Plastic Deformation of Ceramics
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ä Deformation Studies of Quasicrystals99Deformation of Nonstoichiometric CuO Polycrystals109Plastic Deformation of Bulk YBaCuO Ceramics Doped with ZrO[subscript 2]119Impression Plasticity and Creep in Hard Crystals131Deformation of Advanced Materials: Case of Sapphire Modified by Heavy Ion Implantation and of YBCO Superconducting Crystals149Spherical Indentation as a Means for Investigating the Plastic Deformation of Ceramics161The Nanoindentation Response of Silicon and Related Structurally Similar Materials173Investigation of Depth-Area Relationships Associated with Nanoindentations185"Nano" and "Micro" Hardnesses of Single Crystal Yttrium Aluminum Garnet (YAG) on the{111} Plane195Deformation of Thin Ceramic Films Designed for Electronic Applications207Apparent Indentation Plasticity in Ceramic Coated Systems219Hardness Change of Nonstoichiometric MgO.3Al[subscript 2]O[subscript 3] by Neutron Irradiation231The Cumulative Deformation, Work-Hardening and Fracture of Magnesium Oxide at Room Temperature, Under Repeated Point Loading Conditions241The Characteristics of Superplastic-like Flow in Ceramics251Solution-Precipitation Creep Model for Superplastic Ceramics with Intergranular Liquid Film269A Granular Flow Approach to Fine-Grain Superplasticity279Creep Deformation of Nanocrystalline Oxides285Characterization of High-Temperature Superplasticity in Fine-Grained Zirconia Polycrystals293A Quantitative Analysis of Cavity Formation in Superplastic Yttria-Stabilized Tetragonal Zirconia301Superplastic Deformation of CuO-Doped 3Y-TZP313Superplastic Forming of Zirconia321Superplastic Deformation of Zirconia/Alumina Composites Produced by Reaction Bonding333Enhanced Ductility of High-Purity Polycrystalline Yttria343Superplastic Deformation of a Monolithic Silicon Nitride351Creep Mechanisms in Multiphase Ceramics359High-Temperature Deformation Mechanisms in Ceramic Materials369Creep Recovery Mechanisms381Deformation of High-Temperature Superconductors393Stable Dislocation Configurations in [actual symbol not reproducible]403Creep Behavior of Cation Solid Solution Alloys415Kinetics and Mechanisms of Constant Stress Creep in the Non-Oxide Ceramics of SiC, SiC-Whisker-Reinforced Si[subscript 3]N[subscript 4] Composites and AlN424Dislocation Mechanisms in Alpha SiC Deformed at High Temperature445Evolution of Oxidation and Creep Damage Mechanisms in HIPed Silicon Nitride Materials457Bend Stress Relaxation and Tensile Primary Creep of Polycrystalline [alpha]-SiC Fiber467Importance of Cavitation to the Creep of Structural Ceramics479The Role of Grain Boundary Sliding on Creep Deformation Characteristics of Discontinuous Reinforced Composites495High-Temperature Deformation of Dual Phase Alumina-Zirconia Composites507Tensile Creep of Alumina and SiC Whisker-Reinforced Alumina519Plastic Deformation of Alumina Reinforced with SiC Whiskers533Creep Behavior in SiC Whisker-Reinforced Alumina Composite543High-Temperature Creep Behavior of High-Purity Hot-Pressed Silicon Nitride555Creep and Fatigue of SiC Fiber-Reinforced BMAS Glass-Ceramic Matrix Composites567Morphology and Deformation Characteristics of a CMC Based on a MLAS Vitroceramic Matrix577Fatigue Crack Growth in Ceramics and Ceramic Composites at High Temperatures589Mechanical Response of Ceramic Composites at Elevated Temperatures601Issues for Creep and Rupture Evaluation of Ceramic Fibers619Crack-Wake Plasticity and Time-Dependent Bridging During Subcritical Crack Growth in CVI-SiC Reinforced with Nicalon Fibers631Evaluation of Elevated-Temperature Crack Growth in Ceramics under Static and Cyclic Loads643Effect of Grain Size on Fatigue Crack Growth in Silicon Nitride and Alumina653Index667
\ BooknewsThe August 1994 conference emphasized the deformation of many of the newer, more complex ceramics, attempting to access what was previously learned from simple ceramic systems and extend that fundamental knowledge to the new systems. International authorities gave keynote lectures followed by presentations of invited individual papers. Sessions were devoted to general plasticity, indentation testing, superplasticity, general creep, creep in structural ceramics, creep in composites, fatigue and fracture, and thin films and irradiation effects. That organization sequence is generally followed in these proceedings. Annotation c. Book News, Inc., Portland, OR (booknews.com)\ \
