Synopses & Reviews
Transition metal oxides form a series of compounds with a uniquely wide range of electronic properties. They have important applications as dielectrics, semiconductors, and metals, and as materials for magnetic and optical uses. The recent discovery of high-temperature superconductors has brought the attention of a wide scientific community to this area, and has highlighted the problems involved in trying to understand transition metal oxides. The present book is not primarily about high Tc superconductors, although their properties are discussed in the final section. The main aim is to describe the varied electronic behavior shown by transition metal oxides, and to discuss the different types of theoretical models that have been proposed to interpret it. It is intended to provide an introduction to this fascinating and complex field, at a level suitable for graduate students and other research workers with a background in solid-state chemistry or physics.
Review
"Eminently readable and lucid account. The book does serve as a guidebook for phenomena and concepts in the chemistry and physics of oxides and does provide a good, readable, elementary introduction to an area that has risen to prominence in the last two decades." --Journal of Solid State Chemistry
Review
"Eminently readable and lucid account. The book does serve as a guidebook for phenomena and concepts in the chemistry and physics of oxides and does provide a good, readable, elementary introduction to an area that has risen to prominence in the last two decades." --Journal of Solid State Chemistry
Table of Contents
1. Contents
1.1. Scope and Plan of the Book
1.2. Chemical Aspects
1.3. Structural Principles
1.4. Electronic Classification
2. Models of Electronic Structure
2.1. Ionic Models
2.2. Cluster Models
2.3. Band Theory
2.4. Intermediate Models
3. Insulating Oxides
3.1. Compounds
3.2. Other Closed Shell Oxides
3.3. Transition Metal Impurities
3.4. Magnetic Insulators
4. Defects and Semiconduction
4.1. Electronic carrier Properties
4.2. The Point-Defect Model
4.3. Carrier Binding Energies and Spectroscopy
4.4. Transition to the Metallic State
5. Metallic Oxides
5.1. Simple Metals
5.2. Electron Correlation and Magnetic Anomalies
5.3. Lattice Interactions
5.4. Superconductivity