316 Prakt. Met. Sonderband 41 (2009)
scale or growth of subscale (internal oxidation). Moreover, an algorithm that transforms the
instantaneous electrical resistance changes to the parameter that describes the kinetics of the
internal oxidation was defined. A comparison of internal oxidation kinetics obtained by the novel
method shows good correlation with kinetics obtained by conventional methods (metallographic
analysis and Wagner’s derivation).
5 References
[1] P. Bronsted, O. Toftsorensen, Journal of Materials Science 1978, 13, 1224-1228.
[2] J. H. Swisher, E. O. Fuchs, Journal of the Institute of Metals 1970, 98, 129-133.
[3] B.C. Proroka, K.C. Gorettaa, J.-H. Parka, U. Balachandrana, M.J. McNallan, Physica C
2002, 370, 30-38.
[41 K. Song, J. Xing, Q. Dong, P. Liu, B. Tian, X. Cao, Materials and Design 2005, 26, 337-
341.
[51 L. Guobin, S. Jibing, G. Quanmei, W. Ru, Journal of Materials Processing Technology
2005, 170, 336-340.
[6] L. Charrin, A. Combe, G. Moya, Acta Metalurgica 1981, 29, 1593-1598.
[7] N. Birks, G.H. Meier, Introduction to High Temperature Oxidation of Metals, Edward
Arnold Ltd, London, 1983.
[8] P.Kofstad, High Temperature Corrosion, Elsevier Applied Science, New York, 1988.
[9] K. Schröder, CRC Handbook of Electrical Resistivities of Binary Metallic Alloys, Boca
Raton, CRC Press, Florida, 1988.
[10] K. Schroder, Electrical, Magnetic and Thermal Properties of Solid Materials, M. Dekker,
New York, 1978.
[11] J. L Meijering., Advances Materials Research 1970, 5, 1 — 82.
[12] J.H. Swisher, E. O. Fuchs, Transactions of the Metallurgical Society of AIME 1969, 245,
1969-1789.
[13] S. Kubo, G. Yamauchi, K. Arita, Japanese Journal of Applied Physics 1977, 16, 447-452.
[14] M. Bruncko, I. Anzel A.C. Kneissl, Corrosion Science 2007, 49, 1228-1244.
[15] C. Wagner., Z. Electrochem 1959, 63, 772-782.
[16] M.Bruncko, The Electrical Resistance Changes of Metallic Materials During High-
Temperature Oxidation, Doctoral Thesis, 2004, p. 75.