Electronic transport in semiconductors

A comprehensive treatment of the fundamentals of semiconductor physics and materials science. The first edition of the Survey of Semiconductor Physics set the standard for the multifaceted exploration of semiconductor physics. Now, Dr. Karl Boeer, one of the world's leading experts in solid-state physics, with assistance from a team of the fields top researchers, expands this coverage in the Second Edition. Completely updated and substantially expanded, the Survey of Semiconductor Physics, Second Edition covers the basic elements in the entire field of semiconductor physics, emphasizing the materials and surface science involved. The Second Edition uses similar theoretical approaches and analyses for the basic material classes: crystalline, amorphous, quantum structures, and organics. The first volume provides thorough coverage of the structure of semiconductors, including: Phonons Energy bands Photons as they interact with the semiconductor and other particles Defects Generation and recombination Kinetics Part I of the Volume 2 begins with a thorough treatment of the carrier transport in homogeneous semiconductors, creating the context for the studies of inhomogeneous semiconductors that consume the majority of the text. The editors' primary concerns are the effects and implications of surfaces, interfaces, inhomogeneous doping, and space charges upon the electronic transport. Part II provides a general overview of the types of abrupt material inhomogeneities that are produced by interfaces and surfaces. Part III presents a detailed mathematical analysis of the interrelation between space charges, fields, and carrier transport, applying these calculations to a wide array of specific examples. Returning to his stated emphasis on practical application, Boeer then focuses on the material preparations that are essential to produce semiconductor devices in Part IV and examines two specific examples of semiconductors-solar cells and light-emitting diodes-in Part V. In both volumes, extensive appendices simplify searches for important formulae and tables. An elaborate word index and reference listings allow readers to use the reference in multiple ways to discover expanding literature; to explore similarities and connecting principles in other fields; to find out how others in adjacent fields came up with intriguing solutions to similar problems; and to obtain a broad overview of the entire field of semiconductor physics.

• List of Tables
• Permissions
• Chapter 1. Introduction
• PART I: CARRIER TRANSPORT IN HOMOGENEOUS SEMICONDUCTORS
• Chapter 2. Basic Carrier Transport Equations
• Chapter 3. External and Built-In Fields
• Chapter 4. The Boltzmann Equation
• Chapter 5. Carriers in Magnetic Fields and Temperature Gradients
• Chapter 6. Magnetic Semiconductors and Diluted Magnetic Semiconductors
• Chapter 7. Giant Magnetoresistance and Related Phenomena
• Chapter 8. Carrier Scattering at Low Fields
• Chapter 9. Carrier Scattering at High Fields
• Chapter 10. Phase Transitions in Electron-Hole Systems
• Chapter 11. Superconductivity
• Chapter 12. Quasicarrier Mobilities
• Chapter 13. Noise
• Chapter 14. Carrier Transport in Superlattices
• Chapter 15. Defect-Induced Carrier Transport
• Chapter 16. Carrier Transport in Organic Semiconductors
• Chapter 17. Photoconductivity
• Chapter 18. Carrier Transit and Relaxation
• PART II: CARRIER TRANSPORT THROUGH SURFACES
• Chapter 19. Surface Influence on Bulk Properties
• Chapter 20. Electron Penetration Through Surfaces
• PART III: SPACE-CHARGE EFFECTS IN SEMICONDUCTORS
• Chapter 21. Space Charges and Their Creation in Semiconductors
• Chapter 22. The Schottky Barrier
• Chapter 23. Minority Carriers and Currents in Barriers
• Chapter 24. Schottky Barrier in Two-Carrier Model
• Chapter 25. pn Homojunctions
• Chapter 26. Carrier Velocity Limitation
• Chapter 27. Semiconductor Heterojunctions
• Chapter 28. The Photovoltaic Effect
• Chapter 29. The Schottky Barrier Photodiode
• Chapter 30. The pn Junction with Light
• Chapter 31. The Heterojunction with Light
• Chapter 32. The pin Junction with Light
• Chapter 33. High-Field Domains
• Chapter 34. Current Filaments
• PART IV: MATERIALS
• Chapter 35. Purification of Semiconductor Materials
• Chapter 36. Doping and Junction Formation
• Chapter 37. Electrodes
• PART V: SOME APPLICATIONS
• Chapter 38. Solar Cells
• Chapter 39. Light-Emitting Devices
• PART VI: APPENDIX, BIBLIOGRAPHY, INDEX
• Appendix
• Bibliography
• Index.