Rare Earth and Transition Metal Doping of Semiconductor Materials: Synthesis, Magnetic Properties and Room Temperature Spintronics (Woodhead Publishing Series in Electronic and Optical Materials)

by Ian Ferguson (Editor), John M Zavada (Editor), Volkmar Dierolf (Editor)

New
Illustrated
2016
$299.17

Rare Earth and Transition Metal Doping of Semiconductor Material explores traditional semiconductor devices that are based on control of the electron's electric charge. This book looks at the semiconductor materials used for spintronics applications, in particular focusing on wide band-gap semiconductors doped with transition metals and rare earths. These materials are of particular commercial interest because their spin can be controlled at room temperature, a clear opposition to the most previous research on Gallium Arsenide, which allowed for control of spins at supercold temperatures. Part One of the book explains the theory of magnetism in semiconductors, while Part Two covers the growth of semiconductors for spintronics. Finally, Part Three looks at the characterization and properties of semiconductors for spintronics, with Part Four exploring the devices and the future direction of spintronics.

Synopsis

Rare Earth and Transition Metal Doping of Semiconductor Material explores traditional semiconductor devices that are based on control of the electron's electric charge. This book looks at the semiconductor materials used for spintronics applications, in particular focusing on wide band-gap semiconductors doped with transition metals and rare earths. These materials are of particular commercial interest because their spin can be controlled at room temperature, a clear opposition to the most previous research on Gallium Arsenide, which allowed for control of spins at supercold temperatures. Part One of the book explains the theory of magnetism in semiconductors, while Part Two covers the growth of semiconductors for spintronics. Finally, Part Three looks at the characterization and properties of semiconductors for spintronics, with Part Four exploring the devices and the future direction of spintronics.

$299.17

Quantity

20+ in stock

More Information

Format: Illustrated
Pages: 470
Edition: Illustrated
Publisher: Woodhead Publishing
Published: 01 Feb 2016
ISBN 10: 0081000413
ISBN 13: 9780081000410
Book Overview: This book provides a thorough exploration of the semiconductor materials used for spintronics applications, with a specific focus on wide band-gap semiconductors doped with transition metals and rare earths

Author Bio

Prof Dierolf came to Lehigh in 2000 with a Ph.D in Physics from the University of Utah, and a Habilitation from the University of Paderborn, Germany, He is the current Chair of the Physics Department and holds a Joint appointment with the Materials Science Department. In 2008, he was a Visiting Mercator Professor at the University of Bonn. He is on the International Committees of both the International and the European Conference on Defect in Insulating Materials (ICDIM, EuroDIM). He has served as a Principal Editor for the Journal of Materials Research and has been Guest Editor for Optical Materials. His research is focused on the optical spectroscopy and microscopy of insulating and semiconducting materials. His group exploits the wealth of information that can be obtained by combining high spatial resolution (down to 50nm) of a near field optical microscope or a SEM instrument with the structural and atomic scale information contained in excitation-emission data, cathodoluminescence and Raman spectra. Ferguson holds a Ph.D. in compound semiconductors from University of St. Andrews in Scotland (1989). He also holds a master of science in optoelectronics and laser devices from St. Andrews (1986) and a bachelor of science degree in physics from Heriot-Watt University in Scotland (1984). Prior to joining UNC Charlotte, Ferguson was a professor of electrical engineering at Georgia Institute of Technology from 2001 to 2009. While at Georgia Tech, he also served as director of the Focused Research Program on Next-Generation Lighting and held a faculty appointment in the School of Materials Science and Engineering from 2004 through 2009. Dr. Zavada received a BA degree in physics from Catholic University and MS and PhD degrees, also in physics, from New York University. He has held previous academic appointments at North Carolina State University and the Imperial College of Science and Technology in London. He is a Fellow of the Optical Society of America and a recipient of the Army's Meritorious Civilian Service Award.