Ceramic Materials: Science and EngineeringSpringer Science & Business Media, 2007/04/04 - 716 ページ Ceramic Materials: Science and Engineering is an up-to-date treatment of ceramic science, engineering, and applications in a single, integrated text. Building on a foundation of crystal structures, phase equilibria, defects and the mechanical properties of ceramic materials, students are shown how these materials are processed for a broad diversity of applications in today's society. Concepts such as how and why ions move, how ceramics interact with light and magnetic fields, and how they respond to temperature changes are discussed in the context of their applications. References to the art and history of ceramics are included throughout the text. The text concludes with discussions of ceramics in biology and medicine, ceramics as gemstones and the role of ceramics in the interplay between industry and the environment. Extensively illustrated, the text also includes questions for the student and recommendations for additional reading. KEY FEATURES: Combines the treatment of bioceramics, furnaces, glass, optics, pores, gemstones, and point defects in a single text Provides abundant examples and illustrations relating theory to practical applications Suitable for advanced undergraduate and graduate teaching and as a reference for researchers in materials science Written by established and successful teachers and authors with experience in both research and industry |
目次
Introduction | 3 |
36 | 6 |
Some History | 15 |
Conducting Charge or | 30 |
Background You Need to Know | 35 |
Bonds and Energy Bands | 51 |
Models Crystals and Chemistry | 71 |
7 | 77 |
SolidState Phase Transformations and Reactions | 444 |
Processing Glass and GlassCeramics | 463 |
FeS2 | 476 |
Coatings and Thick Films | 481 |
Thin Films and Vapor Deposition | 494 |
Growing Single Crystals | 507 |
1 | 529 |
14 | 535 |
Binary Compounds | 87 |
10 | 93 |
Complex Crystal and Glass Structures | 100 |
6 | 106 |
Terms and Definitions | 119 |
Equilibrium Phase Diagrams | 120 |
Furnaces | 139 |
Interstitial Sites | 154 |
Point Defects Charge and Diffusion | 181 |
Computer Modeling | 199 |
Are Dislocations Unimportant? | 201 |
Surfaces Nanoparticles and Foams | 224 |
Interfaces in Polycrystals | 246 |
Phase Boundaries Particles and Pores | 269 |
Mechanical Testing | 289 |
Plasticity | 309 |
Background | 310 |
Brittleness | 325 |
Raw Materials | 345 |
Powders Fibers Platelets and Composites | 359 |
Glass and GlassCeramics | 379 |
Sols Gels and Organic Chemistry | 400 |
Shaping and Forming | 412 |
Sintering and Grain Growth | 427 |
Locally Redistributing Charge | 556 |
10 | 563 |
Piezoelectricity | 569 |
MoS2 and CdI2 | 575 |
Coloring Glass and Glazes | 581 |
Introduction | 596 |
Using Magnetic Fields and Storing Data | 598 |
Spinel | 606 |
529 | 618 |
Responding to Temperature Changes | 619 |
The Silicates and Structures Based on SiO4 | 625 |
Ceramics in Biology and Medicine | 635 |
650 | |
Olivine | 652 |
10 | 658 |
Chemical Stability Durability | 664 |
Treatment of Gems | 670 |
540 | 676 |
Mining | 682 |
691 | |
696 | |
697 | |
698 | |
多く使われている語句
alkoxides alumina anion applications atoms BaTiO3 bioceramics bonding Burgers vector carbon cations ceramics Chapter charge chemical coating color components composition contain covalent crack crystal structure crystalline cubic density determine diamond dielectric diffraction diffusion dislocation electrical electron equilibrium example ferrimagnetic ferroelectric fibers fracture Frenkel defects furnace gemstones glass glass-ceramic glaze glide plane grain boundaries graphite growth heat high temperatures illustrated in Figure important interface ionic ions lattice layer liquid magnetic materials mechanical melt metal method minerals Mullite NaCl nanoparticles occurs optical orbitals oxide oxygen particles perovskite phase diagram plane point defects polycrystalline pores powder pressure produce properties reaction sample sapphire Schematic Schottky defects semiconductors shown in Figure shows silica silicon single crystals sintering SiO2 sol-gel solid spinel stress substrate superconductors Table technique thermal conductivity thin films TiO2 tion types usually vacancies values vapor X-ray ZrO2