Composition- and temperature-dependence of β to ω phase transformation in Ti-Nb alloys

Yunting Su; Chuanxin Liang; Dong Wang

doi:10.20517/jmi.2023.12

Journal of Materials Informatics ›› 2023, Vol. 3 ›› Issue (3) :14 DOI: 10.20517/jmi.2023.12

Research Article

Composition- and temperature-dependence of β to ω phase transformation in Ti-Nb alloys

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Abstract

ω phases have shown great effects on the superelasticity and modulus of metastable β-Ti alloys. In this study, the microstructure evolution during cooling and aging for β → ω phase transformation is investigated by integrating a thermodynamic database with phase field simulations. Our CALPHAD calculations based on an available thermodynamic database give the Gibbs energies of metastable β (Nb-lean β₁ + Nb-rich β₂ produced via spinodal decomposition) and ω phases in Ti-Nb. Informed by the results, our phase field simulations show that the formation mechanisms of ω exhibit dependence on the composition and temperature. The ω can form in Ti-26 at.% Nb without the assistance of spinodal decomposition. Further analysis shows that the precursory spinodal decomposition in the β phase occurs in Ti-50 at.% Nb, and could induce geometrically confined ω. The novel transformation pathway could create unique morphology of ω. This study could elucidate new insights into the ω phase transformation in Ti-Nb alloys and metastable β-Ti alloys having spinodal decomposition.

Keywords

Omega phase / Ti-Nb / microstructural evolution / spinodal decomposition / phase field simulation

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Yunting Su, Chuanxin Liang, Dong Wang. Composition- and temperature-dependence of β to ω phase transformation in Ti-Nb alloys. Journal of Materials Informatics, 2023, 3(3): 14 DOI:10.20517/jmi.2023.12

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