Anodic characteristics and stress corrosion cracking behavior of nickel rich alloys in bicarbonate and buffer solutions

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The aim of this work is to investigate which alloying element in C-22 is responsible for the cracking susceptibility of the alloy in bicarbonate and two buffer solutions (tungstate and borate). Six nickel based alloys, with different amount of chromium (Cr) and molybdenum (Mo) were tested using elec...

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Autor principal: Zadorozne, N.S
Otros Autores: Giordano, M.C, Ares, Alicia Esther, Carranza, R.M, Rebak, R.B
Formato: Capítulo de libro
Lenguaje:Inglés
Publicado: Elsevier Ltd 2016
Materias:
CORROSION
Acceso en línea:Registro en Scopus
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100 1 |a Zadorozne, N.S. 
245 1 0 |a Anodic characteristics and stress corrosion cracking behavior of nickel rich alloys in bicarbonate and buffer solutions 
260 |b Elsevier Ltd  |c 2016 
270 1 0 |m Zadorozne, N.S.; Instituto de Materiales de Misiones-IMAM, Consejo Nacional de Investigaciones Cientificas y Tecnicas-CONICET, Universidad Nacional de Misiones-UNaM, Félix de Azara 1552, Argentina; email: nataliazadorozne@gmail.com 
504 |a Rebak, R.B., Crystallinne alloys: nickel (2013) Environmental Degradation of Advanced and Traditional Engineering Materials, pp. 197-218. , Taylor & Francis Books, Inc., New York, L.H. Hihara, R.P.I. Adler, R.M. Latanision (Eds.) 
504 |a Weber, J.H., Nickel and nickel alloys: an overview (2001) Encyclopedia of Materials: Science and Technology, pp. 6145-6146. , Elsevier 
504 |a Rebak, R.B., Crook, P., Nickel alloys for corrosive environments (2000) Adv. Mater. Process., 157, pp. 37-42 
504 |a Rebak, R.B., (2000) Corrosion and Environmental Degadation in Materials Science and Technology: A Comprehensive Treatment: Corrosion and Environmental Degradation, 1-2. , Wiley-VCH Verlag GmbH, Weinheim, Germany 
504 |a Rebak, R.B., Factors affecting the crevice corrosion susceptibility of alloy 22 (2005) NACE Corros., 2005, pp. 1-17. , (Pap. 05610) 
504 |a Carranza, R.M., The crevice corrosion of Alloy 22 in the Yucca Mountain nuclear waste repository (2008) JOM J. Miner. Met. Mater., pp. 58-65 
504 |a Paul, C., Rebak, R.B., Influence of the environment on the general corrosion rate of alloy 22 (N06022) (2004) Transport Store Diposal Radioact. Mater., 483, pp. 131-136 
504 |a Gordon, G.M., Speller Award Lecture: corrosion considerations related to permanent disposal of high-level radioactive waste (2002) Corrosion, 58, pp. 811-825 
504 |a Yucca Mountain Science and Engineering Report (2001), DOE/RW-0539, Las Vegas, NV, USA; Rebak, R.B., Corrosion testing of nickel and titanium alloys for nuclear waste disposition (2009) Corrosion, 65, pp. 252-271 
504 |a Chiang, K.T., Dunn, D.S., Cragnolino, G.A., Effect of simulated groundwater chemistry on stress corrosion cracking of alloy 22 (2007) Corrosion, 63, pp. 940-950 
504 |a Rebak, R.B., (2011) Stress Corrosion Cracking of Nickel Alloys in Stress Corrosion Cracking: Theory and Practice, pp. 273-306. , Woodhead Publishing, Sawston, Cambridge, UK 
504 |a Estill, J.C., King, K.J., Fix, D.V., Spurlock, D.G., Hust, G.A., Gordon, S.R., Susceptibility of alloy 22 to environmentally assisted cracking in yucca mountain relevant environments (2002) NACE Corros., 2002, pp. 1-13. , (Pap. 02535) 
504 |a Dunn, D.S., Pan, Y.-M., Cragnolino, G.A., Stress corrosion cracking of nickel-chromium-molybdenum alloys in chloride solutions (2002) NACE Corros, 2002, pp. 1-20. , (Pap. 02425) 
504 |a Andresen, P.L., Emigh, P.W., Young, L.M., Gordon, G.M., Stress corrosion cracking growth rate behavior of alloy 22 (UNS N06022) in concentrated groundwater (2003) NACE Corros., pp. 1-31. , (Pap. 03683) 
504 |a Fix, D.V., Estill, J.C., Hust, G.A., Wong, L.L., Rebak, R.B., Environmentally assisted cracking behavior of nickel alloys in simulated acidic and alkaline ground waters using u-bend specimens (2004) NACE Corros., pp. 1-18. , (Pap. 04549) 
504 |a King, K.J., Wong, L.L., Estill, J.C., Rebak, R.B., Slow strain rate testing of alloy 22 in simulated concentrated ground waters (2004) NACE Corros., 2004, pp. 1-16. , (Pap. 04548) 
504 |a Chiang, K.T., Dunn, D.S., Cragnolino, G.A., Effect of groundwater chemistry on stress corrosion cracking (2005) NACE Corros., 2005. , (Pap. 05463) 
504 |a Chiang, D.S., The combined effect of bicarbonate and chloride ions on the stress corrosion cracking susceptibility of alloy 22 (2006) NACE Corros, 2006, pp. 1-20. , (Pap. 06506) 
504 |a Chiang, K.T., Dunn, D.S., Cragnolino, G.A., Effect of simulated groundwater chemistry on stress corrosion cracking of alloy 22 (2007) Corrosion, 63, pp. 940-950 
504 |a Shukla, D.S., Stress corrosion cracking model for alloy 22 in the potential yucca mountain repository environment (2006) NACE Corros., 2006, pp. 1-25. , (Pap. 06502) 
504 |a Dunn, D.S., Chiang, K.T., Cragnolino, G.A., Surface analysis of alloy 22 under conditions that promote stress corrosion cracking (2006) NACE Corros., pp. 1-11. , (Pap. 06509) 
504 |a Fix, D.V., Estill, J.C., Rebak, R.B., Day, S.D., King, K.J., Hust, G.A., Influence of environmental variables on the susceptibility of alloy 22 to environmentally assisted cracking (2003) Corrosion, 2003. , (Pap 0354) 
504 |a Zadorozne, N.S., Giordano, C.M., Rebak, R.B., Ares, A.E., Carranza, R.M., Anodic stress corrosion cracking suspectibility of nickel and nickel-Chromium alloys containing molybdenum and iron in bicarbonate plus chloride solutions at 90 (2015) Corrosion, pp. 420-432 
504 |a Mishra, A.K., Ramamurthy, S., Biesinger, M., Shoesmith, D.W., The activation/depassivation of nickel-chromium-molybdenum alloys in bicarbonate solution: part I (2013) Electrochim. Acta, 100, pp. 118-124 
504 |a Mishra, A.K., Shoesmith, D.W., The activation/depassivation of nickel-chromium-molybdenum alloys: an oxyanion or a pH effect-Part II (2013) Electrochim. Acta, 102, pp. 328-335 
504 |a Standard reference test method for making potentiostatic and potentiodynamic anodic polarization measurements (2004) Annual Book of ASTM Standards, pp. 53-64. , ASTM International, West Conshohocken, PA, (03.02) 
504 |a Macdonald, A.C., External reference electrodes for use in high temperature aqueous systems (1979) J. Electrochem. Soc., p. 6 
504 |a Standard practice for slow strain rate to evaluate the susceptibility of metallic materials to environmentally assisted cracking (2004) Annual Book of ASTM Standards, pp. 552-558. , ASTM International, West Conshohocken, PA, (03.02) 
504 |a Evans, K.J., Rebak, R.B., Corrosion science, a retrospective and current status in honor of Robert P. Frankenthal (2002) Electrochem. Soc., pp. 344-354 
506 |2 openaire  |e Política editorial 
520 3 |a The aim of this work is to investigate which alloying element in C-22 is responsible for the cracking susceptibility of the alloy in bicarbonate and two buffer solutions (tungstate and borate). Six nickel based alloys, with different amount of chromium (Cr) and molybdenum (Mo) were tested using electrochemical methods and slow strain rate tests (SSRT) at 90 °C. All Cr containing alloys had transgranular cracking at high anodic potential; however, C-22 containing high Cr and high Mo was the most susceptible alloy to cracking. Bicarbonate was the most aggressive of three tested environments of similar pH. © 2016 Elsevier Ltd.  |l eng 
593 |a Instituto de Materiales de Misiones-IMAM, Consejo Nacional de Investigaciones Cientificas y Tecnicas-CONICET, Universidad Nacional de Misiones-UNaM, Félix de Azara 1552, Posadas, Misiones, Argentina 
593 |a Instituto Sabato-UNSAM/CNEA, Av. General Paz 1499, San Martín, Buenos Aires, Argentina 
593 |a Facultad de Ciencias Exactas, Químicas y Naturales-FCEQyN/Universidad Nacional de Misiones-UNaM, Félix de Azara 1552, Posadas, Misiones, Argentina 
593 |a Gerencia Materiales, CNEA, Av. General Paz 1499, San Martín, Buenos Aires, Argentina 
593 |a GE Global Research, CEB2551, 1 Research Circle, Schenectady, NY, United States 
650 1 7 |2 spines  |a CORROSION 
690 1 0 |a NICKEL 
690 1 0 |a POLARIZATION 
690 1 0 |a STRESS CORROSION 
690 1 0 |a ALLOYING ELEMENTS 
690 1 0 |a CRACKS 
690 1 0 |a MOLYBDENUM 
690 1 0 |a NICKEL 
690 1 0 |a POLARIZATION 
690 1 0 |a RESIDUAL STRESSES 
690 1 0 |a STRAIN RATE 
690 1 0 |a ANODIC POTENTIALS 
690 1 0 |a BUFFER SOLUTIONS 
690 1 0 |a CRACKING SUSCEPTIBILITY 
690 1 0 |a ELECTROCHEMICAL METHODS 
690 1 0 |a NICKEL BASED ALLOY 
690 1 0 |a SLOW STRAIN RATE TESTS 
690 1 0 |a STRESS CORROSION 
690 1 0 |a TRANSGRANULAR CRACKING 
690 1 0 |a STRESS CORROSION CRACKING 
700 1 |a Giordano, M.C. 
700 1 |a Ares, Alicia Esther 
700 1 |a Carranza, R.M. 
700 1 |a Rebak, R.B. 
773 0 |d Elsevier Ltd, 2016  |g v. 108  |h pp. 1-10  |x 0010938X  |w (AR-BaUEN)CENRE-4330  |t Corros. Sci. 
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856 4 0 |u https://hdl.handle.net/20.500.12110/paper_0010938X_v108_n_p1_Zadorozne  |y Handle 
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999 |c 76857 

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