Microcrack clustering in stress corrosion cracking of 22Cr and 25Cr duplex stainless steels

“…A number of researchers have found that the occurrence of pitting corrosion was an important contributing factor in crack initiation during the process of SCC . Furthermore, many other researchers have shown that the temperature of maximum SCC susceptibility is between 80–120 °C .…”

“…A number of researchers have found that the occurrence of pitting corrosion was an important contributing factor in crack initiation during the process of SCC. [13,14,30] Furthermore, many other researchers have shown that the temperature of maximum SCC susceptibility is between 80-120°C. [3] Van Gelder et al [31] found that DSS (UNS 31803) when subjected to slow plastic strain was susceptible to SCC in sulphidechloride media at temperatures higher than 80°C.…”

“…Test results from four‐point bend specimens of austenitic stainless steel in chloride environment showed increased susceptibility to pitting corrosion with increased pre‐existing surface roughness or damage while compact tension test results in simulated boiling water reactor conditions showed that ppb level of chloride may result in fast SCC of low alloy steels . SCC of 22 and 25Cr SDSS under evaporative seawater conditions using uniaxial tensile specimen has been shown to depend on the level of applied stress and the test temperature; as the applied stress increased the threshold temperature for corrosion and cracking decreased . A summary of the effects of intrinsic material parameters (e.g., chemical composition, microstructure, and surface condition) and environment (e.g., pH, temperature, concentration of aggressive species, and DO) on the initiation and growth of pits in metals has recently been presented by Soltis .…”

“…[13] SCC of 22 and 25Cr SDSS under evaporative seawater conditions using uniaxial tensile specimen has been shown to depend on the level of applied stress and the test temperature; as the applied stress increased the threshold temperature for corrosion and cracking decreased. [14] A summary of the effects of intrinsic material parameters (e.g., chemical composition, microstructure, and surface condition) and environment (e.g., pH, temperature, concentration of aggressive species, and DO) on the initiation and growth of pits in metals has recently been presented by Soltis. [15] Although Keitelman and Alvarez elucidation of the localized acidification pitting model (initiation and growth) by Galvele stated that it did not consider the interactions between dissolved metal ions and chloride or other anionic species in solution; they concluded that laboratory experiments and field experience with alloys like 22 and 25Cr SDSS confirmed quantitatively the predictions of Galvele's model.…”

Effect of ammonium bisulphite and chloride on the pitting and stress corrosion cracking resistance of super duplex stainless steel pipes under combined internal pressure and axial tension

“…A number of researchers have found that the occurrence of pitting corrosion was an important contributing factor in crack initiation during the process of SCC . Furthermore, many other researchers have shown that the temperature of maximum SCC susceptibility is between 80–120 °C .…”

“…A number of researchers have found that the occurrence of pitting corrosion was an important contributing factor in crack initiation during the process of SCC. [13,14,30] Furthermore, many other researchers have shown that the temperature of maximum SCC susceptibility is between 80-120°C. [3] Van Gelder et al [31] found that DSS (UNS 31803) when subjected to slow plastic strain was susceptible to SCC in sulphidechloride media at temperatures higher than 80°C.…”

“…Test results from four‐point bend specimens of austenitic stainless steel in chloride environment showed increased susceptibility to pitting corrosion with increased pre‐existing surface roughness or damage while compact tension test results in simulated boiling water reactor conditions showed that ppb level of chloride may result in fast SCC of low alloy steels . SCC of 22 and 25Cr SDSS under evaporative seawater conditions using uniaxial tensile specimen has been shown to depend on the level of applied stress and the test temperature; as the applied stress increased the threshold temperature for corrosion and cracking decreased . A summary of the effects of intrinsic material parameters (e.g., chemical composition, microstructure, and surface condition) and environment (e.g., pH, temperature, concentration of aggressive species, and DO) on the initiation and growth of pits in metals has recently been presented by Soltis .…”

“…[13] SCC of 22 and 25Cr SDSS under evaporative seawater conditions using uniaxial tensile specimen has been shown to depend on the level of applied stress and the test temperature; as the applied stress increased the threshold temperature for corrosion and cracking decreased. [14] A summary of the effects of intrinsic material parameters (e.g., chemical composition, microstructure, and surface condition) and environment (e.g., pH, temperature, concentration of aggressive species, and DO) on the initiation and growth of pits in metals has recently been presented by Soltis. [15] Although Keitelman and Alvarez elucidation of the localized acidification pitting model (initiation and growth) by Galvele stated that it did not consider the interactions between dissolved metal ions and chloride or other anionic species in solution; they concluded that laboratory experiments and field experience with alloys like 22 and 25Cr SDSS confirmed quantitatively the predictions of Galvele's model.…”

Effect of ammonium bisulphite and chloride on the pitting and stress corrosion cracking resistance of super duplex stainless steel pipes under combined internal pressure and axial tension

“…A high level of cold work has been reported to decrease the stress corrosion cracking resistance of UNS S32550 duplex stainless steel [ 19 ]. Dealloying in the nanocrystalline layer by surface grinding and subsequent cracking of the dealloyed layer have been observed in 22Cr and 25Cr duplex stainless steels after testing under evaporative seawater conditions [ 20 ].…”

SCC of 2304 Duplex Stainless Steel—Microstructure, Residual Stress and Surface Grinding Effects

Unraveling Magnesium Alloy Corrosion Patterns Through Unsupervised Machine Learning: Exploring Clustering Techniques for Enhanced Insight