Analysis of effects of reactant particle size on phase transformations in the Ti-Si-Cu system using differential thermal analysis and x-ray diffraction

Effects of Ti and Si particle sizes on phase transformations of Ti–Si–Cu system were explored through differential thermal analysis (DTA), x-ray diffraction (XRD), and field emission scanning electron microscope (FESEM). For Ti [15] Si [15] Cu [45] system, fine Ti easily dissolves into Si–Cu liquid to form Ti–Si–Cu liquid at ∼795 °C, which further participates into the reaction of β-Ti and Si to yield abundant quantity of Ti 5 Si 3 at ∼917 °C. For Ti [150] Si [15] Cu [45] system, nonetheless, the reaction of coarse Ti with Si–Cu liquid involves more difficulty in forming the ternary liquid , which is the causal factor for the delay in the formation of Ti 5 Si 3 to ∼948 °C. For Ti [15] Si [150] Cu [45] system, coarse Si results in the formation of insufficient Si–Cu liquid initially, whereas Ti–Cu liquid forms at ∼960 °C instead, which further reacts with coarse Si to form Ti–Si–Cu liquid, and then Ti 5 Si 3 is precipitated from the liquid.

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