High-temperature structural materials

Conventional materials, such as nickel based alloys, will not be able to match the required performance specifications for the future generation of high temperature materials. This book reviews the characteristics and potential of a wide range of candidate superalloy replacements, such as ceramics, intermetallics, and their composites. Particular attention is devoted to the problems of processing and design with these materials.

Nickel-base superalloys: current status and potential - M McLean. Materials requirements for high-temperature structures in the 21st century - J C Williams. Materials selection to resist creep - M F Ashby and C A Abel. Reliability of structural ceramics - M Knechtel, N Claussen and J Rodel. Ceramic matrix composites - R R Naslain. Multiphase intermetallics - R W Cahn. Ceramics and ceramic composites as high-temperature structural materials: challenges and opportunities - A G Evans. Quantum mechanical predictions in intermetallics modelling - D Nguyen Manh, A M Bratkovsky and D G Pettifor. Phase diagram calculations for high temperature structural materials - N Saunders. Process modelling and microstructure - M Rappaz and Ch-A Gandin. Mechanical testing of high-temperature materials: modelling data-scatter - B F Dyson. Effect of matrix cracking on the overall thermal conductivity of fibre-reinforced composites - T J Lu and J W Hutchinson. High-temperature mechanism-based design - F A Leckie.