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Comparison of Modelled and Experimental Data for the NixRu1-xAl Intermetaixic Compound in the Ni-Ru-Al Ternary System

Published online by Cambridge University Press:  06 March 2019

A. S. Harte
Affiliation:
School of Process and Materials Engineering
P. M. Hung
Affiliation:
School of Process and Materials Engineering
I. J. Horner
Affiliation:
School of Process and Materials Engineering
N. Hall
Affiliation:
School of Process and Materials Engineering
L. A. Cornish
Affiliation:
School of Process and Materials Engineering
M. J. Witcomb
Affiliation:
Electron Microscope Unit University of the Witwatersrand Private Bag 3 Johannesburg, 2050 South Africa
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Abstract

A program was developed to predict d-spacings and intensities for peaks of binary phases, using data of the stoichiometric compositions as a basis, and was extended for ternary systems. Predicted data were compared with results from a series of alloys in the Ni-Ru-Al system, spanning the system near 50 atomic % aluminum, to ascertain the extension of the RuAl and NiAl intermetallic compounds into the ternary system. The microstructures mainly appeared cored, and one sample was single phase.

The program enabled easy identification of the peaks, and also allowed comparison of experimental data with predicted ordered and random spectra.

Type
Research Article
Copyright
Copyright © International Centre for Diffraction Data 1995

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References

1. International Centre for Diffraction Data, 1601 Park Lane, Swarthmore, PA 19081, USA (1992).Google Scholar
2. Taylor, A. and Doyle, N. J., Further studies on the nickel-aluminium system: I. The β-AlNi and δ-Ni2Al3 phase fields, J. Appl. Cryst., 5:201(1972).Google Scholar
3. Fleischer, R. L., Substitutional solutes in AlRu: I. Effects of solute oa moduli, lattice parameters and vacancy production, Acta MetalL Mater., 41:863(1993).Google Scholar
4. Tsurikov, V. F., Sokolovskaya, E. M. and Kazakova, E. F., Reaction of nickel and aluminium with ruthenium, Vesnik Moskovkogo Umversiteta, Khimtya, 35:512(1980).Google Scholar
5. Chakravorty, S., Hashim, H. and West, D. R. F., The Ni3Al-Ni3Cr-Ni3Ru section of the Ni-Cr-Al-Ru system, J. Mat. Sd., 20:2313(1985).Google Scholar
6. Chakravorty, S. and West, D. R. F.. Phase equilibria between NiAl and RuAl in the Ni-Al-Ru system, Scripts Met., 19:1355(1985).Google Scholar
7. Chakravorty, S. and West, D. R. F., The constitution of the Ni-Al-Ru system, J. Mat. Sd., 21:2721(1986).Google Scholar
8. Horner, I. J., Witcomb, M. J. and Cornish, L. A., An investigation of the high aluminium region of the Al-Ni-Ru ternary system, Proc. Electron Microsc. Soc. South. Afr. 25:13(1995).Google Scholar