Understanding the Anomalous Discontinuous Precipitation in Cu-Ni-X (X = Co,Fe) Alloys Based on CALPHAD Method and Phase-Field Simulation

Journal of the Japan Institute of Metals and Materials Pub Date : 2021-01-01 DOI:10.2320/jinstmet.j2020037

J. Goto, T. Koyama, Yuhki Tsukada

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引用次数: 1

Abstract

The anomalous discontinuous precipitation which is called “Cellular Decomposition (CD)” has been observed in Cu–Ni–X (X = Co,Fe) ternary systems, i.e., the precipitate morphology in cell region is a nanoscale fine fiber, the direction of the fibers does not take specific crystal orientation, and the morphology is wavy. In this study, we elucidated the reason why such an unusual cellular decomposition occurs by means of the Calphad method and phase–field simulations. In particular, we focused on the spinodal decomposition inside the grain before CD. The results showed that the Ni component preferentially segregates at the interface region between precipitate and matrix phase in the two–phase microstructure by spinodal decomposition, and the Ostwald ripening is suppressed due to the low solute solubility of the matrix phase in the Cu–Ni–X (X = Co,Fe) system. Hence, the spinodal microstructure formed inside the grain before CD is trapped into high–energy level, which induces the discontinuous precipitation with high speed grain boundary migration, that provides “Cellular Decomposition”. [doi:10.2320/jinstmet.J2020037]

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基于CALPHAD法和相场模拟的Cu-Ni-X (X = Co,Fe)合金中异常不连续析出

在Cu-Ni-X (X = Co,Fe)三元体系中观察到异常的不连续析出现象，称为“细胞分解(CD)”，即细胞区析出形态为纳米级细纤维，纤维方向不采取特定的晶体取向，形态呈波浪状。在这项研究中，我们通过calphhad方法和相场模拟来阐明这种不寻常的细胞分解发生的原因。结果表明，在两相微观结构中，Ni组分在析出相与基体相的界面区优先偏析，而基体相在Cu-Ni-X (X = Co,Fe)体系中的溶解度较低，抑制了Ostwald成熟。因此，CD前在晶粒内部形成的旋多态微观结构被捕获到高能能级，导致晶界高速迁移的不连续析出，提供了“细胞分解”。(doi: 10.2320 / jinstmet.J2020037)

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Journal of the Japan Institute of Metals and Materials

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