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Mechanics-- Microstructure-- Corrosion coupling : concepts, experiments, modeling and cases /

Mechanics - Microstructure - Corrosion Coupling: Concepts, Experiments, Modeling and Cases presents the state-of-the-art on scientific and technological developments relating to the durability of materials and structures subjected to mechanical and environmental stress in industries such as energy,...

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Detalles Bibliográficos
Clasificación:Libro Electrónico
Otros Autores: Blanc, Christine (Editor ), Aubert, Isabelle (Editor )
Formato: Electrónico eBook
Idioma:Inglés
Publicado: London : ISTE Press, 2019.
Temas:
Acceso en línea:Texto completo
Tabla de Contenidos:
  • Front Cover; "Mechanics
  • Microstructure
  • Corrosion" Coupling: Concepts, Experiments, Modeling and Cases; Copyright Page; Contents; Acknowledgements; Introduction; 1. Environmentally Assisted Cracking: Some Critical Aspects; 1.1. Introduction; 1.2. Practical identification of susceptibility to EAC; 1.3. The cracking processes; 1.4. Conclusion; 1.5. References; PART 1: The Basics for Understanding Mechanics-Environment-Microstructure Couplings; 2. The Basics to Better Understand Couplings in Physical Metallurgy; 2.1. Structures and defects; 2.2. Phase transformations and segregation
  • 2.3. Effect of mechanical fields2.4. References; 3. Continuum Mechanics; 3.1. Introduction; 3.2. Kinematics of 3D continuous media; 3.3. Internal forces in continuous media; 3.4. Thermodynamic approach of the constitutive equations; 3.5. References; 4. Fatigue Crack Initiation and Propagation; 4.1. Introduction; 4.2. Cyclic mechanical behavior, plastic fatigue; 4.3. High-cycle and very high-cycle fatigue; 4.4. Fatigue crack propagation; 4.5. Mixed-mode fatigue crack growth; 4.6. References; 5. Surface Chemistry and Passivation of Metals and Alloys; 5.1. Surface chemistry
  • 5.2. Metal and alloy passivation5.3. References; 6. Electrochemistry for Mechanicallyassisted Corrosion; 6.1. Conceptualization elements of mechanically-assisted corrosion; 6.2. From the phenomenological analysis to the electrochemical analysis; 6.3. Corrosion due to the local fracture of the passive film; 6.4. Physical contribution associated with the electrochemical reduction reaction: effects induced by the proton reduction react; 6.5. Electrochemical phenomena in a confined environment; 6.6. Principles of local electrochemical measurements; 6.7. Conclusion; 6.8. References
  • 7. Modeling Tools: From the Atom to the Macroscopic Scale7.1. Introduction; 7.2. The atomic scale; 7.3. Mesoscopic scale; 7.4. Macroscopic scale: crystal plasticity; 7.5. Conclusion; 7.6. References; PART 2: Hydrogen and the Embrittlement of Metallic Materials; 8. State of Hydrogen in Matter: Fundamental Ad/Absorption, Trapping and Transport Mechanisms; 8.1. Hydrogen sources and important parameters; 8.2. Adsorption; 8.3. Absorption
  • dissolution; 8.4. Diffusion; 8.5. Trapping; 8.6. Hydrogen transport by mobile defects; 8.7. Conclusion; 8.8. References
  • 9. Hydrogen and Crystal Defects Interactions: Effects on Plasticity and Fracture9.1. Introduction; 9.2. The role of hydrogen during interface decohesion; 9.3. The effect of hydrogen on plastic deformation processes; 9.4. Embrittlement through vacancy formation; 9.5. Embrittlement through hydride formation; 9.6. Conclusion and unanswered questions; 9.7. References; 10. Industrial Consequences of Hydrogen Embrittlement; 10.1. Introduction; 10.2. The energy sector; 10.3. Hydrogen in transport; 10.4. References; 11. Experimental Techniques for Dosage and Detection of Hydrogen; 11.1. Introduction