Analysis of morphological stability in ternary two-phase diffusion couples

•Interfacial stability of a ternary two-phase diffusion couple has been investigated.•Stability is related to the diffusion paths on the phase diagram.•Examples of unstable boundaries are derived for a model ternary system. It has been established that, under certain conditions, the flat interphase...

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Bibliographic Details
Published in:Journal of crystal growth 2020-11, Vol.549, p.125850, Article 125850
Main Author: Hoyt, J.J.
Format: Article
Language:English
Subjects:
A1. Diffusion
A1. Morphological stability
A1. Phase diagrams
Alloy solidification
Diffusion
Free energy
Interdiffusion
Phase diagrams
Solidification
Stability analysis
Supercooling
Ternary systems
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Summary:•Interfacial stability of a ternary two-phase diffusion couple has been investigated.•Stability is related to the diffusion paths on the phase diagram.•Examples of unstable boundaries are derived for a model ternary system. It has been established that, under certain conditions, the flat interphase boundary separating two ternary phases can be become morphologically unstable during the interdiffusion process. By a direct analogy with the constitutional supercooling criterion in alloy solidification, it has been proposed that the instability in ternary two-phase diffusion couples occurs when either or both diffusion paths enter into the two-phase region of the phase diagram. In this work a linear stability analysis of the diffusion problem is performed and the conditions for stability are expressed in terms of the diffusion coefficients, the slopes of the concentration profiles at the interface, and the system free energy as a function of composition. Through the use of a model ternary system, various examples of unstable interfaces are illustrated. It is found that the crossing of a diffusion path into the two-phase coexistence region is a necessary, but not sufficient condition for instability.
ISSN:0022-0248
1873-5002
DOI:10.1016/j.jcrysgro.2020.125850