Time Dependent Mechanical Response of Engineering Ceramics
Published on 28. April 1999
Software
Digital media
176 pages
978-3-03859-693-6 (ISBN)
Description
Volume is indexed by Thomson Reuters CPCI-S (WoS).
The application of ceramic materials is currently expanding into a wide range of areas, e.g. gas turbine assembly, engine components, electronic devices, bio-materials etc. But because ceramics pose problems with respect to their brittleness and low reliability, due to their intrinsic nature and/or processing defects, research related to the deformation and fracture of ceramics is still a subject of high priority.
The application of ceramic materials is currently expanding into a wide range of areas, e.g. gas turbine assembly, engine components, electronic devices, bio-materials etc. But because ceramics pose problems with respect to their brittleness and low reliability, due to their intrinsic nature and/or processing defects, research related to the deformation and fracture of ceramics is still a subject of high priority.
More details
Language
English
Place of publication
Switzerland
Publishing group
Trans Tech Publications
Target group
Professional and scholarly
Dimensions
Height: 142 mm
Width: 125 mm
Thickness: 10 mm
Weight
200 gr
ISBN-13
978-3-03859-693-6 (9783038596936)
DOI
10.4028/www.scientific.net/KEM.166
Schweitzer Classification
Other editions
Additional editions
E. Yasuda | F. Wakai | L. M. Manocha
Time Dependent Mechanical Response of Engineering Ceramics
From Pico-Second to Million Years
Book
04/1999
Trans Tech Publications Ltd
€88.00
Article exhausted; check different version
Trans Tech Publications Ltd | E. Yasuda | Fumihiro Wakai
Time Dependent Mechanical Response of Engineering Ceramics
E-Book
04/1999
Trans Tech Publications Ltd
€153.01
Available for download
Content
Computational Modeling of Ceramic Microstructure by MC and MD Aspect in DynamicsFast Fracture in Tempered GlassHigh Temperature Impact Response of Silicon Nitride CeramicsNew Computer Simulation Method for Evaluation of Crack Growth Using Lennard-Jones Type Potential FunctionElasticity and Plasticity in Indentation ProblemsPastic Deformation of Brittle MaterialsFatigue and Lifetime of Biomechanical CeramicsFracture of SIC Fiber-Reinforced Glass CompositesCreep Behaviour at High Temperatures of Fine SiC and Alumina Based FibresPhysics of the Brittle-Ductile Transition in Glasses and Glass-Containing Ceramics: Time and Temperature IncidencesSubcritical Crack Growth and Creep Behaviour of Silicon Carbide for Heat Exchanger ApplicationsCreep Behavior of Ceramics and Geological Materials at Low Stress LevelsCreep Behavior of Fiber Reinforced Ceramic CompositesTensile Creep Degradation in Quasi-Ductile Silicon NitrideA Novel Deformation Mechanism for Superplastic DeformationSuperplastic Deformation of Silicon Nitride CeramicsSpallations of Silicon and Aluminum Induced by Short-Pulsed LaserHigh Speed Observation of Impact Fracture of Carbon MaterialsCrack Healing Behavior of Monolithic Al2O3 and Al2O3-SiCw Composite at High TemperatureThe Influence of Nitrate Salt as Sintering Additives on Mechanical Strength in Silicon NitrideTEM Investigation and Fracture Behavior of SiC/SiC Composites Fabricated by Hot-PressingStrain Rate Dependence on the Shear Strength of Unidirectional Carbon/Carbon CompositesComparative Study of Internal Friction in Y2O3-ZrO2 Ceramics at 100 kHzCyclic Fatigue Crack Growth Behavior of Small Cracks in a-?-Si-Al-O-N Ceramic MaterialMovement of Nanocrystalline Grains in SuperplasticityCreep Deformation Mechanism of Ceramics Based on Microstructural Observation