| Description |
1 online resource |
| Contents |
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 |
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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 |
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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 |
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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 |
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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 |
| Summary |
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, aeronautics, chemistry and oil. Experimental, theoretical and numerical aspects are tackled at different scales, providing readers with the most advanced tools and scientific approaches to apprehend coupling phenomena by understanding associated mechanisms, identifying variables of the first order, and proposing strategies to control and/or extend the lifespan of structures in a multi-process coupling situation. In addition, the book presents the latest advances in research in these areas (hydrogen embrittlement, stress corrosion, fatigue, etc.), especially in the consideration of the multi-scale aspect of the phenomena in the implementation of dedicated experiments |
| Bibliography |
Includes bibliographical references and index |
| Notes |
Online resource; title from PDF title page (EBSCO, viewed February 27, 2019) |
| Subject |
Strength of materials.
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strength of materials.
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TECHNOLOGY & ENGINEERING -- Engineering (General)
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TECHNOLOGY & ENGINEERING -- Reference.
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Strength of materials
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| Form |
Electronic book
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| Author |
Blanc, Christine, editor
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Aubert, Isabelle, editor
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| ISBN |
9780128192412 |
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0128192410 |
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