An Introduction to Electronic and Ionic MaterialsWorld Scientific, 1999 - 357 Seiten The subject of electronic and ionic materials has grown rapidly over the last 20 to 30 years. The application of these materials has had a significant impact on modern industries and on society in general. The subject is so important that no electrical engineering, materials science and engineering, applied physics or chemistry degree would be complete without it. This valuable textbook is aimed at engineering and technology undergraduates who have a background in physics or chemistry only at first year level. It provides a basic understanding of the properties and uses of a wide range of electrically and ionically conducting materials. It is not intended to be a solid state physics or chemistry book, and so the mathematics is kept to a minimum. However, it is intended to give the student an overview of a wide range of electrical materials and their uses in today's society. |
Inhalt
Introduction | 1 |
Classical Theory of Electrical Conduction | 8 |
Electron Energy in Solids | 34 |
Electron Emission | 50 |
Semiconductor Properties and Materials | 63 |
Magnetic Phenomena and Magnetic Materials | 107 |
Dielectric Materials | 148 |
Optical Properties and Materials | 173 |
Superconductivity and Superconductors | 217 |
Ionic Properties of Materials | 248 |
Mixed Conductivity | 306 |
Techniques for Studying the Conductivity | 318 |
Case Study The Solid Oxide Fuel Cell | 331 |
345 | |
351 | |
Thermal and Thermoelectric Properties | 202 |
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An Introduction To Electronic And Ionic Materials Wei Gao,Nigel M Sammes Eingeschränkte Leseprobe - 1999 |
Häufige Begriffe und Wortgruppen
alloys anode applications applied field atoms band gap beam BSCCO capacitor carriers cathode cation cell ceramic charge chemical circuit coefficient compounds concentration conduction band constant crystal structure defects density described devices dielectric material diffusion dipoles dopant doped effect elec electric field electrolyte electron hole electronic conductivity elements emission emitted energy gap energy level example extrinsic semiconductors ferrites ferromagnetic frequency function glass heat high temperature higher hole hysteresis impurity increases insulators interstitial intrinsic ion conductors ionic ionic conductivity laser lattice layer magnetic field magnetic materials magnetisation magnetostriction mechanical metals mobility n-type oxide oxygen oxygen ion oxygen partial pressure p-n junction p-type semiconductor partial pressure phase photons plot polarisation produce radiation reaction resistivity S/cm Science and Engineering Shepard and Wulff shown in Fig shows silicon single crystal SOFC solid superconducting surface technique thermal conductivity thermal expansion vacancies valence band voltage wavelength zirconia