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Oxide Film Characterization after the crack propagation in CT specimens of AISI 304L under Hydrogen Water Chemistry Condition.
Published online by Cambridge University Press: 07 March 2016
Abstract
Stress Corrosion Cracking (SCC) in a general term describing stressed alloy fracture that occurs by crack propagation in specifically environments, and has the appearance of brittle fracture, yet it can occur in ductile materials like AISI 304L used in internal components of Boiling Water Reactors (BWR). The high levels of oxygen and hydrogen peroxide generated during an operational Normal Water Condition (NWC) promotes an Electrochemical Corrosion Potential (ECP), enough to generate SCC in susceptible materials. Changes in water chemistry have been some of the main solutions for mitigate this degradation mechanism, and one of these changes is reducing the ECP by the injection of Hydrogen in the feed water of the reactor; this addition moves the ECP below a threshold value, under which the SCC is mitigated (-230mV vs SHE). This paper shows the characterization by Scanning Electron Microscopy (SEM), X-Ray Diffraction (XRD) and Raman Spectroscopy of the oxide film formed in to a crack propagated during a Rising Displacement Test method (RDT), on Hydrogen Water Chemistry (HWC) conditions: 20 ppb O2, 125 ppb H2, P=8MPa, T=288°C, using a CT specimen of austenitic stainless steel AISI 304L sensitized. The characterization allowed identifying the magnetite formation since an incipient way, until very good formed magnetite crystals.
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- MRS Online Proceedings Library (OPL) , Volume 1814: Symposium 6H – Materials in Nuclear Science and Technology—2015 , 2016 , imrc2015sim28-abs026
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- Copyright © Materials Research Society 2016
References
REFERENCES
Lundgren, Klas and Wikmark, Gunnar, 12th Scandinavian Corrosion Progress, Eurocor 92, BWR water chemistry available option and monitoring technique; 187–195.Google Scholar
Angeliu, T. M., Andresen, P. L., Ford, F. P., Applying slip-oxidation to the SCC of austenitics materials in BWR/PWR environments, Corrosion 98, NACE, 1998, 262/1–24.Google Scholar
Kim, J. Y. 1999. Corrosion Engineering Section, Analysis of Oxide Film Formed on Type 304, Stainles Steel in 288, Corrosion- Vol. 55, No. 1.Google Scholar
Kim, J. Y. and Andresen, P. L. 2003. Transformation kinetics of oxide formed on noble metal-treated type 304 stainless steel in 288 °C water; Corrosion- Vol. 59, No.6.Google Scholar
Sund, G, Molander, A. Stress corrosion cracking of prefilmed sensitized type 304 stainless steel in pure water at 250°C”; Proceedings of the 12th Scandinavian Corrosion Congress Eurocorr´92: Finland 1992.Google Scholar
Beavers, J.A. and Koch, G.H. 1992, Limitation of the slow strain rate test for stress corrosion cracking testing, Corrosion, March.Google Scholar
Kikuchi, E., Itow, M., Sakamoto, H., Yacamoto, M., Sudo, A., Suzuki, S. and Kitamura, M. 1997. Intergranular stress corrosion crack growth of sensitized type 304 stainless steel in a simulated boiling water reactor environment; Corrosion- Vol. 53, No.4.CrossRefGoogle Scholar
Raman Data base of Laboratory of photoinduced Effects vibrational and X-Ray Spectroscopy (2015). http://www.fis.unipr.it/phevix/ramandb.html.Google Scholar