Overview

Semiconductor Device Physics and Design provides a fresh and unique teaching tool. Over the last decade device performances are driven by new materials, scaling, heterostructures and new device concepts. Semiconductor devices have mostly relied on Si but increasingly GaAs, InGaAs and heterostructures made from Si/SiGe, GaAs/AlGaAs etc have become important. Over the last few years one of the most exciting new entries has been the nitride based heterostructures. New physics based on polar charges and polar interfaces has become important as a result of the nitrides. Nitride based devices are now used for high power applications and in lighting and display applications. For students to be able to participate in this exciting arena, a lot of physics, device concepts, heterostructure concepts and materials properties need to be understood. It is important to have a textbook that teaches students and practicing engineers about all these areas in a coherent manner. Semiconductor Device Physics and Design starts out with basic physics concepts including the physics behind polar heterostructures and strained heterostructures. Important devices ranging from p-n diodes to bipolar and field effect devices is then discussed. An important distinction users will find in this book is the discussion presented on device needs from the perspective of various technologies. For example, how much gain is needed in a transistor, how much power, what kind of device characteristics are needed. Not surprisingly the needs depend upon applications. The needs of an A/D or D/A converter will be different from that of an amplifier in a cell phone. Similarly the diodes used in a laptop will place different requirements on the device engineer than diodes used in a mixer circuit. By relating device design to device performance and then relating device needs to system use the student can see how device design works in real world. This book is comprehensive without being overwhelming. The focus was to make this a useful text book so that the information contained is cohesive without including all aspects of device physics. The lesson plans demonstrated how this book could be used in a 1 semester or 2 quarter sequence.

Full Product Details

Author:   Umesh Mishra ,  Jasprit Singh
Publisher:   Springer
Imprint:   Springer
Edition:   2008 ed.
Dimensions:   Width: 15.50cm , Height: 3.00cm , Length: 23.50cm
Weight:   0.884kg
ISBN:  

9789400797789

ISBN 10:   9400797788
Pages:   559
Publication Date:   08 November 2014
Audience:   Professional and scholarly ,  Professional & Vocational
Format:   Paperback
Publisher's Status:   Active
Availability:   Manufactured on demand  
We will order this item for you from a manufactured on demand supplier.

Table of Contents

Acknowledgements. Preface. Introduction. 1 Structural Properties of Semiconductors. 1.1 INTRODUCTION. 1.2 CRYSTAL STRUCTURE. 1.3 LATTICE MISMATCHED STRUCTURES. 1.4 STRAINED EPITAXY:STRAIN TENSOR. 1.5 TECHNOLOGY CHALLENGES. 1.6 PROBLEMS. 1.7 FURTHER READING. 2 Electronic levels in semiconductors. 2.1 INTRODUCTION. 2.2 PARTICLES IN AN ATTRACTIVE POTENTIAL: BOUND STATES. 2.3 ELECTRONS IN CRYSTALLINE SOLIDS. 2.4 OCCUPATION OF STATES: DISTRIBUTION FUNCTION. 2.5 METALS AND INSULATORS. 2.6 BANDSTRUCTURE OF SOME IMPORTANT SEMICONDUCTORS. 2.7 MOBILE CARRIER. 2.8 DOPING OF SEMICONDUCTORS. 2.9 DOPING IN POLAR MATERIALS. 2.10 TAILORING ELECTRONIC PROPERTIES. 2.11 STRAINED HETEROSTRUCTURES. 2.12 DEFECT STATES IN SOLIDS. 2.13 TECHNOLOGY ISSUES. 2.14 PROBLEMS. 2.15 FURTHER READING. 3 Charge transport in materials. 3.1 INTRODUCTION. 3.2 CHARGE TRANSPORT:AN OVERVIEW. 3.3 TRANSPORT AND SCATTERING. 3.4 TRANSPORT UNDER AN ELECTRIC FIELD. 3.5 SOME IMPORTANT ISSUES IN TRANSPORT. 3.6 CARRIER TRANSPORT BY DIFFUSION. 3.7 CHARGE INJECTION AND QUASI-FERMI LEVELS. 3.8 CARRIER GENERATION AND RECOMBINATION. 3.9 CURRENT CONTINUITY(The law of conservation of electrons and holes separately). 3.10 PROBLEMS. 3.11 FURTHER READING. 4 Junctions in Semiconductors: P-N Diodes. 4.1 INTRODUCTION. 4.2 P-N JUNCTION IN EQUILIBRIUM. 4.3 P-N DIODE UNDER BIAS. 4.4 REAL DIODES: CONSEQUENCES OF DEFECTS AND CARRIER GENERATION. 4.5 REVERSE BIAS CHARACTERISITCS. 4.6 HIGH-VOLTAGE EFFECTS IN DIODES. 4.7 AVALANCHE BREAKDOWN IN A P-N JUNCTION. 4.8 DIODE APPLICATIONS:AN OVERVIEW. 4.9 LIGHT EMITTING DIODE (LED). 4.10 PROBLEMS. 4.11 DESIGN PROBLEMS. 4.12 FURTHER READING. 5 Semiconductor Junctions. 5.1 INTRODUCTION. 5.2 METAL INTERCONNECTS. 5.3 METAL SEMICONDUCTOR JUNCTION: SCHOTTKY BARRIER. 5.4 METAL SEMICONDUCTOR JUNCTIONS FOR OHMIC CONTACTS. 5.5 INSULATOR-SEMICONDUCTOR JUNCTIONS. 5.6 SEMICONDUCTOR HETEROJUNCTIONS. 5.7 PROBLEMS. 5.8 FURTHER READING. 6 Bipolar Junction Transistors. 6.1 INTRODUCTION. 6.2 BIPOLAR TRANSISTOR:A CONCEPTUAL PICTURE. 6.3 STATIC CHARACTERISTICS: CURRENT-VOLTAGE RELATION. 6.4 DEVICE DESIGN AND DEVICE PERFORMANCE PARAMETERS. 6.5 BJT DESIGN LIMITATIONS: NEED FOR BAND TAILORING AND HBTs. 6.6 SECONDARY EFFECTS IN REAL DEVICES. 6.7 PROBLEMS. 6.8 DESIGN PROBLEMS. 6.9 FURTHER READING. 7 Temporal Response Of Diodes and Bipolar Transistors. 7.1 INTRODUCTION. 7.2 MODULATION AND SWITCHING OF A P-N DIODE: AC RESPONSE. 7.3 TEMPORAL RESPONSE OF A SCHOTTKY DIODE. 7.4 BIPOLAR JUNCTION TRANSISTORS: A CHARGE-CONTROL ANALYSIS. 7.5 HIGH-FREQUENCY BEHAVIOR OF A BJT. 7.6 BIPOLAR TRANSISTORS: A TECHNOLOGY ROADMAP. 7.7 PROBLEMS. 7.8 DESIGN PROBLEMS. 8 Field Effect Transistors. 8.1 INTRODUCTION. 8.2 JFET AND MESFET: CHARGE CONTROL. 8.3 CURRENT-VOLTAGE CHARACTERISTICS. 8.4 HFETs: INTRODUCTION. 8.5 CHARGE CONTROL MODEL FOR THE MODFET. 8.6 POLAR MATERIALS AND STRUCTURES. 8.7 DESIGN ISSUES IN HFETS. 8.8 SMALL AND LARGE SIGNAL ISSUES AND FIGURES OF MERIT. 8.9 IMPLICATIONS ON DEVICE TECHNOLOGY AND CIRCUITS. 8.10 PROBLEMS. 8.11 DESIGN PROBLEMS. 8.12 FURTHER READING. 9 Field Effect Transistors: MOSFET. 9.1 INTRODUCTION. 9.2 MOSFET: DEVICES AND IMPACT. 9.3 METAL-OXIDE-SEMICONDUCTOR CAPACITOR. 9.4 CAPACITANCE-VOLTAGE CHARACTERISTICS OF THE MOS STRUCTURE. 9.5 MOSFET OPERATION. 9.6 IMPORTANT ISSUES AND FUTURE CHALLENGES IN REAL MOSFETS. 9.7 SUMMARY. 9.8 PROBLEMS. 9.9 DESIGN PROBLEMS. 9.10 FURTHER READING. 10 Coherent Transport and Mesoscopic Devices. 10.1 INTRODUCTION. 10.2 ZENER-BLOCH OSCILLATIONS. 10.3 RESONANT TUNNELING. 10.4 QUANTUM INTERFERENCE EFFECTS. 10.5 MESOSCOPIC STRUCTURES. 10.6 MAGNETIC SEMICONDUCTORS AND SPINTRONICS. 10.7 PROBLEMS. 10.8 FURTHER READING. A LIST OF SYMBOLS. B BOLTZMANN TRANSPORT THEORY. B.1 BOLTZMANN TRANSPORT EQUATION. B.2 AVERAGING PROCEDURES. C DENSITY OF STATES. D IMPORTANT PROPERTIES OF SEMICONDUCTORS.

Reviews

From the reviews: This book is a course very well written and comprehensive dedicated to semiconductors. The authors have detailed fundamental concepts from basic physics until research and development topics. ... Important semiconductors properties are summarized in useful tables at the end of the book. To help students to be familiar with the theory, examples are detailed in the text and at the end of each chapter exercises are proposed. (Gregory Guisbiers, Physicalia, Vol. 30 (2), 2008) This is a classical textbook about the physics of semiconductor devices. It is intended for electrical engineers, but is also useful for young physicists. The book is very clear and covers all the main knowledge necessary for a graduate student in the area of semiconductors ... . It contains many helpful figures, examples and problem sets. This book is also a good guide for teachers. In addition, advanced researchers could use it because the needed information is easy to find and extremely well synthesized. (Mircea Dragoman, Optics and Photonics News, September, 2008)

From the reviews: This book is a course very well written and comprehensive dedicated to semiconductors. The authors have detailed fundamental concepts from basic physics until research and development topics. ... Important semiconductors properties are summarized in useful tables at the end of the book. To help students to be familiar with the theory, examples are detailed in the text and at the end of each chapter exercises are proposed. (Gregory Guisbiers, Physicalia, Vol. 30 (2), 2008) This is a classical textbook about the physics of semiconductor devices. It is intended for electrical engineers, but is also useful for young physicists. The book is very clear and covers all the main knowledge necessary for a graduate student in the area of semiconductors ... . It contains many helpful figures, examples and problem sets. This book is also a good guide for teachers. In addition, advanced researchers could use it because the needed information is easy to find and extremely well synthesized. (Mircea Dragoman, Optics and Photonics News, September, 2008)

Author Information

Dr. Umesh K. Mishra is Professor at UC Santa Barbara in the Department of Electrical and Computer Engineering. His areas of focus include: Electronics and Photonics: high-speed transistors, semiconductor device physics, quantum electronics, optical control, design and fabrication of millimeter-wave devices, in situation processing and integration techniques.  Professor Mishra joined the College's ECE Department in 1990 from the Department of Electrical and Computer Engineering at North Carolina State University. A recognized leader in the area of high-speed field effect transistors, Dr. Mishra has made major contributions at every laboratory and academic institution for which he has worked, including: Hughes Research Laboratories in Malibu, California; the University of Michigan at Ann Arbor; and General Electric, Syracuse, New York. His current research areas attempt to develop an understanding of novel materials and extend them into applications. He is the Director of the AFOSR PRET Center for Non-Stoichiometric Semiconductors and of the ONR MURI Center (IMPACT), which relates to the application of SiC and GaN based transistors for power amplification. In 1989 Dr. Mishra received the Presidential Young Investigator Award from the National Science Foundation. In 1992 he received the Young Scientist of the Year Award from the International Symposium on GaAs and Related Compounds. He was elected as a Fellow of IEEE in 1995. Jasprit Singh joined the University of Michigan, Ann Arbor, in 1985 and he is Professor in the Electrical Engineering and Computer Science department.

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