Diffusion Research in BCC Ti-Al-Ni Ternary Alloys

Interdiffusion in BCC phase of Ti-Al-Ni ternary system was investigated at 1473 K (1200 °C) by employing the diffusion-couple technique. The raw composition profiles resulting from interdiffusion treatment and retrieved from EMPA were first analytically represented by error function expansion (ERFEX...

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Bibliographic Details
Published in:Journal of phase equilibria and diffusion 2017-08, Vol.38 (4), p.502-508
Main Authors: Gao, Bo, Gu, Yuanyu, Wu, Qiaojun, Guo, Yanhua, Cui, Yuwen
Format: Article
Language:English
Subjects:
Aluminum
Body centered cubic lattice
Ceramics
Cobalt
Composites
Crystallography and Scattering Methods
Diffusion rate
Engineering Thermodynamics
Error analysis
Glass
Heat and Mass Transfer
Interdiffusion
Iron
Metallic Materials
Natural Materials
Nickel
Physics
Physics and Astronomy
Species diffusion
Ternary alloys
Ternary systems
Thermal expansion
Thermodynamics
Titanium alloys
Titanium base alloys
Vacancies
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Summary:Interdiffusion in BCC phase of Ti-Al-Ni ternary system was investigated at 1473 K (1200 °C) by employing the diffusion-couple technique. The raw composition profiles resulting from interdiffusion treatment and retrieved from EMPA were first analytically represented by error function expansion (ERFEX), and the ternary interdiffusion and impurity diffusion coefficients were then extracted by the Whittle-Green and generalized Hall methods, respectively. The obtained main interdiffusion coefficients D ~ AlAl Ti and two cross coefficients, i.e. D ~ AlNi Ti and D ~ NiAl Ti , were found to increase with increasing composition of diffusing species, whereas the values of D ~ NiNi Ti show no noticeable compositional dependence. The impurity diffusivities D ~ Al Ti - Ni ∗ and D ~ Ni Ti - Al ∗ increase with decreasing the Ni and Al compositions, respectively. The results imply that Al diffusion in β Ti-Al-Ni alloys would occur via an ordinary vacancy diffusion mechanism, whereas Ni diffusion, at least one order magnitude faster than Al, very likely benefits from interstitial diffusion as Fe and Co anomaly diffuse in BCC Titanium alloys.
ISSN:1547-7037
1863-7345
1934-7243
DOI:10.1007/s11669-017-0544-9