Verfügbarkeit: Quantum processes in semiconductors /

Quantum processes in semiconductors /:

Aimed at graduate students, this is a guide to quantum processes of importance in the physics and technology of semiconductors. The fifth edition includes new chapters that expand the coverage of semiconductor physics relevant to its accompanying technology.

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Bibliographische Detailangaben
1. Verfasser:	Ridley, B. K. (VerfasserIn)
Format:	Elektronisch E-Book
Sprache:	English
Veröffentlicht:	Oxford : Oxford University Press, 2013.
Ausgabe:	Fifth edition.
Schlagworte:	Semiconductors. Quantum theory. Semiconductors Quantum Theory Semi-conducteurs. Théorie quantique. semiconductor. SCIENCE > Physics > Electricity. SCIENCE > Physics > Electromagnetism. Quantum theory
Online-Zugang:	Volltext
Zusammenfassung:	Aimed at graduate students, this is a guide to quantum processes of importance in the physics and technology of semiconductors. The fifth edition includes new chapters that expand the coverage of semiconductor physics relevant to its accompanying technology.
Beschreibung:	Previous edition: 1999.
Beschreibung:	1 online resource (xviii, 430 pages) : illustrations
Bibliographie:	Includes bibliographical references and indexes.
ISBN:	9780191664892 0191664898

Internformat

MARC


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publishDateSort	2013
publisher	Oxford University Press,
record_format	marc
spelling	Ridley, B. K., author. Quantum processes in semiconductors / B.K. Ridley, FRS, Professor Emeritus of Physics, University of Essex. Fifth edition. Oxford : Oxford University Press, 2013. ©2013 1 online resource (xviii, 430 pages) : illustrations text txt rdacontent computer c rdamedia online resource cr rdacarrier Previous edition: 1999. Includes bibliographical references and indexes. Print version record. Aimed at graduate students, this is a guide to quantum processes of importance in the physics and technology of semiconductors. The fifth edition includes new chapters that expand the coverage of semiconductor physics relevant to its accompanying technology. Cover; Contents; 1 Band structure of semiconductors; 1.1. The crystal Hamiltonian; 1.2. Adiabatic approximation; 1.3. Phonons; 1.4. The one-electron approximation; 1.5. Bloch functions; 1.6. Nearly-free-electron model; 1.6.1. Group theory notation; 1.7. Energy gaps; 1.8. Spin-orbit coupling and orbital characteristics; 1.9. Band structures; 1.10. Chemical trends; 1.11. k · p perturbation and effective mass; 1.11.1. Oscillator strengths; 1.12. Temperature dependence of energy gaps; 1.13. Deformation potentials; 1.14. Alloys; References; 2 Energy levels; 2.1. The effective-mass approximation 2.2. Electron dynamics2.3. Zener-Bloch oscillations; 2.4. Landau levels; 2.5. Plasma oscillations; 2.6. Excitons; 2.7. Hydrogenic impurities; 2.8. Hydrogen molecule centres; 2.9. Core effects; 2.10. Deep-level impurities; 2.11. Scattering states; 2.12. Impurity bands; References; 3 Lattice scattering; 3.1. General features; 3.2. Energy and momentum conservation; 3.2.1. Spherical parabolic band; 3.2.2. Spherical non-parabolic band; 3.2.3. Ellipsoidal parabolic bands; 3.2.4. Equivalent valleys; 3.2.5. Non-equivalent valleys; 3.3. Acoustic phonon scattering; 3.3.1. Spherical band: equipartition 3.3.2. Spherical band: zero-point scattering3.3.3. Spheroidal parabolic bands; 3.3.4. Momentum and energy relaxation; 3.4. Optical phonon scattering; 3.4.1. Inter-valley scattering; 3.4.2. First-order processes; 3.5. Polar optical mode scattering; 3.5.1. The effective charge; 3.5.2. Energy and momentum relaxation; 3.6. Piezoelectric scattering; 3.7. Scattering-induced electron mass; 3.8. Mobilities; 3.9. Appendix: Acoustic waves in the diamond lattice; References; 4 Impurity scattering; 4.1. General features; 4.2. Charged-impurity scattering; 4.2.1. Conwell-Weisskopf approximation 4.2.2. Brooks-Herring approach4.2.3. Uncertainty broadening; 4.2.4. Statistical screening; 4.3. Neutral-impurity scattering; 4.3.1. Hydrogenic models; 4.3.2. Square-well models; 4.3.3. Sclar's formula; 4.3.4. Resonance scattering; 4.3.5. Statistical screening; 4.4. Central-cell contribution to charged-impurity scattering; 4.5. Dipole scattering; 4.6. Electron-hole scattering; 4.7. Electron-electron scattering; 4.8. Mobilities; 4.9. Appendix: Debye screening length; 4.10. Appendix: Average separation of impurities; 4.11. Appendix: Alloy scattering; References; 5 Radiative transitions 5.1. Transition rate5.1.1. Local field correction; 5.1.2. Photon drag; 5.2. Photo-ionization and radiative capture cross-sections; 5.3. Wavefunctions; 5.4. Direct interband transitions; 5.4.1. Excitonic absorption; 5.5. Photo-deionization of a hydrogenic acceptor; 5.6. Photo-ionization of a hydrogenic donor; 5.7. Photo-ionization of quantum-defect impurities; 5.8. Photo-ionization of deep-level impurities; 5.9. Summary of photo-ionization cross-sections; 5.10. Indirect transitions; 5.11. Indirect interband transitions; 5.12. Free-carrier absorption; 5.12.1. Energy and momentum Semiconductors. http://id.loc.gov/authorities/subjects/sh85119903 Quantum theory. http://id.loc.gov/authorities/subjects/sh85109469 Semiconductors https://id.nlm.nih.gov/mesh/D012666 Quantum Theory https://id.nlm.nih.gov/mesh/D011789 Semi-conducteurs. Théorie quantique. semiconductor. aat SCIENCE Physics Electricity. bisacsh SCIENCE Physics Electromagnetism. bisacsh Quantum theory fast Semiconductors fast has work: Quantum processes in semiconductors (Text) https://id.oclc.org/worldcat/entity/E39PCGdtg3ymY6vRQFktBTykrC https://id.oclc.org/worldcat/ontology/hasWork Print version: Ridley, B.K. Quantum processes in semiconductors. Fifth edition 9780199677214 (DLC) 2013941293 (OCoLC)858935541 FWS01 ZDB-4-EBA FWS_PDA_EBA https://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&AN=643657 Volltext CBO01 ZDB-4-EBA FWS_PDA_EBA https://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&AN=643657 Volltext
spellingShingle	Ridley, B. K. Quantum processes in semiconductors / Cover; Contents; 1 Band structure of semiconductors; 1.1. The crystal Hamiltonian; 1.2. Adiabatic approximation; 1.3. Phonons; 1.4. The one-electron approximation; 1.5. Bloch functions; 1.6. Nearly-free-electron model; 1.6.1. Group theory notation; 1.7. Energy gaps; 1.8. Spin-orbit coupling and orbital characteristics; 1.9. Band structures; 1.10. Chemical trends; 1.11. k · p perturbation and effective mass; 1.11.1. Oscillator strengths; 1.12. Temperature dependence of energy gaps; 1.13. Deformation potentials; 1.14. Alloys; References; 2 Energy levels; 2.1. The effective-mass approximation 2.2. Electron dynamics2.3. Zener-Bloch oscillations; 2.4. Landau levels; 2.5. Plasma oscillations; 2.6. Excitons; 2.7. Hydrogenic impurities; 2.8. Hydrogen molecule centres; 2.9. Core effects; 2.10. Deep-level impurities; 2.11. Scattering states; 2.12. Impurity bands; References; 3 Lattice scattering; 3.1. General features; 3.2. Energy and momentum conservation; 3.2.1. Spherical parabolic band; 3.2.2. Spherical non-parabolic band; 3.2.3. Ellipsoidal parabolic bands; 3.2.4. Equivalent valleys; 3.2.5. Non-equivalent valleys; 3.3. Acoustic phonon scattering; 3.3.1. Spherical band: equipartition 3.3.2. Spherical band: zero-point scattering3.3.3. Spheroidal parabolic bands; 3.3.4. Momentum and energy relaxation; 3.4. Optical phonon scattering; 3.4.1. Inter-valley scattering; 3.4.2. First-order processes; 3.5. Polar optical mode scattering; 3.5.1. The effective charge; 3.5.2. Energy and momentum relaxation; 3.6. Piezoelectric scattering; 3.7. Scattering-induced electron mass; 3.8. Mobilities; 3.9. Appendix: Acoustic waves in the diamond lattice; References; 4 Impurity scattering; 4.1. General features; 4.2. Charged-impurity scattering; 4.2.1. Conwell-Weisskopf approximation 4.2.2. Brooks-Herring approach4.2.3. Uncertainty broadening; 4.2.4. Statistical screening; 4.3. Neutral-impurity scattering; 4.3.1. Hydrogenic models; 4.3.2. Square-well models; 4.3.3. Sclar's formula; 4.3.4. Resonance scattering; 4.3.5. Statistical screening; 4.4. Central-cell contribution to charged-impurity scattering; 4.5. Dipole scattering; 4.6. Electron-hole scattering; 4.7. Electron-electron scattering; 4.8. Mobilities; 4.9. Appendix: Debye screening length; 4.10. Appendix: Average separation of impurities; 4.11. Appendix: Alloy scattering; References; 5 Radiative transitions 5.1. Transition rate5.1.1. Local field correction; 5.1.2. Photon drag; 5.2. Photo-ionization and radiative capture cross-sections; 5.3. Wavefunctions; 5.4. Direct interband transitions; 5.4.1. Excitonic absorption; 5.5. Photo-deionization of a hydrogenic acceptor; 5.6. Photo-ionization of a hydrogenic donor; 5.7. Photo-ionization of quantum-defect impurities; 5.8. Photo-ionization of deep-level impurities; 5.9. Summary of photo-ionization cross-sections; 5.10. Indirect transitions; 5.11. Indirect interband transitions; 5.12. Free-carrier absorption; 5.12.1. Energy and momentum Semiconductors. http://id.loc.gov/authorities/subjects/sh85119903 Quantum theory. http://id.loc.gov/authorities/subjects/sh85109469 Semiconductors https://id.nlm.nih.gov/mesh/D012666 Quantum Theory https://id.nlm.nih.gov/mesh/D011789 Semi-conducteurs. Théorie quantique. semiconductor. aat SCIENCE Physics Electricity. bisacsh SCIENCE Physics Electromagnetism. bisacsh Quantum theory fast Semiconductors fast
subject_GND	http://id.loc.gov/authorities/subjects/sh85119903 http://id.loc.gov/authorities/subjects/sh85109469 https://id.nlm.nih.gov/mesh/D012666 https://id.nlm.nih.gov/mesh/D011789
title	Quantum processes in semiconductors /
title_auth	Quantum processes in semiconductors /
title_exact_search	Quantum processes in semiconductors /
title_full	Quantum processes in semiconductors / B.K. Ridley, FRS, Professor Emeritus of Physics, University of Essex.
title_fullStr	Quantum processes in semiconductors / B.K. Ridley, FRS, Professor Emeritus of Physics, University of Essex.
title_full_unstemmed	Quantum processes in semiconductors / B.K. Ridley, FRS, Professor Emeritus of Physics, University of Essex.
title_short	Quantum processes in semiconductors /
title_sort	quantum processes in semiconductors
topic	Semiconductors. http://id.loc.gov/authorities/subjects/sh85119903 Quantum theory. http://id.loc.gov/authorities/subjects/sh85109469 Semiconductors https://id.nlm.nih.gov/mesh/D012666 Quantum Theory https://id.nlm.nih.gov/mesh/D011789 Semi-conducteurs. Théorie quantique. semiconductor. aat SCIENCE Physics Electricity. bisacsh SCIENCE Physics Electromagnetism. bisacsh Quantum theory fast Semiconductors fast
topic_facet	Semiconductors. Quantum theory. Semiconductors Quantum Theory Semi-conducteurs. Théorie quantique. semiconductor. SCIENCE Physics Electricity. SCIENCE Physics Electromagnetism. Quantum theory
url	https://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&AN=643657
work_keys_str_mv	AT ridleybk quantumprocessesinsemiconductors

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