Strain-rate dependence of low cycle fatigue behavior in a simulated BWR environment
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[1] Y. Katada,et al. The effect of temperature on fatigue crack growth behaviour of a low alloy pressure vessel steel in a simulated BWR environment , 1985 .
[2] A. Turnbull,et al. A review of electrochemistry of relevance to environment-assisted cracking in light water reactors , 1992 .
[3] Koichi Saito,et al. Mechanochemical model to predict stress corrosion crack growth of stainless steel in high temperature water , 2001 .
[4] Omesh K. Chopra,et al. Low-cycle fatigue of piping and pressure vessel steels in LWR environments , 1998 .
[5] H. Anzai,et al. Effect of MnS inclusions on stress corrosion cracking in low-alloy steels , 1992 .
[6] In Sup Kim,et al. Strain Rate Effects on the Fatigue Crack Growth of SA508 Cl.3 Reactor Pressure Vessel Steel in High-Temperature Water Environment , 2001 .
[7] Shunji Sato,et al. Low Cycle Fatigue Behavior of Pressure Vessel Steels in High Temperature Pressurized Water , 1991 .
[8] J. Castle,et al. Studies by auger spectroscopy of pit initiation at the site of inclusions in stainless steel , 1990 .
[9] J. D Atkinson,et al. Factors influencing the rate of growth of fatigue cracks in RPV steels exposed to a simulated PWR primary water environment , 1985 .
[10] H. Hänninen,et al. Effects of MnS inclusion dissolution on environmentally assisted cracking in low-alloy and carbon steels , 1990 .
[11] T. Hemmingsen. The electrochemical reaction of sulphur-oxygen compounds. Part II: Voltammetric investigation performed on platinum , 1992 .
[12] P. M. Scott,et al. Corrosion Fatigue of Pressure Vessel Steels in PWR Environments—Influence of Steel Sulfur Content , 1984 .
[13] P. S. Maiya,et al. Prediction of environmental and strain-rate effects on the stress corrosion cracking of austenitic stainless steels , 1987 .
[14] J. Scully. The interaction of strain-rate and repassivation rate in stress corrosion crack propagation , 1980 .
[15] P. M. Scott,et al. Corrosion Fatigue Crack Growth in Reactor Pressure Vessel Steels in PWR Primary Water , 1983 .
[16] Xinqiang Wu,et al. Effects of strain rate and temperature on tensile behavior of hydrogen-charged SA508 Cl.3 pressure vessel steel , 2003 .
[17] E. A. A. Aal. Measurements of pitting corrosion currents of zinc in near neutral media , 2002 .
[18] F. Ford,et al. The prediction of the maximum corrosion fatigue crack propagation rate in the low alloy steel-de-oxygenated water system at 288°C , 1985 .
[19] R. Alkire,et al. Microelectrochemical Measurements of the Dissolution of Single MnS Inclusions, and the Prediction of the Critical Conditions for Pit Initiation on Stainless Steel , 2001 .
[20] R. N. Parkins,et al. The stress corrosion cracking of reactor pressure vessel steel in high temperature water , 1985 .
[21] F. P. Ford. Quantitative Prediction of Environmentally Assisted Cracking , 1996 .
[22] Omesh K. Chopra,et al. Overview of Fatigue Crack Initiation in Carbon and Low-Alloy Steels in Light Water Reactor Environments , 1999 .
[23] J. Yu,et al. THE ROLE OF DYNAMIC STRAIN‐AGEING IN THE ENVIRONMENT ASSISTED CRACKING OBSERVED IN PRESSURE VESSEL STEELS , 1997 .
[24] Makoto Higuchi,et al. Effects of strain rate change on fatigue life of carbon steel in high-temperature water , 1997 .
[25] Hannu Hänninen,et al. On the mechanisms of environment sensitive cyclic crack growth of nuclear reactor pressure vessel steels , 1983 .