Mechanics - Microstructure - Corrosion Coupling

<p>Part 1. The Basics for Understanding Mechanics–Environment–Microstructure Couplings<br>1. Environmentally Assisted Cracking<br>2. The Basics to Better Understand Couplings in Physical Metallurgy<br>3. Continuum Mechanics<br>4. Fatigue Crack Initiation and Propagation<br>5. Surface Chemistry and Passivation of Metals and Alloys<br>6. Electrochemistry for Mechanically assisted Corrosion <br>7. Modeling Tools: From the Atom to the Macroscopic Scale</p> <p>Part 2. Hydrogen and the Embrittlement of Metallic Materials Ad/Absorption, Trapping and Transport Mechanisms<br>8. State of Hydrogen in Matter: Fundamental Ad/Absorption, Trapping and Transport Mechanisms<br>9. Hydrogen and Crystal Defects Interactions: Effects on Plasticity and Fracture<br>10. Industrial Consequences of Hydrogen Embrittlement<br>11. Experimental Techniques for Dosage and Detection of Hydrogen</p> <p>Part 3. Stress Corrosion Cracking<br>12. Effect of Stress/Strain Fields on Electrochemical Activity: Metallurgy/Stress Interaction and Surface Reactivity<br>13. Stress Corrosion Cracking. Between the Corrosion Defect and the Long Crack: The Phase of the Initiation of the Cracks<br>14. Stress Corrosion Crack Propagation<br>15. Oxidation-assisted Cracking<br>16. Stress Corrosion Cracking: From In-service Cracking to Laboratory Studies </p> <p>Part 4. Corrosion Fatigue<br>17. Corrosion and Hydrogen Fatigue at Different Scales<br>18. Local-scale Modeling of Plasticity–Environment Interactions <br>19. Specific Cases of Corrosion Fatigue</p> <p>Part 5. Additional Information and the Paths to Solving Interrelated Problems<br>20. Local Electrochemical Methods Adapted to Studying Environment–Microstructure–Mechanics Couplings<br>21. Mechanical Tests in Corrosive Environments and Under Gaseous Hydrogen<br>22. Liquid Metal Embrittlement</p>