Microstructural Changes during Interfacial Diffusion at the Sm₂Fe₁₇–Zn Interface

抄録

The microstructural changes and interdiffusion coefficients at the Sm₂Fe₁₇–Zn interface were investigated in this study. Sm₂Fe₁₇–Zn diffusion couples were annealed for 10 min at 320, 350, and 400°C, which are below the melting temperature of Zn (419°C), resulting in the interdiffusion of Zn, Fe, and Sm. At the interface annealed at 400°C, three diffusion regions were identified between the Sm₂Fe₁₇ and Zn phases. The thickest region was a Zn-rich region composed of polycrystalline δ- and ζ-Zn–Fe binary alloy phases and a ThMn₁₂-type Sm(Zn,Fe)₁₂ ternary alloy phase. The annealing time dependence of the thickness of the Zn-rich region at 400°C was measured, and the interdiffusion coefficient was evaluated as 7.3 × 10⁻¹³ m²s⁻¹ using the Einstein–Smoluchowski equation. At the surface of the Sm₂Fe₁₇ phase, a region with a fiber-like microstructure was observed that consisted of two phases, α-(Zn,Fe) and Sm(Zn,Fe)₁₂. Interestingly, these two phases exhibited a specific crystal orientational relationship of α-FeZn(10-1)[111]//Sm(Zn,Fe)₁₂(01-1)[011]. Between these two diffusion regions, a third region composed of nanosized polycrystalline grains of Γ-FeZn, α-FeZn, and Sm(Zn,Fe)₁₂ was observed.

The temperature dependence of the microstructural changes at the Sm₂Fe₁₇–Zn interface indicated that the microstructural changes proceed as follows. In the initial stage of diffusion, interdiffusion of Zn, Fe, and Sm lead to the formation of the Zn-rich region. As the interdiffusion progresses, Zn diffuses into the Sm₂Fe₁₇ phase, which decomposes to Sm(Zn,Fe)₁₂ and α-FeZn phases with a fiber-like microstructure. Upon further Zn diffusion into the fiber-like region, Zn reacts with the α-FeZn phase to generate a polycrystalline region composed of Γ-FeZn, α-FeZn, and Sm(Zn,Fe)₁₂ phases. To the best our knowledge, this is the first paper to report on the interdiffusion and detailed microstructural changes at the Sm₂Fe₁₇–Zn interface.