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Semiconductor Spintronics Thomas Schäpers

De Gruyter, 2016 354 pages, $84.00 (e-book $67.00) ISBN 978-3110361674

Published online by Cambridge University Press:  10 August 2017

Abstract

Type
Book Review
Copyright
Copyright © Materials Research Society 2017 

This book’s clear physics diagrams and theoretical models on magnetic semiconductors and spintronics are impressive. It contains almost all of the new findings on spin-related carriers in different dimensionalities as well as quantum descriptions. It includes a comprehensive discussion on spin-related physical phenomena, their quantum expressions, and future applications, which will be very helpful for graduate students and those beginning research in this field. It can work as a textbook on spintronics for those majoring in condensed-matter physics, as spin physics becomes more important in the field. The exercises listed in each chapter are well presented and helpful. This book will also help expand the concepts of semiconductor spintronics to more people and facilitate more research on new spin-related concepts and devices.

After the introduction to the book in chapter 1, chapter 2 focuses on low-dimensional semiconductor structures. Chapter 3 discusses magnetism in solids, and chapter 4 covers diluted magnetic semiconductors. Chapter 5 reviews magnetic electrodes. Chapter 6 focuses on spin injection; chapter 7 highlights the spin transistor; chapter 8 discusses spin interference; and chapter 9 covers the spin Hall effect. Chapter 10 reviews the quantum spin Hall effect. Chapter 11 describes topological insulators, and chapter 12 discusses quantum computation with electron spins.

Although this book is satisfactory, there are two areas that were omitted. It would have been useful for the book to cover spin-polarized excitations. In this rapidly growing field of research, spin-related carriers are not the only topic that should be covered. Optical techniques remain one of the most important tools to study magnetic semiconductors, but spin-related optical detection and application were not discussed. Perhaps these topics should belong to discussions of spin excitonics on spin photonics. Nonetheless, spin-related exciton and spin-polarized optical behaviors, though having fewer publications on these topics, are also important both in concepts and applications. For example, the excitonic magnetic polaron and its extensions in polarized luminescence, photo-induced ferromagnetism in quantum dots or nanostructures, and spontaneous spin optical orientations and coherent optical behaviors, and possibly the collective magnetic exciton condensation are important.

Additionally, according to recent literature, more examples of ferromagnetic semiconductors have been found in non-doped compounds, whose existence may add some complexity in spintronic materials because defects may also find applications in future spintronic devices. A more explicit discussion of this in chapter 4 would have helped provide a more complete description of semiconductor spintronics. If the author plans a second edition, it would be useful to add some sections or information on the above subjects.

Although the book could be enhanced with the additions discussed previously, this is a good book for graduate students in solid-state physics and semiconductor devices.

Reviewer: Bingsuo Zou of the Beijing Institute of Technology, China.