Evolution and deformability of inclusions in Al-killed steel with rare earth-alkali metals (Ca or Mg) combined treatment

The quality of stainless steel is closely related to the deformability of inclusions, which is significantly affected by their compositions. The present study first investigated the evolution of inclusion compositions in Al-killed steel with rare earth-alkali metals (Ca or Mg) combined treatment through four laboratory-scale experiments. The Ce contents in the final steel are 0.0080 wt%, 0.015 wt%, 0.016 wt% and 0.010 wt%, respectively. The Mg content is 0.0014 wt% in Ce-Mg combined treated steel, and the Ca content is 0.0015 wt% in Ce-Ca combined treated steel. The deformability of inclusions in both Ce2O3-Al2O3-CaO and Ce2O3-Al2O3-MgO systems was subsequently evaluated by calculating their Young's modulus at low temperature. The results show that irregular Al2O3 and MgAl2O4 with poor deformability are modified to CeAlO3 and Ce2O3 by Ce treatment, resulting in the decrease of Young's modulus of inclusions. The deformability of inclusions is further improved due to the transformation from lumped-like CeAlO3 to spherical CaO-Al2O3-Ce2O3 caused by Ca treatment, and some of these inclusions are the ones with low liquidus temperature. Thermodynamic analysis was used to discuss the control condition of the formation and evolution of inclusions. Accordingly, the appropriate addition amounts of Al, Mg, Ce, and Ca are expected to control inclusion compositions and properties, including deformability and liquidus temperature, thereby improving the steel performance.0 2022 Chinese Society of Rare Earths. Published by Elsevier B.V. All rights reserved.

Automated summary

This study investigated the influence of combined treatment with rare earth-alkali metals on the composition and deformability of inclusions in stainless steel. The results show that the deformability of inclusions can be improved by modifying their composition through Ce and Ca treatment. Thermodynamic analysis was used to discuss the control conditions for the formation and evolution of inclusions.