References
- 1. ASTM F899-12b Standard Specification for Wrought Stainless Steels for Surgical Instruments.
- 2. Carmezim M. J. (2005), Capacitance behaviour of passive films on ferritic and austenitic stainless steel, Corrosion Science, No. 47, 581-591.
- 3. Cho H. S. et al. (2004), Corrosion properties of oxide dispersion strengthened steels in super-critical water environment, Journal of Nuclear Materials, No. 329-333, 387-391.
- 4. Hoelzer D. T et al. (2000), A microstructural study of the oxide scale formation on ODS Fe13Cr steel, Journal of Nuclear Materials, No. 283-287, 1306-1310.
- 5. Kim J. S. (2002), Effect of alloying elements on the contact resistance and the passivation behaviour of stainless steels, Corrosion Science, No. 44, 635-655.
- 6. Oksiuta Z. (2011), Microstructural changes of ODS ferritic steel powder during mechanical alloying, Acta Mechanica et Automatica, Vol. 5, No. 2, 74-78.
- 7. Oksiuta Z. et al. (2011), Influence of Y2O3 and Fe2Y additions on the formation of nano-scale oxide particles and the mechanical properties of an ODS RAF steel, Fusion Engineering and Design, No. 86, 2417-2420.
- 8. Ollivier-Leduc A. (2011), Study of selective oxidation by means of glow discharge optical emission spectroscopy, Corrosion Science, 53 (2011) 1375¸1382.
- 9. Tyurin A. G. (2003), Thermodynamic Assessment of the Effect of Chromium and Molybdenum on the Passivability of Nickel-Base Alloys, Protection of Metals, Vol. 39, No. 6, 568-574.
- 10. Ukai S. et al. (1998), R&D of oxide dispersion strengthened ferritic martensitic steels for FBR, Journal of Nuclear Materials, No. 258-263, 1745-1749.