Role of interfacial energy and liquid diffusivities on pattern formation during thin-film three-phase eutectic growth

TL;DR

This study explores how interfacial energies and diffusivities influence pattern formation during three-phase eutectic growth in thin films, revealing diffusivities as a key factor in pattern morphology.

Contribution

The paper introduces a comprehensive phase-field simulation approach to analyze pattern selection and stability in three-phase eutectic growth, highlighting the role of diffusivities and interfacial energies.

Findings

Diffusivities significantly influence pattern morphology.

No strong phase selection observed.

Interfacial energies have a lesser impact.

Abstract

In this paper, we investigate three-phase eutectic growth during thin-film directional solidification of a model symmetric ternary eutectic alloy. In contrast to two-phase eutectics that have only a single possibility, ${\alpha}{\beta}{\alpha}{\beta}$..., as the growth pattern, during three-phase eutectic growth infinite possibilities exist. Here, we explore the possible existence of pattern selection influenced by the change in the solid-solid interfacial energies and the diffusivities. We begin the study by estimating the undercooling vs. spacing variation for the simplest possible configurations of pattern lengths 3 and 4, where phase-field simulations are utilized to quantify the influence of the solid-solid interfacial energy and the contrast in the component diffusivities. Subsequently, extended simulations consisting of multiple periods of ${\alpha}{\beta}{\delta}$... as well as ${\alpha}{\beta}{\delta}{\beta}$... are carried out for assessing the stability of the configurations to long-wavelength perturbations in spacing. Thereafter, growth competition among the simplest patterns is investigated through phase-field simulations of coupled growth of configurations of the type [${\alpha}{\beta}{\delta}]_m[{\alpha}{\beta}{\delta}{\beta}]_n$, (m,n) being the respective number of periods. Finally, pattern selection is studied by initializing with random initial configurations and classifying the emerging patterns based on the phase sequences. The principal finding is that, while there is no strong phase selection, between the solid-solid interfacial energies and the contrast in the component diffusivities, we find the latter to strongly influence pattern morphology.