Critical Factors in Localized Corrosion 6, in Honor of Professor ShibataJ. Weidner The papers included in this issue of ECS Transactions were originally presented in the symposium ¿Critical Factors in Localized Corrosion 6, in Honor of Professor Shibata¿, held during the PRiME 2008 joint international meeting of The Electrochemical Society and The Electrochemical Society of Japan, with the technical cosponsorship of the Japan Society of Applied Physics, the Korean Electrochemical Society, the Electrochemistry Division of the Royal Australian Chemical Institute, and the Chinese Society of Electrochemistry. This meeting was held in Honolulu, Hawaii, from October 12 to 17, 2008. |
Contents
A Quantitative Study on the Effects of Environment and Microstructure on Pit Initiation | 1 |
An EQCM Study of the Corrosion of Synthetic Aluminium Alloys | 13 |
Localized Approach of Galvanic Coupling on AluminumMagnesium Systems | 25 |
Galvanic Corrosion and Localized Degradation of AluminumMatrix Composites | 39 |
Anodic Activation of Aluminum by Trace Element Tin | 55 |
The Aqueous Corrosion Behavior of Plutonium Metal and PlutoniumGallium Alloys Exposed to Aqueous Nitrate and Chloride Solutions | 71 |
The Effect of Alloy Composition on the Metastable Pitting Behavior of NiCrMo Alloys in Hot Dilute Chloride Solution | 91 |
Stress Corrosion Cracking of Zirconium in Boiling Nitric Acid Solution at | 101 |
Chloride Ion Effects in the Corrosion Kinetics of Intermetallics in Acidic Solutions | 217 |
Initial Stage of SCC of Type 316L Stainless Steel in High Temperature and High | 227 |
Passivity Breakdown and Repassivation on TiNi During Rapid Straining | 233 |
Localized Corrosion Behavior of Austenitic Stainless Steels under Stress Loading | 239 |
Initiation of SCC on SUS304 Stainless Steel without Corrodent on Surface | 247 |
Critical Potential for Propagation of Stress Corrosion Cracking | 255 |
Microelectrochemistry on CrS and MnS Inclusions and Its Relation with Pitting | 269 |
Electrochemical Noise Analysis of 13 mass Cr Stainless Steel HAZ by Solution Flow | 281 |
The Influence of the Semiconducting Properties of Passive Films on Localized | 117 |
Insitu Raman Spectroscopy for the Passive Oxide Film on Iron in Neutral Borate | 125 |
The Effect of Metal Texture on Depassivationrepassivation Behavior of Iron in Borate | 133 |
Passivity and Pit Stability Behavior of Copper as a Function of Selected Water | 141 |
Corrosion Behaviour of New PVD Coatings on Steel | 165 |
Selfhealing Ability of Conductive Polypyrrole Coating with Artificial Defect | 177 |
Neutral and nDoped Conjugated Polymers for Corrosion Control of Aluminum Alloys | 183 |
Lift Off Strategies for SelfOrganized TiO2 Nanotube Layers | 195 |
Pitting of Passivated Cadmium Monocrystals | 203 |
Depassivation pH of Austenitic Stainless Steels in NaCl Aqueous Solution | 291 |
Critical Pitting Temperature of a 2205 Duplex Stainless Steel and Pitting Potential | 297 |
Characterization of Boundwater in Passive Film of Type 304 Stainless Steel Formed in | 307 |
Effect of Alloying Elements on Electrochemical Behavior of Fe18Cr Alloy | 313 |
Effect of the Passive Film on the Crevice Corrosion of Stainless Steels Experimental | 321 |
Critical Factors for Controlling the Stability of the Passive Film on Stainless Steels | 331 |
| 345 | |
Common terms and phrases
acid active addition alloys aluminum analysis anodic applied behavior cathodic cell charge chloride coating composition concentration condition consistent constant containing copper corrosion couple crack crevice critical current density decrease defect dependent determined Discussion dissolution distribution effect electrochemical electrode electrolyte elements Equation experimental experiments exposed Figure formed frequency higher immersion inclusions increase indicated initiation interface ions iron islands layer localized Materials measured mechanism metal metastable pitting microscope NaCl observed obtained occur oxide oxide film oxygen particles passive film peak performed pitting potential plutonium polarization polarization curves potentiostatic present range reaction reduction reference region repassivation resistance sample scanning shown shown in Figure shows similar Society solution specimen stable stainless steel stress suggested surface SVET Table technique temperature thickness treatment values