Formation mechanism of surface oxide layer of grain-oriented silicon steel

The surface oxide layer of grain-oriented electrical steels was investigated by scanning electron microscopy. The formation mechanism and the influence on the glass film of the surface oxide layer were analyzed by the calculation of thermodynamics and kinetics. The surface oxide layer with 2.3 mu m in thickness is mainly composed of SiO2, a small amount of FeO and Fe2SiO4. During the formation of surface oxide layer, the restriction factor was the diffusion of O in the oxide layer. At the initial stage of the decarburization annealing, FeO would be formed on the surface layer. SiO(2)and silicate particles rapidly nucleated, grew and formed a granular oxide layer in the subsurface. As the oxidation layer thickens, the nucleation of new particles decreases, and the growth of oxide particles would be dominant. A lamellar oxide layer was formed between the surface oxide layer and the steel matrix, and eventually formed a typical three-layer structure. During the high temperature annealing, MgO mainly reacted with SiO(2)and Fe(2)SiO(4)in the surface oxide layer to form Mg(2)SiO(4)and Fe(2)SiO(4)would respond first, thus forming the glass film with average thickness of 4.87 mu m.

Automated summary

The surface oxide layer of grain-oriented electrical steels, mainly composed of SiO2, FeO, and Fe2SiO4 with a thickness of approximately 2.3 μm, was found to be formed with the diffusion of oxygen as a limiting factor. During high temperature annealing, MgO reacts mainly with SiO2 and Fe2SiO4 to form Mg2SiO4, leading to the formation of a glass film with an average thickness of 4.87 μm.