New York, : Wiley-VCH, c1999

9786612308147

9781282308145

1282308149

9780470145333

0470145331

9780470145548

0470145544

1 online resource (499 p.)

Inorganic reactions and methods ; ; v. 18

ZuckermanJ. J <1936-1987.> (Jerold J.)

AtwoodJim D. <1940->

541.3/9

541.39

Ceramics

Chemistry, Technical

Inglese

Description based upon print version of record.

Includes bibliographical references and indexes.

Inorganic Reactions and Methods; Contents; How to Use this Book; Preface to the Series; Editorial Consultants to the Series; Contributors to Volume 18; The Formation of Ceramics; Introduction; Ceramic Preparative Methods; Introduction; Preparation of Powders for Ceramic Processing; Purity, Particle Size Uniformity and Small Particle Size; Comminution Techniques; Solution Preparation; Coprecipitation; Sol Gel.; Freeze-Drying; Solvent Evaporation.; Vapor Phase Techniques; Reactions in the Vapor Phase.; Vapor Decomposition.; Direct Vaporization Condensation.; Thermal Decomposition

Densification of Ceramic PowdersIntroduction; Forming; Pressing of Dry or Semi-Dry Powders.; Casting of Concentrated Suspensions.; (i)Slip Casting.; (ii) Tape Casting.; Plastic Deformation of Powder Mixtures.; (i) Extrusion; (ii) Injection Molding.; Drying; Physical Principles of Drying.; Drying Defects.; Binder Removal; The Process of Thermal Debinding.;

Models for Thermal Debinding.; Firing; Principles of Solid State Sintering.; Experimental Observations of Solid-state Sintering.; Pressure Sintering.; Liquid-Phase Sintering.; Crystal Growth from Melts and Solutions; Growth from Melts

Pulling from the Melt.(i) Dislocations.; (ii) Facets; (iii) Striations.; (iv) Nonstoichiometry.; Directional Solidification.; Controlled Heat Removal.; Float Zone Growth.; Flame Fusion Method.; Skull Melting.; Shaped Crystal Growth.; Fiber Growth.; Arc-Fusion Method.; Growth from High-Melting Solutions; Slow Cooling.; Solvent Evaporation.; Solute Transport in a Temperature Gradient.; Traveling Solvent Zone Methods.; Flux Reaction Techniques1.; Electrocrystallization; Liquid-Phase Epitaxy (LPE).; Hydrothermal Synthesis of Ceramics; Growth from Other Solutions; Chemical Vapor Deposition

FundamentalsThermodynamics.; Kinetics and Transport Considerations.; Film Growth and Morphology.; Reaction Pathways; Pyrolysis; Oxidation/Hydrolysis; Reduction.; Carbidization/Nitridation; Disproportionation; Plasma CVD (PCVD); Non-Conventional CVD Techniques; Laser/Photo CVD.; Hot Filament CVD.; Ion Beam CVD.; Aerosol CVD.; Technologically Significant Ceramics via CVD; Silicon Dioxide.; Aluminium Oxide.; Silicon Nitride.; Titanium Dioxide.; Titanium Nitride.; Boron Nitride.; Aluminum Nitride.; Silicon Carbide.; Metal Oxides and High Tc Superconductors.; Doping; Doping from Solids

Group I Dopants.Group II Dopants.; Group Ill Dopants.; Group V Dopants.; Group VI Dopants.; Doping from Liquids; Directly Applied Liquid Sources; Liquid Sources for Open-Tube Diffusion.; Doping from the Vapor; Ion Implantation; Gas Flow or Liquid Vapor.; External Thermal Oven.; Sputtering, Electron Bombardment, Oxide-Chloride Conversion.; Neutron Transmutation Doping; The Synthesis and Fabrication of Ceramic for Special Application; Introduction; Preparation of Glasses for Special Applications; Bonding, Kinetic, and Other Factors that Favor Glass Formation; Glass Formation.; Glass Structure.

Composition of Glasses.

Boasting numerous industrial applications, inorganic chemistry forms the basis for research into new materials and bioinorganic compounds such as calcium that act as biological catalysts. Now complete, this highly acclaimed series presents current knowledge in all areas of inorganic chemistry, including chemistry of the elements; organometallic, polymeric and solid-state materials; and compounds relevant to bioinorganic chemistry.