Examination of solidification pathways and the liquidus surface in the Nb-Ti-Al system |
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Authors: | Keith J Leonard Joseph C Mishurda Vijay K Vasudevan |
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Affiliation: | (1) the Department of Materials Science and Engineering, University of Cincinnati, 45221-0012 Cincinnati, OH |
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Abstract: | The solidification pathways, subsequent solid-state transformations, and the liquidus surface in the Nb-Ti-Al system have
been examined as part of a larger investigation of phase equilibria in Nb-Ti-Al intermetallic alloys. Fifteen alloys ranging
in composition from 15 to 40 at. pct Al, with Nb to Ti ratios of 4:1, 2:1, 1.5:1, 1:1, and 1:1.5, were prepared by arc melting
and the as-cast microstructures were characterized by optical microscopy (OM), microhardness, X-ray diffraction (XRD), differential
thermal analysis (DTA), backscattered electron imaging (BSEI), electron probe microanalysis (EPMA), and transmission electron
microscopy (TEM). The results indicate that the range of primary β solidification is much wider than that indicated in previously reported liquidus surfaces, both experimental and calculated.
Differential thermal analysis has identified the existence of a β to σ+γ transformation in three alloys where it was previously thought not to exist; confirmation was provided by high-temperature
vacuum heat treatments in the single-phase β region followed by rapid quenching. The location of the boundary between the β, σ, and δ primary solidification fields has been redefined. A massive β → δ transformation, which was observed in the cast microstructure of a Nb-25Ti-25Al alloy, was repeatable through cooling following
homogenization. A β → δ+σ eutectoid-like transformation in the 25 at. pct Al alloys, was detected by DTA and evaluated through microstructural analysis
of heat-treated samples. Trends in the β phase with variations in composition were established for both lattice parameters and microhardness. As a result of this
wider extent of the primary β solidification field, a greater possibility exists for microstructural control through thermal processing for alloys consisting
of either σ+γ, β+σ, or β+δ phases.
An erratum to this article is available at . |
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