Mechanical Behaviour of Materials at High Temperature

Part I: High Temperature Metallic Alloys. Overview on Monotonic, Creep and Cyclic Stress Strain Behaviour at High Values of Strain; E. Czoboly. Creep Behaviour of Engineering Alloys; G.A. Webster. Development of Intergranular Damage under High Temperature Loading Conditions; V. Sklenicka. Defect Assessment Procedures in the Creep Range; A. Pineau. Intergranular Creep Cavitation and Fracture; V. Sklenicka. Elevated Temperature Fatigue Crack Growth of Nickel Base Superalloys: A Review and Modelling; C. Moura Branco, et al. Fatigue and Creep-Fatigue Behaviour of Ni-Base Superalloys: Microstructural and Environmental Effects; A. Pineau. Interaction of High Temperature Creep with High Cycle Fatigue; P. Lukàs, et al. Creep and Creep- Fatigue Crack Growth of High Strength Steels; G.A. Webster. The Behaviour of Short Cracks at Elevated Temperatures; D.J. Smith. Local Approach: Numerical Simulation of Creep Crack Initiation and Growth; D. Poquillon. The Effect of Temperature on the Growth of Cracks Subjected to Combined Major and Minor Stress Cycles; R.F. Hall, B.E. Powell. Part II: Engineering Applications of High Temperature Alloys. Aspects of the Assessment of the Mechanical Behaviour of Metallic Materials at High Temperature; D.J. Smith. The Behaviour of Defects in Welds at High Temperature; D.J. Smith. Developments in Creep-Fatigue Crack Initiation and Growth Procedures in High Temperature Codes; R.P. Skelton. Quantitative Microstructural Assessment of P91 Ferritic Steel after Long Term Creep at High Temperature; J. Bursík, N. Merk. Aeroengine Applications of Advanced High Temperature Materials; G.F. Harrison, M.R. Winstone. Stressing and Lifing Techniques for High Temperature Aeroengine Components; G.F.Harrison, P.H. Tranter. Part III: Thermal-Mechanical Fatigue and Thermal Shock. Thermo-Mechanical Deformation of Engineering Alloys and Components &endash; Experiments and Modeling; H. Sehitoglu. Thermal-Mechanical Fatigue and Thermal Fatigue Experiments; L. Rémy. Damage Modelling in Thermal Mechanical Fatigue; L. Rémy. Analysis of Thermal Shock and Thermal-Mechanical Fatigue; J. Ginstzler. Experimental Analysis of Thermal Shock; J. Ginsztler. Part IV: High Temperature Behaviour of Metal Matrix and Ceramic Matrix Composites. Crack Propagation in Metal-Matrix Composites. I: Interaction of Cracks with Metal/Ceramic Interfaces; R.O. Ritchie. Crack Propagation in Metal-Matrix Composites. II. Mechanisms of Fatigue-Crack Growth; R.O. Ritchie. Processing, Structure and High Temperature Creep of MMCs; A. Dlouhý, G. Eggeler. Modelling of High Temperature Deformation in MMCs; A. Dlouhý, G. Eggeler. Temperature and Loading Rate Effects on Toughness of in-situ Niobium Silicide &endash; Niobium Composites; J.J. Lewandowski, J.D. Rigney. Sialons and Silicon Nitrides as High Temperature Engineering Materials; Retrospect and Prospect; M.H. Lewis. Toughened Silicon Carbides for High-Temperature Use; R.O. Ritchie, C.J. Gilbert. Indentation Creep Behaviour of Glasses and Glass-Ceramics; T. Unyi, et al. Mechanical Properties of Mullite at High Temperature; M.I. Osendi. Ceramic Matrix Composites; M.H. Lewis. Si3N4- SiC Composites Prepared by SHS Technique; D. Kata, et al. CMC Processing Routes for High Temperature Applications; R. Kochendörfer. Design Concepts for CMC Structures; R. Kochendörfer. CMC's Static and Fatigue Behaviour at High Temperature;