材料科学
氧化物
铁氧体(磁铁)
碳钢
冶金
焊接
相(物质)
锰
金属
碳纤维
扩散
微观结构
氧气
氧化锰
液相
热力学平衡
铬
热影响区
过渡金属
基质(化学分析)
复合材料
作者
Ryuichi Homma,Genichi Shigesato,Masaaki Fujioka,Kota Kadoi,Hiroshige Inoue
标识
DOI:10.2355/tetsutohagane.tetsu-2021-087
摘要
The structure of the oxide as a nucleus for intragranular ferrite formation in the low O weld metal and the formation mechanism of Mn depleted zone (MDZ) at the oxide/matrix interface were studied using liquid-tin quenched specimens at high-temperature conditions during laser welding of low carbon Ti added steel. At a high temperature of 1720 K, MDZ is formed around the complex oxides of (Ti,Mn)3O5, (Ti,Mn)2O3, and liquid phase oxides (containing Si, Mn, Ti, and S). The width of the MDZ increases with cooling, and at low temperatures (1275 K) MDZ is formed around the complex oxide consisting mainly of (Ti,Mn)2O3 with MnS and Si-Mn oxides. These MDZs are formed all around the complex oxides, regardless of the kind of oxide. The formation of MDZs is considered to promote the ferrite transformation around the oxides. The equilibrium Mn concentration in each of the oxide phases increases during the cooling process and the thermodynamically stable phase changes from (Ti,Mn)3O5 with a low equilibrium Mn concentration to (Ti,Mn)2O3 with a high equilibrium Mn concentration, which drives the diffusion of Mn from the matrix phase to the oxide. In this process, MDZs are formed all around the complex oxides.
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