Kooperativer Bibliotheksverbund

UID:

Format: 321, XVI p , ill , 24 cm

ISBN: 9782296063617

Series Statement: Collection Logiques sociales

Language: French

Keywords: Stadtentwicklung ; Nachhaltigkeit ; Aufsatzsammlung

Author information: Hamman, Philippe 1974-

UID:

Format: 1 Videokassette (VHS, 58 Min.) , farb. - Zweikanalton

Note: Zweikanalton dt. u. franz. - Fernsehmitschnitt: arte 13.05.1998 , Enth.: 2 unselbständige Werke

Language: Undetermined

Keywords: Stravinsky, Igor 1882-1971 Žar-ptica ; Ballett ; Theaterprobe ; Béjart, Maurice 1927-2007 ; Stravinsky, Igor 1882-1971 Le sacre du printemps ; Ballett ; Theaterprobe ; Béjart, Maurice 1927-2007

Author information: Béjart, Maurice 1927-2007

UID:

Format: 1 Videokassette

Note: Fernsehmitschnitt: arte 13.05.1998

Language: Undetermined

Author information: Béjart, Maurice 1927-2007

Author information: Boulez, Pierre 1925-2016

UID:

Format: 1 online resource (574 pages)

ISBN: 0-12-819241-0

Note: 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 fields -- 2.4. 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 passivation -- 5.3. 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 Scale -- 7.1. 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 Fracture -- 9.1. 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 -- 11.2. Quantitative or semi-quantitative experimental dosage techniques -- 11.3. Hydrogen location methods within a microstructure -- 11.4. Conclusion -- 11.5. References -- PART 3: Stress Corrosion Cracking -- 12. Effect of Stress/Strain Fields on Electrochemical Activity: Metallurgy/Stress Interaction and Surface Reactivity -- 12.1. Introduction -- 12.2. Structural modification: the different contributions of deformation -- 12.3. Thermokinetic approach -- 12.4. Towards a measure of the weight of each contribution: some examples of the mechanical impact -- 12.5. Conclusion -- 12.6. References. , 13. Stress Corrosion Cracking. Between the Corrosion Defect and the Long Crack: the Phase of the Initiation of the Cracks -- 13.1. Introduction -- 13.2. Incubation phase -- 13.3. Initiation of cracks: transition between corrosion defects and short cracks -- 13.4. Propagation of short cracks -- 13.5. Conclusion -- 13.6. References -- 14. Stress Corrosion Crack Propagation -- 14.1. Introduction -- 14.2. Elementary physical SCC cracking propagation mechanisms -- 14.3. Study of long crack propagation under SCC -- 14.4. Multi-cracking -- 14.5. Conclusion and limitations -- 14.6. References -- 15. Oxidation-assisted Cracking -- 15.1. Introduction -- 15.2. Multiprocess assistance: oxidation's role -- 15.3. From multiple processes to coupled processes -- 15.4. Conclusion -- 15.5. References -- 16. Stress Corrosion Cracking: From In-service Cracking to Laboratory Studies -- 16.1. Introduction -- 16.2. Some aspects of the fight against stress corrosion cracking using laboratory tests -- 16.3. Cases highlighting specific problems -- 16.4. Conclusion -- 16.5. References -- PART 4: Corrosion Fatigue -- 17. Corrosion and Hydrogen Fatigue at Different Scales -- 17.1. Introduction -- 17.2. Fatigue endurance in a situation of corrosion fatigue coupling -- 17.3. Initiation and propagation of short cracks -- 17.4. Role of the environment on crack propagation by fatigue -- 17.5. References -- 18. Local-scale Modeling of Plasticity-Environment Interactions -- 18.1. Introduction -- 18.2. Incubation modeling -- 18.3. Initiation modeling -- 18.4. Propagation: extension process -- 18.5. Conclusion -- 18.6. References -- 19. Specific Cases of Corrosion Fatigue -- 19.1. Introduction -- 19.2. Alloy microstructure -- 19.3. Localized corrosion -- 19.4. Stress corrosion -- 19.5. Corrosion fatigue -- 19.6. Conclusion -- 19.7. References. , PART 5: Additional Information and the Paths to Solving Interrelated Problems -- 20. Local Electrochemical Methods Adapted to Studying Environment- Microstructure-Mechanics Couplings -- 20.1. Introduction -- 20.2. Electrochemical microscopy -- 20.3. Electrochemical microcells -- 20.5. Local potential measurement technique (SRET) -- 20.6. Scanning Vibrating Electrode Technique -- 20.7. Conclusion -- 20.8. References -- 21. Mechanical Tests in Corrosive Environments and Under Gaseous Hydrogen -- 21.1. Introduction -- 21.2. Instrumented mechanical tests for transient current analysis -- 21.3. Instrumentation of mechanical tests by digital image correlation -- 21.4. Mechanical tests in a gaseous hydrogen atmosphere -- 21.5. Mechanical testing methodology combining crystalline plasticity and EBSD analysis to detect crack initiation -- 21.6. Electrochemical noise analysis for SCC -- 21.7. Electrochemical permeation test under mechanical loading -- 21.8. References -- 22. Liquid Metal Embrittlement -- 22.1. Liquid metal embrittlement -- 22.2. Definition and characteristics of liquid metal embrittlement -- 22.3. Highlighting liquid metal embrittlement -- 22.4. Liquid metal embrittlement mechanisms -- 22.5. References -- List of Authors -- Index -- Back Cover.

Additional Edition: ISBN 1-78548-309-9

Language: English

UID:

Format: 1 online resource (574 pages)

ISBN: 0-12-819241-0

Note: 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 fields -- 2.4. 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 passivation -- 5.3. 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 Scale -- 7.1. 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 Fracture -- 9.1. 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 -- 11.2. Quantitative or semi-quantitative experimental dosage techniques -- 11.3. Hydrogen location methods within a microstructure -- 11.4. Conclusion -- 11.5. References -- PART 3: Stress Corrosion Cracking -- 12. Effect of Stress/Strain Fields on Electrochemical Activity: Metallurgy/Stress Interaction and Surface Reactivity -- 12.1. Introduction -- 12.2. Structural modification: the different contributions of deformation -- 12.3. Thermokinetic approach -- 12.4. Towards a measure of the weight of each contribution: some examples of the mechanical impact -- 12.5. Conclusion -- 12.6. References. , 13. Stress Corrosion Cracking. Between the Corrosion Defect and the Long Crack: the Phase of the Initiation of the Cracks -- 13.1. Introduction -- 13.2. Incubation phase -- 13.3. Initiation of cracks: transition between corrosion defects and short cracks -- 13.4. Propagation of short cracks -- 13.5. Conclusion -- 13.6. References -- 14. Stress Corrosion Crack Propagation -- 14.1. Introduction -- 14.2. Elementary physical SCC cracking propagation mechanisms -- 14.3. Study of long crack propagation under SCC -- 14.4. Multi-cracking -- 14.5. Conclusion and limitations -- 14.6. References -- 15. Oxidation-assisted Cracking -- 15.1. Introduction -- 15.2. Multiprocess assistance: oxidation's role -- 15.3. From multiple processes to coupled processes -- 15.4. Conclusion -- 15.5. References -- 16. Stress Corrosion Cracking: From In-service Cracking to Laboratory Studies -- 16.1. Introduction -- 16.2. Some aspects of the fight against stress corrosion cracking using laboratory tests -- 16.3. Cases highlighting specific problems -- 16.4. Conclusion -- 16.5. References -- PART 4: Corrosion Fatigue -- 17. Corrosion and Hydrogen Fatigue at Different Scales -- 17.1. Introduction -- 17.2. Fatigue endurance in a situation of corrosion fatigue coupling -- 17.3. Initiation and propagation of short cracks -- 17.4. Role of the environment on crack propagation by fatigue -- 17.5. References -- 18. Local-scale Modeling of Plasticity-Environment Interactions -- 18.1. Introduction -- 18.2. Incubation modeling -- 18.3. Initiation modeling -- 18.4. Propagation: extension process -- 18.5. Conclusion -- 18.6. References -- 19. Specific Cases of Corrosion Fatigue -- 19.1. Introduction -- 19.2. Alloy microstructure -- 19.3. Localized corrosion -- 19.4. Stress corrosion -- 19.5. Corrosion fatigue -- 19.6. Conclusion -- 19.7. References. , PART 5: Additional Information and the Paths to Solving Interrelated Problems -- 20. Local Electrochemical Methods Adapted to Studying Environment- Microstructure-Mechanics Couplings -- 20.1. Introduction -- 20.2. Electrochemical microscopy -- 20.3. Electrochemical microcells -- 20.5. Local potential measurement technique (SRET) -- 20.6. Scanning Vibrating Electrode Technique -- 20.7. Conclusion -- 20.8. References -- 21. Mechanical Tests in Corrosive Environments and Under Gaseous Hydrogen -- 21.1. Introduction -- 21.2. Instrumented mechanical tests for transient current analysis -- 21.3. Instrumentation of mechanical tests by digital image correlation -- 21.4. Mechanical tests in a gaseous hydrogen atmosphere -- 21.5. Mechanical testing methodology combining crystalline plasticity and EBSD analysis to detect crack initiation -- 21.6. Electrochemical noise analysis for SCC -- 21.7. Electrochemical permeation test under mechanical loading -- 21.8. References -- 22. Liquid Metal Embrittlement -- 22.1. Liquid metal embrittlement -- 22.2. Definition and characteristics of liquid metal embrittlement -- 22.3. Highlighting liquid metal embrittlement -- 22.4. Liquid metal embrittlement mechanisms -- 22.5. References -- List of Authors -- Index -- Back Cover.

Additional Edition: ISBN 1-78548-309-9

Language: English

UID:

Format: 1 online resource (574 pages)

ISBN: 0-12-819241-0

Note: 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 fields -- 2.4. 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 passivation -- 5.3. 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 Scale -- 7.1. 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 Fracture -- 9.1. 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 -- 11.2. Quantitative or semi-quantitative experimental dosage techniques -- 11.3. Hydrogen location methods within a microstructure -- 11.4. Conclusion -- 11.5. References -- PART 3: Stress Corrosion Cracking -- 12. Effect of Stress/Strain Fields on Electrochemical Activity: Metallurgy/Stress Interaction and Surface Reactivity -- 12.1. Introduction -- 12.2. Structural modification: the different contributions of deformation -- 12.3. Thermokinetic approach -- 12.4. Towards a measure of the weight of each contribution: some examples of the mechanical impact -- 12.5. Conclusion -- 12.6. References. , 13. Stress Corrosion Cracking. Between the Corrosion Defect and the Long Crack: the Phase of the Initiation of the Cracks -- 13.1. Introduction -- 13.2. Incubation phase -- 13.3. Initiation of cracks: transition between corrosion defects and short cracks -- 13.4. Propagation of short cracks -- 13.5. Conclusion -- 13.6. References -- 14. Stress Corrosion Crack Propagation -- 14.1. Introduction -- 14.2. Elementary physical SCC cracking propagation mechanisms -- 14.3. Study of long crack propagation under SCC -- 14.4. Multi-cracking -- 14.5. Conclusion and limitations -- 14.6. References -- 15. Oxidation-assisted Cracking -- 15.1. Introduction -- 15.2. Multiprocess assistance: oxidation's role -- 15.3. From multiple processes to coupled processes -- 15.4. Conclusion -- 15.5. References -- 16. Stress Corrosion Cracking: From In-service Cracking to Laboratory Studies -- 16.1. Introduction -- 16.2. Some aspects of the fight against stress corrosion cracking using laboratory tests -- 16.3. Cases highlighting specific problems -- 16.4. Conclusion -- 16.5. References -- PART 4: Corrosion Fatigue -- 17. Corrosion and Hydrogen Fatigue at Different Scales -- 17.1. Introduction -- 17.2. Fatigue endurance in a situation of corrosion fatigue coupling -- 17.3. Initiation and propagation of short cracks -- 17.4. Role of the environment on crack propagation by fatigue -- 17.5. References -- 18. Local-scale Modeling of Plasticity-Environment Interactions -- 18.1. Introduction -- 18.2. Incubation modeling -- 18.3. Initiation modeling -- 18.4. Propagation: extension process -- 18.5. Conclusion -- 18.6. References -- 19. Specific Cases of Corrosion Fatigue -- 19.1. Introduction -- 19.2. Alloy microstructure -- 19.3. Localized corrosion -- 19.4. Stress corrosion -- 19.5. Corrosion fatigue -- 19.6. Conclusion -- 19.7. References. , PART 5: Additional Information and the Paths to Solving Interrelated Problems -- 20. Local Electrochemical Methods Adapted to Studying Environment- Microstructure-Mechanics Couplings -- 20.1. Introduction -- 20.2. Electrochemical microscopy -- 20.3. Electrochemical microcells -- 20.5. Local potential measurement technique (SRET) -- 20.6. Scanning Vibrating Electrode Technique -- 20.7. Conclusion -- 20.8. References -- 21. Mechanical Tests in Corrosive Environments and Under Gaseous Hydrogen -- 21.1. Introduction -- 21.2. Instrumented mechanical tests for transient current analysis -- 21.3. Instrumentation of mechanical tests by digital image correlation -- 21.4. Mechanical tests in a gaseous hydrogen atmosphere -- 21.5. Mechanical testing methodology combining crystalline plasticity and EBSD analysis to detect crack initiation -- 21.6. Electrochemical noise analysis for SCC -- 21.7. Electrochemical permeation test under mechanical loading -- 21.8. References -- 22. Liquid Metal Embrittlement -- 22.1. Liquid metal embrittlement -- 22.2. Definition and characteristics of liquid metal embrittlement -- 22.3. Highlighting liquid metal embrittlement -- 22.4. Liquid metal embrittlement mechanisms -- 22.5. References -- List of Authors -- Index -- Back Cover.

Additional Edition: ISBN 1-78548-309-9

Language: English

UID:

Format: 260 S. : , Ill.

ISBN: 978-90-5201-528-6

Series Statement: EcoPolis 9

Language: French

Subjects: Sociology

Keywords: Stadtentwicklung ; Nachhaltigkeit ; Politisches Handeln

URL: http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=018656004&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA

URL: http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=018656004&sequence=000004&line_number=0002&func_code=DB_RECORDS&service_type=MEDIA

Author information: Hamman, Philippe, 1974-