Localized deformation as a key precursor to initiation of intergranular stress corrosion cracking of austenitic stainless steels employed in nuclear power plants

Cold-work has been associated with the occurrence of intergranular cracking of stainless steels employed in light water reactors. This study examined the deformation behavior of AISI 304, AISI 347 and a higher stacking fault energy model alloy subjected to bulk cold-work and (for 347) surface deformation. Deformation microstructures of the materials were examined and correlated with their particular mechanical response under different conditions of temperature, strain rate and degree of prior cold-work. Select slow-strain rate tensile tests in autoclaves enabled the role of local strain heterogeneity in crack initiation in pressurized water reactor environments to be considered. The high stacking fault energy material exhibited uniform strain hardening, even at sub-zero temperatures, while the commercial stainless steels showed significant heterogeneity in their strain response. Surface treatments introduced local cold-work, which had a clear effect on the surface roughness and hardness, and on near-surface residual stress profiles. Autoclave tests led to transgranular surface cracking for a circumferentially ground surface, and intergranular crack initiation for a polished surface.

[1]  R. Chieragatti,et al.  Mechanism of brittle fracture in a ductile 316 alloy during stress corrosion , 1990 .

[2]  P. Pilvin,et al.  Dipole heights in cyclically deformed polycrystalline AISI 316L stainless steel , 2005 .

[3]  T. Byun On the stress dependence of partial dislocation separation and deformation microstructure in austenitic stainless steels , 2003 .

[4]  J. Prohászka,et al.  Magnetic investigation of the effect of α′-martensite on the properties of austenitic stainless steel , 2005 .

[5]  Y. Wang,et al.  Intergranular strains and plastic deformation of an austenitic stainless steel , 2002 .

[6]  J. Hirth,et al.  The role of interface dislocations and ledges as sources/sinks for point defects in scaling reactions , 1995 .

[7]  H. Maier,et al.  Competing mechanisms and modeling of deformation in austenitic stainless steel single crystals with and without nitrogen , 2001 .

[8]  E. Andrieu,et al.  Role of metal-oxide interfacial reactions on the interactions between oxidation and deformation , 1998 .

[9]  J. Robertson The mechanism of high temperature aqueous corrosion of stainless steels , 1991 .

[10]  J. Talonen Effect of strain-induced α'-martensite transformation on mechanical properties of metastable austenitic stainless steels , 2007 .

[11]  S. Degallaix,et al.  Influence of martensitic transformation on the low-cycle fatigue behaviour of 316LN stainless steel at 77 K , 1997 .

[12]  A. Cuitiño,et al.  Effect of temperature and stacking fault energy on the hardening of FCC crystals , 1996 .

[13]  G. Gray,et al.  The influence of shock-pulse shape on the structure/property behavior of copper and 316 L austenitic stainless steel , 2005 .

[14]  D. Bhattacharya,et al.  Comparison of rolling texture in low and medium stacking fault energy austenitic stainless steels , 2005 .

[15]  T. Byun,et al.  Temperature dependence of strain hardening and plastic instability behaviors in austenitic stainless steels , 2004 .

[16]  Z. Jiao,et al.  Localized deformation and IASCC initiation in austenitic stainless steels , 2008 .

[17]  Eal H. Lee,et al.  On the origin of deformation microstructures in austenitic stainless steel: Part II—Mechanisms , 2001 .