Corrosion behavior of 9-12% Cr ferritic-martensitic steels in supercritical water

Corrosion Science

Volumn 52, Issue 4, 2010, Pages 1520-1528

  Tan, L ^a   Ren, X ^a   Allen, T R ^a  

^a University of Wisconsin Madison   (United States)

Author keywords

C. Exfoliation; C. Kinetics; C. Oxidation; C. Porosity

Indexed keywords

C. EXFOLIATION; C. KINETICS; C. OXIDATION; CHARACTERIZATION TECHNIQUES; CORROSION BEHAVIOR; EXPOSURE TEMPERATURE; FERRITIC-MARTENSITIC STEELS; HIGH TEMPERATURE; HIGH-TEMPERATURE WATER; MAGNETITE LAYERS; OXIDE SCALE; PARABOLIC OXIDATION KINETICS; SPINEL LAYERS; STRUCTURAL MATERIALS; SUPERCRITICAL WATER;

BUILDING MATERIALS; CHROMIUM; CORROSION; FERRITE; FERRITIC STEEL; IRON ORES; MARTENSITE; OXIDATION; OXIDE MINERALS; SCALE (DEPOSITS); STEEL METALLOGRAPHY;

MARTENSITIC STEEL;

EID: 77249158792     PISSN: 0010938X     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.corsci.2009.12.032     Document Type: Article

References (33)

1. A Technology Roadmap for Generation IV Nuclear Energy Systems, U.S. DOE Nuclear Energy Research Advisory Committee and the Generation IV International Forum (GIF-002-00), December 2002.
2. Saunders S.R.J., Monteiro M., and Rizzo F. The oxidation behaviour of metals and alloys at high temperatures in atmospheres containing water vapour: a review. Progress in Materials Science 53 (2008) 775-837
3. Quadakkers W.J., Żurek J., and Hänsel M. Effect of water vapor on high-temperature oxidation of FeCr alloys. JOM Journal of the Minerals Metals and Materials Society 61 (2009) 44-50
4. Betova I., Bojinov M., Kinnunen P., Lehtovuori V., Peltonen S., Penttilä S., and Saario T. Composition, structure, and properties of corrosion layers on ferritic and austenitic steels in ultrasupercritical water. Journal of the Electrochemical Society 153 (2006) B464-B473
5. M.G. Angell, S.K. Lister, A. Rudge, The effect of steam pressure on the oxidation behavior of annealed 9Cr-1Mo boiler tubing materials, 15th International Conference on the Properties of Water and Steam (ICPWS XV), Berlin, Germany, September 8-11, 2008.
6. Farrar J.C.M. The Alloy Tree-A Guide to Low-Alloy Steels, Stainless Steels and Nickel-Base Alloys (2004), CRC Press, Boca Raton, FL, USA
7. I.G. Wright, B.A. Pint, An assessment of the high-temperature oxidation behavior of Fe-Cr steels in water vapor and steam, NACE Corrosion/2002, Denver, CO, April 8-11, 2002. Paper No. 02377.
8. Sun C., Hui R., Qu W., and Yick S. Progress in corrosion resistant materials for supercritical water reactors. Corrosion Science 51 (2009) 2508-2523
9. Yin K., Qiu S., Tang R., Zhang Q., and Zhang L. Corrosion behavior of ferritic/martensitic steel P92 in supercritical water. The Journal of Supercritical Fluids 50 (2009) 235-239
10. Jang J.S., Lee Y.B., Han C.H., Yi Y.S., and Hwang S.S. Effect of Cr content on supercritical water corrosion of high Cr alloys. Materials Science Forum 475-479 (2005) 1483-1486
11. Chen Y., Sridharan K., and Allen T. Corrosion behavior of ferritic-martensitic steel T91 in supercritical water. Corrosion Science 48 (2006) 2843-2854
12. Tan L., Yang Y., and Allen T.R. Oxidation behavior of iron-based alloy HCM12A exposed in supercritical water. Corrosion Science 48 (2006) 3123-3138
13. Tan L., Ren X., Sridharan K., and Allen T.R. Corrosion behavior of Ni-base alloys for advanced high temperature water-cooled nuclear plants. Corrosion Science 50 (2008) 3056-3062
14. X. Ren, K. Sridharan, T.R. Allen, Effect of grain refinement on corrosion of ferritic-martensitic steels in supercritical water environment, Materials and Corrosion, in press. doi:10.1002/maco.200905446.
15. Ampornrat P., and Was G.S. Oxidation of ferritic-martensitic alloys T91, HCM12A and HT-9 in supercritical water. Journal of Nuclear Materials 371 (2007) 1-17
16. 2 Statistic (1998), Casulty Actuarial Society Forum, Maryland, USA p. 55
17. Yi Y., Lee B., Kim S., and Jang J. Corrosion and corrosion fatigue behaviors of 9Cr steel in a supercritical water condition. Materials Science and Engineering A 429 (2006) 161-168
18. Castaldi M.J., LaPierre R., Lyubovski M., Pfefferle W., and Roychoudhury S. Effect of water on performance and sizing of fuel-processing reactors. Catalysis Today 99 (2005) 339-346
19. In: Davis J.R. (Ed). Heat-Resistant Materials (ASM Specialty Handbook) (1997), ASM International p. 147
20. F. Masuyama, New developments in steels for power generation boilers, in: R. Viswanathan, J. Nutting (Eds.), Advanced Heat Resistant Steels for Power Generation - Conference Proceedings, San Sebastian, Spain, April 27-29, 1998.
21. Pandat and PanFe are an advanced computational tool for thermodynamic calculation of multi-component systems and Fe-base alloy database developed by CompuTherm LLC. Available from: .
22. Dalvi A.D., and Coates D.E. A review of the diffusion path concept and its application to the high-temperature oxidation of binary alloys. Oxidation of Metals 5 (1972) 113-135
23. Atkinson A. Transport processes during the growth of oxide films at elevated temperature. Reviews of Modern Physics 57 (1985) 437-470
24. Tan L., Machut M.T., Sridharan K., and Allen T.R. Corrosion behavior of a ferritic/martensitic steel HCM12A exposed to harsh environments. Journal of Nuclear Materials 371 (2007) 161-170
25. Ku B.S., and Yu J. Effects of Cu addition on the creep rupture properties of a 12% Cr steel. Scripta Materialia 45 (2001) 205-211
26. Schneider A., and Inden G. Simulation of the kinetics of precipitation reactions in ferritic steels. Acta Materialia 53 (2005) 519-531
27. Varli K.V., Rivlin A.M., Gorchakova E.N., and Umanskii Ya.S. Kinetics of precipitation of Laves' Phase of the Fe2W type in ferritic steel with 8% W. Metal Science and Heat Treatment 13 (1971) 130-131
28. M.S. McIntosh, Mechanisms and factors affecting chromium oxide particle reduction in iron-chromium honeycombs, Ph.D. thesis, Georgia Institute of Technology, April 2005.
29. H.A. Wriedt, Fe-O phase diagram, in: P. Villars (editor-in-chief), H. Okamoto and K. Cenzual (section editors), ASM Alloy Phase Diagrams Center (http://www.asminternational.org/AsmEnterprise/APD), ASM International, Materials Park, OH, 2006.
30. Gaskell D.R. Introduction to the Thermodynamics of Materials. fourth ed. (2003), Taylor & Francis Books, Inc.
31. Hättestrand M., and Andrén H.-O. Microstructural development during ageing of an 11% chromium steel alloyed with copper. Materials Science & Engineering, A: Structural Materials: Properties, Microstructure and Processing 318 (2001) 94-101
32. Komai N., Masuyama F., and Igarashi M. 10-year experience with T23(2.25Cr-1.6W) and T122(12Cr-0.4Mo-2W) in a power boiler. Transactions of the ASME 127 (2005) 190-196
33. Knödler R., Straub S., and Scarlin B. KOMET 650: investigation of materials for use in steam turbines at temperatures up to 650 °C. VGB PowerTech 88 (2008) 59-62