel with a composition of Fe-28Mn-9Al-1C. The steel is hot rolled, subsequently quenched without any solution treatment, and then aged under different conditions. The microstructure of the samples was studied by means of Scanning Electron Microscopy, Electron Backscatter Diffraction, and Transmission Electron Microscopy. The aging treatment leads to the formation of an ordered face-centered cubic L12 phase named x-carbide. This study aims to characterize the formation and growth of these x-carbides qualitatively and quantitatively under different aging conditions. Then, an effort is made to relate the fraction and size of this phase with the tensile properties of the steel to determine the optimal aging conditions that will lead to a good combination of strength and ductility. It has been found that the x-carbides start to form intragranularly through concentration fluctuations of aluminum and manganese inside the austenite grain. Then, with the process of spinodal decomposition, they grow in size coherently with the matrix. During this process, the strength and hardness of the steel increase while maintaining a relatively high elongation. The best combination of high strength and ductility was achieved at the aging condition of 8 h at 550 degrees C with an ultimate tensile strength up to 1157 MPa and total elongation of 51%. Increasing the aging temperature and time, x-carbides start to form intergranularly, lose their coherency with the matrix and severely compromise the hardness and strength. The shearing of the carbides during deformation is also studied.

Automated summary

This study investigates the microstructure evolution of a high-strength low-density steel under different aging conditions. The formation and growth of an ordered face-centered cubic L12 phase called x-carbide are characterized qualitatively and quantitatively. The optimal aging condition is determined to achieve a good combination of strength and ductility. Increasing the aging temperature and time leads to the formation of intergranular x-carbides that compromise the hardness and strength of the steel.