Overview
This book offers a comprehensive and tutorial-based exploration of semiconductor physics, combining the fundamentals of traditional (semiclassical) theory with the latest quantum approaches used to study semiconductor nanostructures. It thoroughly introduces the physical principles established by Shockley and Bardeen, focusing on the intrinsic and extrinsic properties of semiconductors. The content is presented with the necessary academic rigor, enabling readers to understand the behavior and operation of key semiconductor devices such as np junctions, bipolar transistors, solar cells, Schottky junctions, metal-oxide-semiconductors, and MOSFETs. The book is divided into two parts. The first part covers fundamental theory, including the semiclassical formalism, essential concepts for understanding n-type and p-type semiconductors, and the principles governing optoelectronic devices. It also introduces the foundations of simple quantum structures using the transfer matrix method within the scattering approach. The second part focuses on emblematic semiconductor devices, covering representative technologies such as light-emitting diodes, solar cells, bipolar transistors, Schottky junctions, MOS, and MOSFETs. It also explores advanced topics like the optical response of GaN-based blue-emitting lasers, transport in biased quantum heterostructures, tunneling time, integral quantum Hall effect, spin injection efficiency and spin inversion in magnetic superlattices, asymmetric quantum dots, quantum wires containing axial heterostructures, electronic transport in graphene, and multichannel disordered conductors. In addition to discussing well-known semiconductor properties, this book includes several advanced topics that have emerged in semiconductor physics over the last 30 years, many of which are based on the author’s research. These include the optical response of semiconductor superlattices, multichannel conductance in double potential barriers, spin injection, and spin manipulation, as well as tunneling times and the distribution of transition probabilities. The book also presents a novel analytical treatment of the inversion layer in MOS and MOSFET structures, offering new insight into a problem unsolved since the 1950s. Furthermore, it introduces a fresh theoretical perspective on the integral quantum Hall effect, providing a compact expression for the Hall resistance that captures the experimentally observed plateaus. While some theoretical developments and applications in this book require a background in quantum theory, the presentation is exhaustive, pedagogic, and clear enough for undergraduate students to follow.
Full Product Details
Author: Pedro Pereyra
Publisher: Springer
Imprint: Springer
ISBN: 9783032002952
ISBN 10: 3032002958
Pages: 410
Publication Date: 30 September 2025
Audience:
Professional and scholarly
,
Professional & Vocational
Format: Hardback
Publisher's Status: Forthcoming
Availability: Not yet available
This item is yet to be released. You can pre-order this item and we will dispatch it to you upon its release.
Author Information
Pedro Pereyra is Distinguished Professor at Universidad Autónoma Metropolitana (UAM), campus Azcapotzalco. Born in Bolivia, he obtained his B.Sc. from UMSA in La Paz, Bolivia, and his M.Sc. and Ph.D. from UNAM, Mexico. He completed a post-doctorate at the Max-Planck Institute for Nuclear Physics in Heidelberg. Since 1987, he has been Member of the Sistema Nacional de Investigadores (SNI). He has been awarded the UAM Research Prize three times (1994, 2001, 2003). He has also been Associate and Senior Associate of the ICTP in Trieste, Italy, and Visiting Professor at Ohio University, Universidad de la Habana, and the University of Regensburg. Prof. Pereyra's main contributions to physics include the DMPK equation and the multichannel theory of finite periodic systems. Prof. Pereyra has published around 100 papers and is Author of the book Fundamentals of Quantum Physics (2012, Springer).
