The Physics of Semiconductors

1. Front Matter

   Pages i-xxxvii

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2. Introduction

   • Marius Grundmann

   Pages 1-16

3. Fundamentals

   1. Front Matter

      Pages 17-17

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   2. Bonds

      • Marius Grundmann

      Pages 19-33

   3. Crystals

      • Marius Grundmann

      Pages 35-71

   4. Defects

      • Marius Grundmann

      Pages 73-102

   5. Mechanical Properties

      • Marius Grundmann

      Pages 103-138

   6. Band Structure

      • Marius Grundmann

      Pages 139-183

   7. Electronic Defect States

      • Marius Grundmann

      Pages 185-233

   8. Transport

      • Marius Grundmann

      Pages 235-263

   9. Optical Properties

      • Marius Grundmann

      Pages 265-307

   10. Recombination

       • Marius Grundmann

       Pages 309-344

4. Selected Topics

   1. Front Matter

      Pages 345-345

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   2. Heterostructures

      • Marius Grundmann

      Pages 347-378

   3. External Fields

      • Marius Grundmann

      Pages 379-395

   4. Nanostructures

      • Marius Grundmann

      Pages 397-423

   5. Polarized Semiconductors

      • Marius Grundmann

      Pages 425-439

   6. Magnetic Semiconductors

      • Marius Grundmann

      Pages 441-449

   7. Organic Semiconductors

      • Marius Grundmann

      Pages 451-463

   8. Graphene and Carbon Nanotubes

      • Marius Grundmann

      Pages 465-479

Semiconductorelectronicsiscommonplaceineveryhousehold.Semiconductor deviceshavealsoenabledeconomicallyreasonable?ber-basedopticalcom- nication, optical storage and high-frequency ampli?cation and have recently revolutionizedphotography,displaytechnologyandlighting.Alongwiththese tremendous technological developments, semiconductors have changed the way we work, communicate, entertain and think. The technological progress of semiconductor materials and devices is evolving continuously with a large worldwide e?ort in human and monetary capital. For students, semicond- tors o?er a rich, diverse and exciting ?eld with a great tradition and a bright future. This book introduces students to semiconductor physics and semicond- tor devices. It brings them to the point where they can specialize and enter supervisedlaboratoryresearch.Itisbasedonthetwosemestersemiconductor physics course taught at Universit¨ at Leipzig in its Master of Science physics curriculum. Since the book can be followed with little or no pre-existing knowledge in solid-state physics and quantum mechanics, it is also suitable for undergraduate students. For the interested reader some additional topics are included in the book that can be covered in subsequent, more speci- ized courses. The material is selected to provide a balance between aspects of solid-state and semiconductor physics, the concepts of various semiconductor devices and modern applications in electronics and photonics.

• Diffusion
• HTS
• Nanotube
• Semiconductor
• carbon nanotubes
• electricity
• quantum dot
• semiconductor physics
• solar cell
• thin film

From the reviews of the second edition:

“This textbook is divided into three parts. … The book has 247 figures, many of them in color. It is a clearly written and modern textbook for undergraduate and graduate students.” (Mircea Dragoman, Optics & Photonics News, July, 2011)

• Inst. Experimentelle Physik II, LS Halbleiterphysik, Univ. Leipzig, Leipzig, Germany

  Marius Grundmann

Professor Dr. Marius Grundman studied physics at the Technical University of Berlin. He worked on the epitaxy and characterization of electronic and optical properties of semiconductor heterostructures and nanostructures as well as devices made from them. He has been Professor of Experimental Physics at the University of Leipzig since 2000.

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