Cover -- Title Page -- Copyright Page -- Contents -- Preface -- Chapter 1 Localized Corrosion in Complex Engineering Environments -- 1.1 Localized Corrosion Complexity -- 1.1.1 Localized Corrosion and Its Complexity in Engineering Systems -- 1.1.2 Sources of Localized Corrosion Complexity -- 1.2 Corrosion from Simple to Complex -- 1.2.1 Corrosion from Uniform to Localized in Engineering Systems -- 1.2.2 General Corrosion in Micro-Electrochemical Cells -- 1.2.3 Localized Corrosion in Macro-Electrochemical Cells -- 1.3 Cases of Localized Corrosion in Industry -- 1.3.1 Corrosion Due to Unexpected Environmental Changes -- 1.3.2 Pitting Due to Unanticipated Corrosion Mechanism Changes -- 1.3.3 Multifaceted Corrosion of Underground Pipelines -- 1.4 Obstacles in Modeling and Managing Complex Localized Corrosion -- 1.4.1 Challenges in Managing Localized Corrosion -- 1.4.2 Issues in Modeling and Predicting Complex Localized Corrosion -- References -- Chapter 2 Techniques for Localized Corrosion Inspection and Monitoring -- 2.1 Techniques for Corrosion Detection, Inspection, and Data Acquisition -- 2.1.1 Issues in Detecting and Predicting Complex Localized Corrosion -- 2.1.2 Conventional Techniques and Tools for Acquiring Corrosion Data -- 2.1.3 Pipeline Industry Concerns About Integrity Assessment -- 2.1.4 Progress in Techniques for Unpiggable Pipelines Corrosion Assessment -- 2.2 Corrosion Monitoring Using Sensors and Probes -- 2.2.1 Overview of Corrosion Sensors and Probes -- 2.2.2 Electrochemical Probes for Monitoring Localized Corrosion -- 2.3 Multi-Electrode Arrays for Probing Complex Corrosion -- 2.3.1 Localized Corrosion Probes Design Based on Electrode Arrays -- 2.3.2 Various Electrode Array Probe Designs for Examining Crevice Corrosion -- 2.3.3 Further Issues and Challenges in Corrosion Monitoring Probes -- References.

Chapter 3 Localized Corrosion in Changing Environments -- 3.1 Probing Localized Corrosion in Nonuniform and Changing Environments -- 3.1.1 Challenges of Localized Corrosion in Diverse and Changing Environments -- 3.1.2 Probing Localized Corrosion in Diverse and Changing Environments -- 3.2 Steel Corrosion Behavior in Soil Under Disrupted Cathodic Protection -- 3.2.1 Localized Corrosion on Steel in Soils Under Varying CP and Moisture Levels -- 3.2.2 Localized Corrosion on Steel with Varying Coating Defect Sizes -- 3.3 Steel Corrosion Behavior in Soil Under Stray Currents -- 3.3.1 Locating Stray Current Corrosion in Soil -- 3.3.2 Dynamic Stray Current Corrosion Under Anodic Potential Transients -- 3.3.3 Stray Current Corrosion Under the Effects of Cyclic Potential Transients -- References -- Chapter 4 Localized Corrosion Influenced by Changing Mechanisms -- 4.1 Localized Corrosion and Materials Degradation with Varying Mechanisms -- 4.1.1 Issues with Changing Corrosion Mechanisms on Buried Pipelines -- 4.1.2 Assessing Coating Disbondment and Corrosion Under Disbonded Coatings -- 4.2 Probing Localized Coating Degradation and Disbondment -- 4.2.1 Probes for Monitoring Cathodic Disbondment -- 4.2.2 Examining Factors Affecting the Rate of Coating Cathodic Disbondment -- 4.3 Probing Localized Corrosion Under Disbonded Coatings -- 4.3.1 Integrated 3D Probes for Probing Corrosion Under Disbonded Coatings -- 4.3.2 Probing CUDC of Varying Disbondment Geometries in Soil -- 4.3.3 Field Monitoring of Localized Corrosion on Buried Pipelines -- References -- Chapter 5 Corrosion Affected by Multiple Environments and Mechanisms -- 5.1 Localized Corrosion Affected by Multiple Environments and Mechanisms -- 5.2 Probing Multi-Mechanism Corrosion Across Multiple Environments -- 5.2.1 Probing Localized Corrosion Across Soil and Air Interface.

5.2.2 Probing Localized Corrosion Across Water/Air and Soil/Water Interfaces -- 5.2.3 Probing Localized Corrosion of Steel in Concrete -- 5.2.4 Probing Localized Corrosion in Atmospheric Conditions -- 5.3 Cases of Probing Localized Corrosion Over Multiple Environments -- 5.3.1 Probing Localized Corrosion in Marine Environments -- 5.3.2 Probing Localized Corrosion on Shore-Crossing Pipeline by Moving Probes -- References -- Chapter 6 Localized Corrosion Impacted by Flow and Erosion -- 6.1 Localized Corrosion Impacted by Flowing Liquid and Solid Particles -- 6.1.1 Issues with Localized Corrosion Affected by Flow and Erosion -- 6.1.2 Acquiring Corrosion Data from Flowing and Erosion Systems -- 6.2 Cases of Probing Corrosion and Inhibition in Flowing Liquids -- 6.2.1 Probing Erosion-Corrosion Behavior of Stainless Steels -- 6.2.2 Monitoring Corrosion Inhibitor Film Damage by Flowing Liquid -- 6.2.3 Probing Localized Damage of Inhibitor Film and Corrosion -- 6.3 Probing Localized Corrosion Mechanisms Impacted by Flow and Erosion -- 6.3.1 Assessing Factors Affecting FAC and Erosion Corrosion -- 6.3.2 Exploring FAC and Erosion-Corrosion Mechanisms -- References -- Chapter 7 Localized Corrosion Induced by Metallurgical Heterogeneities -- 7.1 Multiscale Corrosion Induced by Metallurgical Heterogeneity -- 7.1.1 Localized Corrosion Over Multi- Time and Length Scales -- 7.1.2 Techniques for Probing Localized Corrosion Over Different Scales -- 7.1.3 Three-Dimensional Techniques for Characterizing Multiscale Localized Corrosion -- 7.2 Various Probes Designed for Probing Multiscale Corrosion -- 7.2.1 2D and 3D Electrode Arrays for Probing Multiscale Corrosion -- 7.2.2 Probing Corrosion of Multi-Metal Structures and Weldments -- 7.2.3 Simplified Method for Probing Multi-Scale Weldment Corrosion -- References.

Chapter 8 Challenges and Opportunities in Managing Complex Localized Corrosion -- 8.1 Future Perspectives in Corrosion Monitoring Tools and Predictive Models -- 8.1.1 Opportunities in Developing More Reliable Monitoring Tools and Models -- 8.1.2 Obstacles in Probing Multiscale Corrosion -- 8.1.3 Challenges in Quantifying Mechanical Impact on Material Behavior -- 8.2 Opportunities in Developing Smart Anticorrosion Methods and Materials -- 8.2.1 Design and Select Materials for Severe Industrial Conditions -- 8.2.2 Design and Apply Environmentally Friendly Anticorrosion Materials -- References -- Index -- EULA.