Microstructure and Mechanical Behaviour of NbTiAl Based Alloys Doped with Low Additions of Silicon

Zhao Zhao; Anne Denquin; Stefan Drawin; Jonathan Barreau

doi:10.4028/www.scientific.net/MSF.783-786.1207

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HomeMaterials Science ForumMaterials Science Forum Vols. 783-786Microstructure and Mechanical Behaviour of NbTiAl...

Microstructure and Mechanical Behaviour of NbTiAl Based Alloys Doped with Low Additions of Silicon

Abstract:

Nb-base refractory intermetallic materials have potential interest for high temperature applications thanks to their low density and high temperature strength. While advanced intermetallics in monolithic form have limited prospects for providing the required balance of properties for use at high temperatures, two-phase or multicomponent intermetallic systems composed of a ductile, Nb-base refractory phase in equilibrium with one or more silicide intermetallics show promise for further development as structural materials. In the present paper, Nb-base refractory alloys based on Nb-35Ti-15Al (at.%) were doped with small amount of Si (1 and 2 at% of silicon) addition to improve its high temperature strength by keeping an acceptable ductility at room temperature. The samples were prepared by arc-melting starting from pure elements (99.99%). The silicon addition effects on the microstructural features were investigated by using X Ray Diffraction (XRD), Scanning Electron Microscopy (SEM) techniques. Its effects on the mechanical properties were assessed by compression tests at ambient and high temperatures. Compression tests show the beneficial effect of the Si addition on strength.

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Materials Science Forum (Volumes 783-786)

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1207-1212

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https://doi.org/10.4028/www.scientific.net/MSF.783-786.1207

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Online since:

May 2014

Authors:

Zhao Zhao*, Anne Denquin, Stefan Drawin, Jonathan Barreau

Keywords:

Mechanical Property, Nb-Base Alloy, Niobium Aluminides, Phase Transformation, Silicide

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References

[1] E.S.K. Menon, P.R. Subramanian and D.M. Dimiduk, Scripta Met. et Mat., 27, p.265 (1992).

Google Scholar

[2] D. -H. Hou, S. S Yang, J. Sheyue and H.L. Fraser, Mat. Res. Soc. Symp. Proc., 322, MRS, Pittsburgh PA, p.437 (1994).

Google Scholar

[3] .S.K. Menon, P.R. Subramanian and D.M. Dimiduk, Met. And Mat. Trans. A, 27, p.1647 (1996).

Google Scholar

[4] K.J. Leonard and V.K. Vasudevan, Intermet., 8, p.1257 (2000).

Google Scholar

[5] K.J. Leonard, J.C. Mishurda and V.K. Vasudevan, Met. and Mat. Trans. B, 31, p.1305 (2000).

Google Scholar

[6] K.J. Leonard, J.C. Mishurda and V.K. Vasudevan, Mat. Sci. and Eng. A, 329, p.282 (2002).

Google Scholar

[7] S. Yang and V.K. Vasudevan, Scripta Met. Et Mat., 31, 7, p.879 (1994).

Google Scholar

[8] S. Dymek, M. Dollar and K.J. Leonard, Mat. Sci. and Eng. A, 239, p.507 (1997).

Google Scholar

[9] F. Ye, C. Mercer and W.O. Soboyejo, Met. Trans. A., 29, p.2361 (1998).

Google Scholar

[10] T.N. Marieb, A.D. Kaiser and S.R. Nutt, Mat. Res. Soc. Symp. Proc., 213, MRS, Pittburgh PA, p.329 (1991).

Google Scholar

[11] J. Shyue, D. Hou, M. Aindow and H. Fraser, Mater. Sci. Eng. A, 170, p.1 (1993).

Google Scholar

[12] S. Hanada, Y. Murayama and Y. Abe, Intermetallics, 2, p.155 (1993).

Google Scholar

[13] U.R. Kattner and W.J. Boettinger, Mat. Sci. and Eng. A, 152, p.9 (1992).

Google Scholar

[14] V.T. Witusiewicz, A. A Bondar, U. hecht, T. Ya. Velikanova, J. of All. and Comp., 472, p.133 (2009).

Google Scholar

[15] J. Shyue, D. H Hou, S.C. Johnson, and H.L. Fraser, Mat. Res. Soc. Symp. Proc., 288, p.573 (1992).

Google Scholar