Book contents
- Frontmatter
- Contents
- Introduction
- 1 Localized and itinerant electrons in solids
- 2 Isolated transition metal ions
- 3 Transition metal ions in crystals
- 4 Mott–Hubbard vs charge-transfer insulators
- 5 Exchange interaction and magnetic structures
- 6 Cooperative Jahn–Teller effect and orbital ordering
- 7 Charge ordering in transition metal compounds
- 8 Ferroelectrics, magnetoelectrics, and multiferroics
- 9 Doping of correlated systems; correlated metals
- 10 Metal–insulator transitions
- 11 Kondo effect, mixed valence, and heavy fermions
- Appendix A Some historical notes
- Appendix B A layman's guide to second quantization
- Appendix C Phase transitions and free energy expansion: Landau theory in a nutshell
- References
- Index
- Periodic Table of the Elements
10 - Metal–insulator transitions
Published online by Cambridge University Press: 05 November 2014
- Frontmatter
- Contents
- Introduction
- 1 Localized and itinerant electrons in solids
- 2 Isolated transition metal ions
- 3 Transition metal ions in crystals
- 4 Mott–Hubbard vs charge-transfer insulators
- 5 Exchange interaction and magnetic structures
- 6 Cooperative Jahn–Teller effect and orbital ordering
- 7 Charge ordering in transition metal compounds
- 8 Ferroelectrics, magnetoelectrics, and multiferroics
- 9 Doping of correlated systems; correlated metals
- 10 Metal–insulator transitions
- 11 Kondo effect, mixed valence, and heavy fermions
- Appendix A Some historical notes
- Appendix B A layman's guide to second quantization
- Appendix C Phase transitions and free energy expansion: Landau theory in a nutshell
- References
- Index
- Periodic Table of the Elements
Summary
In analyzing various phenomena in TM compounds in the previous chapter, we have already several times come across the situation when a material, depending on conditions, can be in an insulating or in a metallic state. Such metal–insulator transitions can be caused either by doping (a change in band filling) or by temperature, pressure, magnetic field, etc. The topic of metal–insulator transitions is one of the most interesting in the physics of systems with correlated electrons. Such metal–insulator transitions often lead to dramaticffects and a drastic change in all properties of the system; and the large sensitivity of materials close to such transitions to external perturbations can be used in many practical applications.
In principle, metal–insulator transitions are not restricted to systems with correlated electrons. They are often observed in more conventional solids, well described by the one-electron picture and standard band theory. However the most interesting such transitions, often significantly different from those in “band” systems, are indeed met in systems with strongly correlated electrons, in particular in transition metal compounds – see for example Mott (1990) or Gebhard (1997).
Different types of metal–insulator transitions
One can divide all metal–insulator transitions into three big groups; these are discussed in the sections below.
Metal–insulator transitions in the band picture
The first group of metal–insulator transitions are transitions which can be understood on the one-electron level in the framework of band theory – although, of course, interactions of some type are always necessary for such transitions.
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- Transition Metal Compounds , pp. 378 - 432Publisher: Cambridge University PressPrint publication year: 2014