Pattern Formation Mechanism of Directionally-Solidified MoSi2/Mo5Si3 Eutectic by Phase-Field Simulation
Chuanqi Zhu, Yuichiro Koizumi, Akihiko Chiba, Koretaka Yuge, Kyosuke, Kishida, Haruyuki Inui

TL;DR
This study uses phase-field simulation to understand the formation of lamellar patterns in MoSi2/Mo5Si3 eutectic composites, revealing mechanisms behind pattern regularity, discontinuity, and effects of nucleation and lattice strain.
Contribution
It introduces a phase-field model that reproduces lamellar pattern formation, including discontinuities and inclination, aligning well with experimental observations.
Findings
Simulated lamellar spacing matches experimental data.
Discontinuity caused by solid-liquid interface instability.
Nucleation frequency influences pattern randomness.
Abstract
A phase-field study has been conducted to obtain an understanding of the formation mechanism of the script lamellar pattern of MoSi2/Mo5Si3 eutectic composite, which is a promising candidate for high-temperature structural application. The spacing of the lamellar pattern in the simulation results shows good agreement with that of experimental observations and analytical solutions under three growth rates: 10 mm/h, 50 mm/h, and 100 mm/h. The discontinuity of Mo5Si3 rods, in contrast to the regular eutectic with a continuous pattern, is claimed to be caused by the instability of the solid-liquid interface. In this study, the implementation of Mo5Si3 nucleation over the solid-liquid interface has been proposed and successfully reproduced the characteristic of discontinuity. A highly random and intersected lamellar pattern similar to that observed in the ternary MoSi2/Mo5Si3 eutectic…
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Taxonomy
TopicsSolidification and crystal growth phenomena · Intermetallics and Advanced Alloy Properties · Aluminum Alloy Microstructure Properties
