X-Ray Diffraction to Study the Oxidation Mechanism of Chromium at Elevated Temperatures

Henri Buscail; Y.P. Jacob; M.F. Stroosnijder; Eric Caudron; Régis Cueff; F. Rabaste; Sébastien Perrier

doi:10.4028/www.scientific.net/MSF.461-464.93

Paper Titles

Kinetic Investigations on Salt Melt Induced High-Temperature Corrosion of Pure Metals
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Effects of Titanium on a Ferritic Steel Oxidation at 950°C
p.69

Yttrium Implantation and Additional Element Effects on the Oxidation Behaviour of Reference Steels at 973 K
p.77

Presentation, Calibration and First Experiments Using a New Thermobalance for Experiments in Sulfur Vapor Atmospheres
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X-Ray Diffraction to Study the Oxidation Mechanism of Chromium at Elevated Temperatures
p.93

Study of the Sulfur Segregation for a TBC System
p.101

Is KCl(g) Corrosive at Temperatures Above its Dew Point? Influence of KCl(g) on Initial Stages of the High Temperature Corrosion of 11% Cr Steel at 600°C
p.109

The Effect of Silicon Addition on the High Temperature Oxidation of a Fe-Cr Alloy
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Experimental Study of the Interactions between Oxidation and Structural Defects
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X-Ray Diffraction to Study the Oxidation Mechanism of Chromium at Elevated Temperatures

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Materials Science Forum (Volumes 461-464)

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93-100

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https://doi.org/10.4028/www.scientific.net/MSF.461-464.93

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August 2004

Authors:

Henri Buscail, Y.P. Jacob, M.F. Stroosnijder, Eric Caudron, Régis Cueff, F. Rabaste, Sébastien Perrier

Keywords:

High-Temperature, Nitrogen, Oxidation, Pure Chromium, X-Ray Diffraction (XRD)

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References

[1] D. Caplan and G.I. Sproule: Oxid. Met. Vol. 9 (1975), p.459.

Google Scholar

[2] M. Skeldon, J.M. Calvert and D.G. Lees: Oxid. Met. Vol. 28 (1987), p.109.

Google Scholar

[3] S. Jianian, Z. Longjiang and L. Tiefan: Oxid. Met. Vol. 48 (1997), p.347.

DOI: 10.1007/bf01670507

Google Scholar

[4] Z. Zurek: Solid State Phenom. Vol. 41 (1995), p.185.

Google Scholar

[5] D. Caplan, A. Harvey and M. Cohen: Corros. Sci. Vol. 3 (1963), p.161.

Google Scholar

[6] E.W.A. Young and J.H. Gerretsen: J. Electrochem. Soc. Vol. 134 (1987), p.2257.

Google Scholar

[7] B. Tveten, G. Hultquist and T. Norby: Oxid. Met. Vol. 51 (1999), p.221.

Google Scholar

[8] H.C. Graham and H.H. Davis: J. Am. Ceram. Soc. Vol. 54 (1971), p.89.

Google Scholar

[9] D. Caplan and M. Cohen: J. Electrochem. Soc. Vol. 108 (1961), p.438.

Google Scholar

[10] H. Asteman, J.E. Svensson, L.G. Johansson and M. Norell: Oxid. Met. Vol. 52 (1999), p.95.

Google Scholar

[11] B. Gleeson and M.A. Harper: Oxid. Met. Vol. 49 (1998), p.373.

Google Scholar

[12] C. de Asmundis, F. Gesmundo and C. Bottino: Oxid. Met. Vol. 14 (1980), p.351.

Google Scholar

[13] T. Mills: Oxid. Met. Vol. 15 (1981), p.437.

Google Scholar

[14] P. Fox, D.G. Lees and G.W. Lorimer: Oxid. Met. Vol. 36 (1991), p.491.

Google Scholar

[15] M.J. Graham, J.I. Eldridge, D.F. Mitchell and R.J. Hussey: Mater. Sci. Forum Vol. 43 (1989), p.207.

Google Scholar

[16] W.C. Hagel A.U. Seybolt: J. Electrochem. Soc. Vol. 108 (1961), p.1146.

Google Scholar

[17] T. Akermark: Oxid. Met. Vol. 50 (1998), p.167.

Google Scholar

[18] C. Brunner, H. Hutter, K. Piplits, P. Wilhartitz, M.F. Stroosnijder, and M. Grasserbauer: J. Anal. Chem. Vol. 358 (1997), p.233.

Google Scholar

[19] S.C. Tsaï, A.M. Huntz and J. Philibert: Defect and Diffusion Forum Vol. 143-147 (1997), p.1195.

Google Scholar

[20] P. Kofstad: High Temperature Corrosion, (Elsevier Applied Science, London, U.K., 1988), p.116.

Google Scholar

[21] Y.P. Jacob, V.A.C. Haanappel, E. Caudron, H. Buscail M.F. Stroosnijder: Mater. Sci. Forum Vol. 371-372 (2001), p.801.

Google Scholar

[22] I. Murris, Y.P. Jacob, V.A.C. Haanappel, and M.F. Stroosnijder: Oxid. Met. Vol. 55 (2001), p.307.

Google Scholar

[23] Y.P. Jacob, V.A.C. Haanappel, M.F. Stroosnijder, H. Buscail, P. Fielitz and G. Borchardt: Corros. Sci. Vol. 44, 9, (2002), p. (2027).

DOI: 10.1016/s0010-938x(02)00022-7

Google Scholar

[24] Y. P. Jacob, H. Buscail, E. Caudron, R. Cueff, M.F. Stroosnijder and V.A.C. Haanappel: Mater. Chem. Phys. Vol. 77/2 (2002), p.444.

Google Scholar

[25] Y.P. Jacob, H. Buscail, E. Caudron, R. Cueff and M.F. Stroosnijder: Journal de Physique IV, Vol. 12 (2002), p.207.

Google Scholar

[26] K. P. Lillerud and P. Kofstad: J. Electrochem. Soc. Vol. 127 (1980), p.2397.

Google Scholar

[27] V. I. Arkharov, V. N. Konev, I. S. Trakhtenberg and S. V. Shumilina: Physics of Metals and Metallography Vol. 5 (1957), p.164.

Google Scholar

[28] P. Gimpel and T. Ladwein: (Proceedings of High Nitrogen Steels 88, Lille, Eds. J. Foct and A. Henry, 1988), p.272.

Google Scholar

[29] G. R. Wilms and T. W. Rea: Journal of the Less-Common Metals Vol. 1 (1959), p.152.

Google Scholar