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Semiconductor Physics

Semiconductor Physics - An Introduction - is suitable for the senior undergraduate or new graduate student majoring in electrical engineering or physics. It will also be useful to solid-state scientists and device engineers involved in semiconductor design and technology. The text provides a lucid account of charge transport, energy transport and optical processes, and a detailed description of many devices. It includes sections on superlattices and quantum well structures, the effects of deep-level impurities on transport, the quantum Hall effect and the calculation of the influence of a magnetic field on the carrier distribution function. This 6th edition has been revised and corrected, and new sections have been added to different chapters.

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  • "The first edition of "Semiconductor Physics" was published in 1973 by Springer-Verlag Wien-New York as a paperback in the Springer Study Edition. In 1977, a Russian translation by Professor Yu. K. Pozhela and coworkers at Vilnius/USSR was published by Izdatelstvo "MIR", Mo scow. Since then new ideas have been developed in the field of semi conductors such as electron hole droplets, dangling bond saturation in amorphous silicon by hydrogen, or the determination of the fine struc ture constant from surface quantization in inversion layers. New tech niques such as molecular beam epitaxy which has made the realization of the Esaki superlattice possible, deep level transient spectroscopy, and refined a. c. Hall techniques have evolved. Now that the Viennese edition is about to go out of print, Springer-Verlag, Berlin-Heidelberg-New York is giving me the opportunity to include these new subjects in a monograph to appear in the Solid-State Sciences series. Again it has been the intention to cover the field of semiconductor physics comprehensively, although some chapters such as diffusion of hot carriers and their galvanomagnetic phenomena, as well as super conducting degenerate semiconductors and the appendices, had to go for commercial reasons. The emphasis is more on physics than on device as pects."
  • "Televisions, telephones, watches, calculators, robots, airplanes and space vehicles all depend on silicon chips. Life as we know it would hardly be possible without semiconductor devices. An understanding of how these devices work requires a detailed knowledge of the physics of semiconductors, including charge transport and the emission and absorption of electromagnetic waves. This book may serve both as a university textbook and as a reference for research and microelectronics engineering. Each section of the book begins with a description of an experiment. The theory is then developed as far as necessary to understand the experimental results. Everyone with high-school mathematics should be able to follow the calculations. A band structure calculation for the diamond lattice is supplemented with a personal computer program. Semiconductor physics developed most rapidly in the two decades following the invention of the transistor, and naturally most of the references date from this time. But recent developments such as the Gunn effect, the acoustoelectric effect, superlattices, quantum well structures, and the integral and fractional quantum Hall effect are also discussed. The book has appeared in translation in Russian, Chinese and Japanese."
  • "Televisions, telephones, watches, calculators, robots, airplanes and space vehicles all depend on silicon chips. Life as we know it would hardly be possible without semiconductor devices. An understanding of how these devices work requires a detailed knowledge of the physics of semiconductors, including charge transport and the emission and absorption of electromagnetic waves. This book may serve both as a university textbook and as a reference for research and microelectronics engineering. Each section of the book begins with a description of an experiment. The theory is then developed as far as necessary to understand the experimental results. Everyone with high-school mathematics should be able to follow the calculations. The band structure calculations for the diamond and zinc blende types of lattice are supplemented with a personal computer program. Semiconductor physics developed most rapidly in the two decades following the invention of the transistor, and naturally most of the references date from this time. But recent developments such as the Gunn effect, the acoustoelectric effect, superlattices, quantum well structures, and the quantum Hall effect are also discussed. The exercises provided (answers to which are available) will greatly assist the student in consolidating the material presented. From the reviews:"This book is a must for any theoretical and experimental physicist working in the area of semiconductor physics." #Physicalia#1."
  • "Semiconductor Physics - An Introduction - is suitable for the senior undergraduate or new graduate student majoring in electrical engineering or physics. It will also be useful to solid-state scientists and device engineers involved in semiconductor design and technology. The text provides a lucid account of charge transport, energy transport and optical processes, and a detailed description of many devices. It includes sections on superlattices and quantum well structures, the effects of deep-level impurities on transport, the quantum Hall effect and the calculation of the influence of a magnetic field on the carrier distribution function. This 6th edition has been revised and corrected, and new sections have been added to different chapters."@en
  • "Semiconductor Physics - An Introduction - is suitable for the senior undergraduate or new graduate student majoring in electrical engineering or physics. It will also be useful to solid-state scientists and device engineers involved in semiconductor design and technology. The text provides a lucid account of charge transport, energy transport and optical processes, and a detailed description of many devices. It includes sections on superlattices and quantum well structures, the effects of deep-level impurities on transport, the quantum Hall effect and the calculation of the influence of a magnetic field on the carrier distribution function. This 6th edition has been revised and corrected, and new sections have been added to different chapters."
  • "This well-established monograph, updated and now in its ninth edition, deals mainly with electron transport in, and optical properties of semiconductors. It includes lasers, e.g. the quantum cascade laser, quantum processes such as the quantum Hall effect, quantum dots, fullerenes, carbon nanotubes, molecular electronics, the nitrides, and many other recent discoveries in the field. New diagrams and tables provide a comprehensive source of materials data. Selected problems help readers to consolidate their knowledge and invite teachers to use this text for graduate courses on semiconductor physics, solid state physics, and physical electronics."
  • "This book has been designed primarily as a text book for a three-semester, three· hour per week senior or graduate course in semiconductor physics for students In electrical engineering and physics, It may be supplemented by a solid state phy .. ics course. Prerequisites are courses in electrodynamics and -for some of the chapters -basic quantum mechanics. Emphasis has been laid on physical rather than technological aspects. Semiconductor physics is in fact an excellent and d ... · manding training ground for a future physicist or electrical engineer givina him an opportunity to practice a large variety of physical laws he was introduced to in the more fundamental courses. A detailed treatment of the transport and optical properties of semiconducton is given. It was decided to omit the usual description of the material propertkl of certain semiconductors and instead to include the "in· between" equations In mathematical derivations which I hope will make life simpler for a non·theorell· ciano In view of the many thousands of papers which appear every y ... ar in th ... field of semiconductor physics and which are distributed amona more than 30 journals, it would have been impossible for a single person to writ ... comprehen· sive book unless there had not been some excellent review art ides on speCial top ics published in the series "Solid State Physics", "FestkOrper·Probleme! Ad· vances in Solid State Physics", "Semiconductors and Semimetals". and "Proareu in Semiconductors", and I have leaned heavily on such review articles."@en
  • "It is a pleasure to take the opportunity to express my sincere grati tude to many colleagues who provided valuable hints for improvements, even including lists of misprints (which I hope have now been complete ly eliminated).It is not possible to name all of them, and so I will only mention the interesting discussions over so many years I had with Pro fessor Hans W. Pötzl of the Technical University of Vienna on the oc casion of our common weekly semiconductor seminar. I am grateful to Professor H.-J. Queisser and Professor M. Cardona for helpful criticism. Special thanks are due to Frau Jitka Fucik for typing and Frau Viktoria Köver for drawing services. The cooperation with Dr. H. K. Lotsch of Springer-Verlag has been a pleasure. Vienna, January 1982 K. Seeger Contents 1.Elementary Properties of Semiconductors . . .. I 1.1 Insulator - Semiconductor - Semimetal - Metal 1 1.2 The Positive Hole . . . . . . . . . . . . . 3 1.3 Conduction Processes, Compensation, Law ofMass Action 4 Problems . 8 2. Energy Band Structure . 10 2.1 Single and Periodically Repeated Potential Well 10 2.2 Energy Bands by Tight Binding ofElectrons to Atoms 17 2.3 The Brillouin Zone 21 2.4 Constant Energy Surfaces 30 Problems . 33 3. Semiconductor Statistics 34 3.1 Fermi Statistics . . . . . . . . . 35 3.2 Occupation Probabilities ofImpurity Levels 39 Problems . 45 4. Charge and Energy Transport in a Nondegenerate Electron Gas ."
  • "This well-established monograph, updated and now in its eighth edition, deals mainly with electron transport in, and optical properties of semiconductors, and includes a treatment of lasers and many other quantum processes. The book is aimed primarily at students of experimental solid-state physics, and assumes only a basic knowledge of mathematics (algebra etc.). In addition to the standard fundamental topics of semiconductor physics, the book also addresses recent developments in the fields of superlattices, quantum wires and quantum dots. New diagrams and tables provide a comprehensive source of materials data. Selected problems help readers to consolidate their knowledge and invite teachers to use this text for graduate courses on semiconductor physics and physical electronics."@en

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  • "Electronic books"@en
  • "Electronic books"
  • "Matériel didactique"
  • "Einführung"
  • "Lehrbuch"

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  • "Semiconductor physics : With 372 fig"
  • "Semiconductor Physics"@en
  • "Semiconductor Physics"
  • "Semiconductor physics : an introd"
  • "Semiconductor Physics an Introduction"
  • "Semiconductor physics an introduction"
  • "Semiconductor physics an introduction"@en
  • "Semiconductor physics : [an introduction]"
  • "Halbleiterphysik : eine Einführung"
  • "Halbleiterphysik eine Einführung"
  • "Semiconductor physics"
  • "Semiconductor physics"@en
  • "Semiconductor physics : an introduction"@en
  • "Semiconductor physics : an introduction"
  • "Semiconductor Physics : an introduction"
  • "Semiconductor physics : An introduction"
  • "Semiconductor Physics An Introduction"
  • "Halbleiterphysik"
  • "Semiconductor Physics [Spons. by the Ludwig Beltzmann-Ges. zur Förderg d. wiss. Forschung in Österreich]"

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