磁性半导体中的巨大磁致电阻及相分离COLOSSAL MAGNETORESISTANCE AND PHASE SEPARATION IN MAGNETIC SEMICONDUCTORS

作者： Eduard L. Nagaev等著

出 版 社： Aspen Publishers

出版时间： 2002-12-1字数：版次： 1页数： 457印刷时间： 2002/05/01开本：印次：纸张： 胶版纸I S B N ： 9781860942952包装： 精装内容简介

Colossal magnetoresistance materials, to which manganites and conventional ferromagnetic semiconductors belong, draw great attention because of their intriguing physical properties and the excellent prospects for their practical applications in electronic devices. In addition, magnetic semiconductors are basic materials for high-temperature conductors, and it is impossible to construct a theory of the latter without elucidating properties of the former.

This book presents theoretical and experimental results on manganites and conventional magnetic semiconductors, with emphasis on the former. Itis addressed mainly to researchers dealing with manganites or high- temperature super- conductors, but is also useful for undergraduate and graduate students.

目录

Appreciation

Preface

Chapter 1 Introduction and Necessary Information about Non-magnetic Semiconductors and Insulating Magnetic Systems

1.1. Introduction

1.1.1. Colossal magnetoresistance against giant magnetoresistance

1.1.2. Colossal magnetoresistance materials and other magnetic semiconductors

1.1.3. Magnetic semiconductors as strongly correlated electron systems. The simple and double exchange

1.1.4. From antiferromagnetic semiconductors to ferromagnetic semiconductors. Phase separation

1.1.5. The magnetoimpurity theory for the colossal magnetoresistance of ferromagnetic semiconductors

1.1.6. The resistivity peak and colossal magnetoresistance in the manganites

1.2. Some basic notions of semiconductor physics

1.2.1. The single-electron approach

1.2.2. Polarons

1.2.3. Mott delocalisation of charge carriers

1.2.4. Degenerate semiconductors

1.3 Some basic notions of the physics of magnetic phenomena

1.3.1. Magnetic Hamiltonians for orbitally non-degenerate and Jahn-Teller insulating systems

1.3.2. Properties of ferromagnets

1.3.3. Collinear and canted antiferromagnetic systems

1.3.4. Antiferromagnetic systems in magnetic field. Metamagnetism and "antimetamagnetism".

Chapter 2 Principles of Theory of Conducting Magnetic Systems

2.1. Magnetic Hamiltonians of conducting magnetic systems ..

2.2. Effect of magnetic ordering on energy of charge carders..

2.3. Double exchange

2.3.1. Classical spins

2.3.2. Quantum spins

2.4. RKKY indirect exchange

2.5. Non-Heisenberg exchange in magnetic semiconductors

Chapter 3 Non-degenerate Ferromagnetic Semiconductors

3.1. Experimental data

3.1.1. Magnetic and crystallographic properties

3.1.2. Optical properties

3.1.3. Conductivity and colossal magnetoresistance

3.2. Theory: free charge carrier energy spectrum and giant optical red shift

3.2.1. Spin wave region

3.2.2. The vicinity of the Curie point and the paramagnetic region (simple exchange)

……

Chapter 4 Non-degenerate Antiferromagnetic Semiconductors and Self-trapped States

Chapter 5 Degenerate Ferrmagnetic Semiconductors

Chapter 6 Degenerate Antiferronmagnetic Semiconductiors and Phase Separation

Chapter 7 Lanthanum Manganites

Chapter 8 Other Manganites

Chapter 9 Specific Effects and Theory of Manganites

Appendix A Double exchange Hamiltonian for quantum spins

Bibliography

Index