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HomeMaterials Science ForumMaterials Science Forum Vols. 461-464High Temperature Corrosion of TiAl - 2-5At-%X...

High Temperature Corrosion of TiAl - 2-5At-%X (X=Ag,Cr,Nb) Alloys in SO₂ and H₂S-H₂ Atmospheres

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High Temperature Corrosion and Protection of Materials 6

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Periodical:

Materials Science Forum (Volumes 461-464)

Pages:

497-504

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.461-464.497

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Online since:

August 2004

Authors:

Kazimierz Przybylski, Tomasz Brylewski, A. Stawiarski, Toshio Narita

Keywords:

Electron Microscopy, Intermetallic, Kinetic, Morpholoy, Oxidation, Sulphidation, TiAl-Based Alloy, Titanium Aluminide, X-Ray Analysis

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© 2004 Trans Tech Publications Ltd. All Rights Reserved

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[1] T. Narita, T. Izumi, M. Yatagai and T. Yoshioka: Intermetallics Vol. 8.

[4] (2000), p.371.

[2] T. Izumi, T. Yoshioka, S. Hayashi and T. Narita: Intermetallics Vol. 8.

[8] (2000), p.891.

[3] T. Izumi, T. Yoshioka, S. Hayashi and T. Narita: Intermetallics Vol. 8.

[8] (2000), p.891.

[4] T. Izumi, T. Yashioka, S. Hayashi and T. Narita: Intermetallics Vol. 10.

[4] (2002), p.353.

[5] W. Kai, M. T. Chang and C. Y. Bai: Oxid. Met. Vol. 55 [3-4] (2001), p.191.

[6] V. Shemet, A.K. Tyagi, J.S. Becker, P. Lersch, L. Singheiser and W.J. Quaddakers: Oxid. Met. Vol. 54 [3-4] (2000), p.21.

[7] A. Zeller, F. Dettenwanger and M. Schütze: Intermetallics Vol. 10 (2002), p.59.

[8] Z. Liu, T. Narita: Intermetallics Vol. 11 (2003), p.795.

[9] K. Przybylski, J. Prazuch, W. Maziarz and J. Dutkiewicz: Ann. Chim. Sci. Mat. Vol. 28 (Suppl. 1), p. S223.

[10] A. Gil, Z. Zurek, L. Niewolak, J. Zurek, A. Stawiarki and W.J. Quaddakers: Proc, 7th National Conf. on Prevention from Corrosion, Kraków, 17-21 June, 2002, p.571 (in Polish).

[11] Z. Zurek: J. Therm. Anal. Vol. 39 (1993) p.15.