| Preface | |
| List of Participants | |
| Thermal Shock Behavior of Ceramic Materials - Modelling and Measurement | p. 3 |
| Thermal Stresses in Materials with Temperature Dependent Properties | p. 15 |
| Thermal Shock Testing and the Problem of Standardisation | p. 27 |
| Summary: I. Overview | p. 33 |
| Factors Influencing the Thermal Shock Behavior of Ceramics | p. 37 |
| The Potential of Si[subscript 3]N[subscript 4] for Thermal Shock Applications | p. 49 |
| Change of Fracture Toughness and Strength Caused by Thermal Shock for Si[subscript 3]N[subscript 4] with Microcrack | p. 59 |
| Interrelation Between Flaw Resistance, R-Curve Behavior, Thermal Shock Strength Degradation, and Stress-Strain Behavior of Ceramics | p. 75 |
| Thermal Shock and Cyclic Loading of Ceramic Parts in Stationary Gas Turbines | p. 87 |
| Summary: II. Materials Development - Thermal Shock Properties and Industrial Applications | p. 99 |
| Fracture Mechanics Treatment of Thermal Shock and the Effect of Bridging Stresses | p. 105 |
| Application of Weight Function Method for Crack Analysis in Thermal Stress Fields | p. 119 |
| Multiple Crack Propagation under Thermal Load | p. 143 |
| Crack Patterns: Generalized Laplacian Structures | p. 155 |
| Summary: III.1. Fracture - Mechanical Modelling of Thermal Shock | p. 167 |
| Theoretical Approach of Optimum Design for a Plate of Functionally Gradient Materials under Thermal Loading | p. 171 |
| Thermal Shock of Cracked Composite Materials with Temperature Dependent Properties | p. 181 |
| Thermally Induced Micromechanical Stresses in Ceramic/Ceramic Composites | p. 193 |
| The Design of the Interface Phase for Obtaining Thermal Shock Resistance in Silicon Nitride | p. 207 |
| Summary: III.2. Tailoring of Materials | p. 223 |
| In -situ Observations of Unstable and Stable Crack Propagation and R-Curve Behavior in Thermally Loaded Disks | p. 229 |
| Thermal Shock Fracture by Laser Irradiation | p. 245 |
| Evaluations of the Thermal Shock Resistances and Fracture Toughnesses of Graphite and C/C-Composites by Arc Discharge Heating | p. 253 |
| Significance of Non-Linear Stress-Strain and R-Curve Behavior on Thermal Shock of Ceramics | p. 269 |
| The Significance of Non-Elastic Deformation in the Thermal Shock Fracture of Heterogeneous Ceramic Materials | p. 279 |
| Influence of Heating Rate on the Thermal Strain Induced Fracture of Mg-PSZ Samples | p. 293 |
| Thermal Shock by Water Quench: Numerical Simulation | p. 307 |
| Thermal Shock Resistance and Fracture of Ceramic Materials | p. 317 |
| Thermal Fatigue Behavior of Actively Cooled Divertor Mock-Ups with Fiber Composites as Plasma Interactive Material | p. 331 |
| Performance of Ceramics and Fiber Composites under Severe Thermal Shocks Applied by Energetic Electron Beams or Accelerated Plasmas | p. 343 |
| Thermal Damage by Erosion and Cracking under Pulsed Irradiation | p. 355 |
| Summary: IV.1. Thermal Shock | p. 365 |
| Thermal Shock and Fatigue of Mullite and Alumina: Refined Analyses | p. 371 |
| Thermal Fatigue of Glass | p. 383 |
| Cyclic Thermal Shock in SiC Whisker Reinforced Alumina and in Other Ceramic Systems | p. 393 |
| Thermal Fatigue and Subcritical Crack Growth in Ceramics | p. 407 |
| Thermal Fatigue of Engineering Ceramics | p. 419 |
| Acoustic Emission Amplitude Analysis in Crack Growth Studies During Thermal Shock of Ceramics | p. 429 |
| Summary: IV.2. Thermal Fatigue | p. 443 |
| Statistical Aspects of the Thermal Shock Damage and the Quench Strengthening of Ceramics | p. 447 |
| Thermal Shock Behavior of Ceramics: Probabilistic Predictions of Failure and Damage | p. 459 |
| Thermal Proof Test of Ceramics | p. 473 |
| Hot-Gas Method and Apparatus for Thermal Shock Testing | p. 483 |
| Summary: IV.3. Probabilistic Characterization of Thermal Shock | p. 495 |
| Improvement of Ductility of Ceramic Rich Region in Functionally Gradient Materials by Metal Fiber Premixing | p. 499 |
| Thermal Shock Fracture Mechanism of Metal/Ceramic Functionally Gradient Materials | p. 509 |
| Multifunctional Ceramics for Thermal Shock Applications | p. 521 |
| Transient Thermal Fracture of Ceramic-to-Metal Interfaces | p. 531 |
| Laser and Plasma-Arc Thermal Shock/Fatigue Fracture Evaluation Procedure for Functionally Gradient Materials | p. 543 |
| Development of a Thermal Shock Evaluation Device for Functionally Gradient Materials for Aerospace Applications | p. 555 |
| Thermal Fatigue Characteristics of Functionally Gradient Materials for Aerospace Applications | p. 567 |
| Summary: V. Functionally Gradient and Fiber Reinforced Materials for Thermal Shock and Fatigue Applications | p. 579 |
| Author Index | p. 581 |
| Subject Index | p. 583 |
| Table of Contents provided by Blackwell. All Rights Reserved. |
