Microstructure and texture evolution in a non-oriented electrical steel during γ→α transformation under various atmosphere conditions

Abstract

The microstructure and texture evolution of Fe–0.50%Mn non-oriented electrical steel during austenite (γ) to ferrite (α) transformation was studied following various processing conditions. The experimental results demonstrate that the γ→α transformation interface moves from the surface of sheets towards the inner part along the normal direction (ND) under a high temperature gradient in pure hydrogen atmosphere, hereafter calling the process as “directional” phase transformation. Driven by the anisotropic strain energy, the strong {100} textured columnar grains are obtained during the “directional” phase transformation in pure hydrogen atmosphere with a high flow rate. However, driven by the anisotropies of both strain energy and surface energy, the fine {100} and {110} textured columnar grains are developed in pure hydrogen atmosphere with a relatively low flow rate. By contrast, the transformation process is “global” when specimens are annealed in pure nitrogen atmosphere. As a consequence, a {111} texture with equiaxed grains is obtained. In addition, the effect of manganese (Mn) upon the surface oxidation behavior is investigated. • The various atmosphere conditions lead to the microstructure and texture evolution. • The γ→α transformation is “directional” in hydrogen and “global” in nitrogen. • {100} textured columnar grains are obtained at the high flow rate of hydrogen. • {100} and {110} textured columnar grains are obtained at a low flow rate of hydrogen. • A γ-fiber texture with equiaxed grains is obtained in “global” γ→α transformation.