Verfügbarkeit: Quantum tunneling and field electron emission theories /

Quantum tunneling and field electron emission theories /:

Quantum tunneling is an essential issue in quantum physics. Especially, the rapid development of nanotechnology in recent years promises a lot of applications in condensed matter physics, surface science and nanodevices, which are growing interests in fundamental issues, computational techniques and...

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Bibliographische Detailangaben
1. Verfasser:	Liang, Shi-Dong (VerfasserIn)
Weitere Verfasser:	Yu, Song (HerausgeberIn)
Format:	Elektronisch E-Book
Sprache:	English
Veröffentlicht:	Singapore : World Scientific Publishing, 2014.
Schlagworte:	Tunneling (Physics) Quantum theory. Electrons > Emission. Effet tunnel. Théorie quantique. Émission électronique. SCIENCE > Energy. SCIENCE > Mechanics > General. SCIENCE > Physics > General. Electrons > Emission Quantum theory
Online-Zugang:	Volltext
Zusammenfassung:	Quantum tunneling is an essential issue in quantum physics. Especially, the rapid development of nanotechnology in recent years promises a lot of applications in condensed matter physics, surface science and nanodevices, which are growing interests in fundamental issues, computational techniques and potential applications of quantum tunneling. The book involves two relevant topics. One is quantum tunneling theory in condensed matter physics, including the basic concepts and methods, especially for recent developments in mesoscopic physics and computational formulation. The second part is the field electron emission theory, which covers the basic field emission concepts, the Fowler-Nordheim theory, and recent developments of the field emission theory especially in some fundamental concepts and computational formulation, such as quantum confinement effects, Dirac fermion, Luttinger liquid, carbon nanotubes, coherent emission current, quantum tunneling time problem, spin polarized field electron emission and non-equilibrium Green's function method for field electron emission. This book presents in both academic and pedagogical styles, and is as possible as self-complete to make it suitable for researchers and graduate students in condensed matter physics and vacuum nanoelectronics.
Beschreibung:	1 online resource (408 pages) : illustrations
Bibliographie:	Includes bibliographical references and index.
ISBN:	9789814440226 9814440221

Internformat

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505	0		\|a 1. Introduction -- Quantum tunneling theory. 2. Quantum physics and quantum formalism. 2.1. Quantum phenomena. 2.2. Quantum characteristics. 2.3. Quantum formalism. 2.4. Probability current and current conservation. 2.5. Quantum physics versus classical physics. 2.6. Mesoscopic physics and characteristic length. 2.7. Mathematics in classical and quantum worlds -- 3. Basic physics of quantum scattering and tunneling. 3.1. Definitions of quantum scattering and tunneling. 3.2. Description of quantum scattering and tunneling. 3.3. Basic physical quantities in quantum tunneling. 3.4. Relationships between transmission coefficient and scattering matrix. 3.5. Basic properties of scattering and transfer matrices. 3.6. Constraints of scattering and transfer matrices -- 4. Wave function matching method. 4.1. Square barrier model. 4.2. Asymmetric square barrier model. 4.3. Double square barrier model. 4.4. Multi-mode square barrier model. 4.5. Triangle barrier. 4.6. Lattice models -- 5. WKB method. 5.1. Mathematics ofWKB method. 5.2. Validity. 5.3. Solution of Schrödinger equation. 5.4. Quantum tunneling. 5.5. Triangle barrier. 5.6. Triangle and image potential barrier -- 6. Lippmann-Schwinger formalism. 6.1. Lippmann-Schwinger equation. 6.2. Wave function and S matrix. 6.3. Green's function and T matrix. 6.4. S matrix. 6.5. Adiabatic transport model. 6.6. Quantum tunneling in time-dependent barrier -- 7. Non-equilibrium Green's function method. 7.1. Basic physics of non-equilibrium transport problems. 7.2. Model of nanodevices. 7.3. Green's functions and self-energy. 7.4. Spectral function, density of states, and correlation function. 7.5. Definitions and relationships. 7.6. Current. 7.7. Tunneling model and master equation -- 8. Spin tunneling. 8.1. Tunneling magnetoresistance phenomena. 8.2. Julliére model. 8.3. Giant magnetoresistance. 8.4. Spin tunneling in spin-orbital coupling semiconductors. 8.5. Spin polarization. 8.6. Remarks -- 9. Applications. 9.1. Josephson effect. 9.2. Theory of scanning tunneling microscopy. 9.3. Conductance of graphene. 9.4. Charge transfer in DNA. 9.5. Remarks -- Field Electron Emission Theory. 10. Introduction. 10.1. Field electron emission phenomenon. 10.2. Brief history of field electron emission. 10.3. Basic concepts of field electron emission. 10.4. Basic issues of field electron emission. 10.5. Novel phenomena and challenges of field emission -- 11. Theoretical model and methodology. 11.1. Theoretical model of field emission. 11.2. Theoretical methodology. 11.3. Remarks -- 12. Fowler-Nordheim theory. 12.1. Assumptions of Fowler-Nordheim theory. 12.2. Fowler-Nordheim theory. 12.3. Remarks. 12.4. Beyond triangular vacuum potential barrier. 12.5. Energy band effect. 12.6. Finite temperature effect. 12.7. Basic characteristic of current-field relation. 12.8. Energy distribution of emission electrons. 12.9. Nottingham effect.
505	8		\|a 13. Field emission from semiconductors. 13.1. Basic properties of semiconductors. 13.2. Model of field emission from semiconductors. 13.3. Supply function density. 13.4. Vacuum potential barrier and transmission coefficient. 13.5. Total energy distribution. 13.6. Basic characteristics of total energy distribution. 13.7. Emission current density -- 14. Surface effects and resonance. 14.1. Field emission model with surface effects. 14.2. Double-barrier vacuum potential and transmission coefficient. 14.3. Total energy distribution. 14.4. Emission current density -- 15. Thermionic emission theory. 15.1. The Richardson theory of thermionic emission. 15.2. Boundary of field emission and thermionic emission -- 16. Theory of dynamical field emission. 16.1. Adiabatic process and dynamic field emission model. 16.2. Supply function and time-dependent transmission coefficient. 16.3. Dynamic total energy distribution. 16.4. Dynamic normal energy distribution. 16.5. Dynamic emission current. 16.6. Quantum tunneling time -- 17. Theory of spin polarized field emission. 17.1. Basic physics of spin polarized field emission. 17.2. Energy band spin-split model. 17.3. Spin-dependent triangular potential barrier model. 17.4. Spin-dependent image potential barrier model. 17.5. Finite temperature effects. 17.6. Comparison of spin polarizations. 17.7. A scheme of pure spin polarized electron emission induced by quantum spin Hall effect. 17.8. Difficulties and possibilities of spin polarized field emission -- 18. Theory of field electron emission from nanomaterials. 18.1. Basic physics of field emission from nanoemitters. 18.2. Formulation of field emission current density. 18.3. Computational framework. 18.4. Special case I: Sommerfeld model. 18.5. Special case II: nanowires. 18.6. Special case III: coupled nanowires. 18.7. Thermionic emission of nanowires. 18.8. Theory of field electron emission from carbon nanotubes. 18.9. Theory of Luttinger liquid field emission -- 19. Computer simulations of field emission. 19.1. Basic idea on computer simulation. 19.2. Formulation of field emission based on non-equilibrium Green's function method. 19.3. Tight-binding approach. 19.4. Cap and doping effects. 19.5. Field penetration effect and field enhancement factor. 19.6. First-principle method -- 20. The empirical theory of field emission. 20.1. The empirical theory of field emission. 20.2. The generalized empirical theory of field emission. 20.3. The empirical theory of thermionic emission. 20.4. Connection between empirical theory and experimental data -- 21. Fundamental physics of field electron emission. 21.1. Field emission behavior and material properties. 21.2. Equilibrium and non-equilibrium currents. 21.3. Many-body effect. 21.4. Coherent and non-coherent emission currents. 21.5. Electron emission mechanism: nano versus bulk effects. 21.6. Universality versus finger effects. 21.7. Open problems and difficulties. 21.8. Perspectives.
520			\|a Quantum tunneling is an essential issue in quantum physics. Especially, the rapid development of nanotechnology in recent years promises a lot of applications in condensed matter physics, surface science and nanodevices, which are growing interests in fundamental issues, computational techniques and potential applications of quantum tunneling. The book involves two relevant topics. One is quantum tunneling theory in condensed matter physics, including the basic concepts and methods, especially for recent developments in mesoscopic physics and computational formulation. The second part is the field electron emission theory, which covers the basic field emission concepts, the Fowler-Nordheim theory, and recent developments of the field emission theory especially in some fundamental concepts and computational formulation, such as quantum confinement effects, Dirac fermion, Luttinger liquid, carbon nanotubes, coherent emission current, quantum tunneling time problem, spin polarized field electron emission and non-equilibrium Green's function method for field electron emission. This book presents in both academic and pedagogical styles, and is as possible as self-complete to make it suitable for researchers and graduate students in condensed matter physics and vacuum nanoelectronics.
546			\|a English.
650		0	\|a Tunneling (Physics) \|0 http://id.loc.gov/authorities/subjects/sh85138672
650		0	\|a Quantum theory. \|0 http://id.loc.gov/authorities/subjects/sh85109469
650		0	\|a Electrons \|x Emission. \|0 http://id.loc.gov/authorities/subjects/sh85042426
650		6	\|a Effet tunnel.
650		6	\|a Théorie quantique.
650		6	\|a Émission électronique.
650		7	\|a SCIENCE \|x Energy. \|2 bisacsh
650		7	\|a SCIENCE \|x Mechanics \|x General. \|2 bisacsh
650		7	\|a SCIENCE \|x Physics \|x General. \|2 bisacsh
650		7	\|a Electrons \|x Emission \|2 fast
650		7	\|a Quantum theory \|2 fast
650		7	\|a Tunneling (Physics) \|2 fast
700	1		\|a Yu, Song, \|e editor.
776	0	8	\|i Print version: \|a Liang, Shi-Dong. \|t Quantum tunneling and field electron emission theories. \|d Singapore : World Scientific Publishing, ©2014 \|h xx, 387 pages \|z 9789814440219
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contents	1. Introduction -- Quantum tunneling theory. 2. Quantum physics and quantum formalism. 2.1. Quantum phenomena. 2.2. Quantum characteristics. 2.3. Quantum formalism. 2.4. Probability current and current conservation. 2.5. Quantum physics versus classical physics. 2.6. Mesoscopic physics and characteristic length. 2.7. Mathematics in classical and quantum worlds -- 3. Basic physics of quantum scattering and tunneling. 3.1. Definitions of quantum scattering and tunneling. 3.2. Description of quantum scattering and tunneling. 3.3. Basic physical quantities in quantum tunneling. 3.4. Relationships between transmission coefficient and scattering matrix. 3.5. Basic properties of scattering and transfer matrices. 3.6. Constraints of scattering and transfer matrices -- 4. Wave function matching method. 4.1. Square barrier model. 4.2. Asymmetric square barrier model. 4.3. Double square barrier model. 4.4. Multi-mode square barrier model. 4.5. Triangle barrier. 4.6. Lattice models -- 5. WKB method. 5.1. Mathematics ofWKB method. 5.2. Validity. 5.3. Solution of Schrödinger equation. 5.4. Quantum tunneling. 5.5. Triangle barrier. 5.6. Triangle and image potential barrier -- 6. Lippmann-Schwinger formalism. 6.1. Lippmann-Schwinger equation. 6.2. Wave function and S matrix. 6.3. Green's function and T matrix. 6.4. S matrix. 6.5. Adiabatic transport model. 6.6. Quantum tunneling in time-dependent barrier -- 7. Non-equilibrium Green's function method. 7.1. Basic physics of non-equilibrium transport problems. 7.2. Model of nanodevices. 7.3. Green's functions and self-energy. 7.4. Spectral function, density of states, and correlation function. 7.5. Definitions and relationships. 7.6. Current. 7.7. Tunneling model and master equation -- 8. Spin tunneling. 8.1. Tunneling magnetoresistance phenomena. 8.2. Julliére model. 8.3. Giant magnetoresistance. 8.4. Spin tunneling in spin-orbital coupling semiconductors. 8.5. Spin polarization. 8.6. Remarks -- 9. Applications. 9.1. Josephson effect. 9.2. Theory of scanning tunneling microscopy. 9.3. Conductance of graphene. 9.4. Charge transfer in DNA. 9.5. Remarks -- Field Electron Emission Theory. 10. Introduction. 10.1. Field electron emission phenomenon. 10.2. Brief history of field electron emission. 10.3. Basic concepts of field electron emission. 10.4. Basic issues of field electron emission. 10.5. Novel phenomena and challenges of field emission -- 11. Theoretical model and methodology. 11.1. Theoretical model of field emission. 11.2. Theoretical methodology. 11.3. Remarks -- 12. Fowler-Nordheim theory. 12.1. Assumptions of Fowler-Nordheim theory. 12.2. Fowler-Nordheim theory. 12.3. Remarks. 12.4. Beyond triangular vacuum potential barrier. 12.5. Energy band effect. 12.6. Finite temperature effect. 12.7. Basic characteristic of current-field relation. 12.8. Energy distribution of emission electrons. 12.9. Nottingham effect. 13. Field emission from semiconductors. 13.1. Basic properties of semiconductors. 13.2. Model of field emission from semiconductors. 13.3. Supply function density. 13.4. Vacuum potential barrier and transmission coefficient. 13.5. Total energy distribution. 13.6. Basic characteristics of total energy distribution. 13.7. Emission current density -- 14. Surface effects and resonance. 14.1. Field emission model with surface effects. 14.2. Double-barrier vacuum potential and transmission coefficient. 14.3. Total energy distribution. 14.4. Emission current density -- 15. Thermionic emission theory. 15.1. The Richardson theory of thermionic emission. 15.2. Boundary of field emission and thermionic emission -- 16. Theory of dynamical field emission. 16.1. Adiabatic process and dynamic field emission model. 16.2. Supply function and time-dependent transmission coefficient. 16.3. Dynamic total energy distribution. 16.4. Dynamic normal energy distribution. 16.5. Dynamic emission current. 16.6. Quantum tunneling time -- 17. Theory of spin polarized field emission. 17.1. Basic physics of spin polarized field emission. 17.2. Energy band spin-split model. 17.3. Spin-dependent triangular potential barrier model. 17.4. Spin-dependent image potential barrier model. 17.5. Finite temperature effects. 17.6. Comparison of spin polarizations. 17.7. A scheme of pure spin polarized electron emission induced by quantum spin Hall effect. 17.8. Difficulties and possibilities of spin polarized field emission -- 18. Theory of field electron emission from nanomaterials. 18.1. Basic physics of field emission from nanoemitters. 18.2. Formulation of field emission current density. 18.3. Computational framework. 18.4. Special case I: Sommerfeld model. 18.5. Special case II: nanowires. 18.6. Special case III: coupled nanowires. 18.7. Thermionic emission of nanowires. 18.8. Theory of field electron emission from carbon nanotubes. 18.9. Theory of Luttinger liquid field emission -- 19. Computer simulations of field emission. 19.1. Basic idea on computer simulation. 19.2. Formulation of field emission based on non-equilibrium Green's function method. 19.3. Tight-binding approach. 19.4. Cap and doping effects. 19.5. Field penetration effect and field enhancement factor. 19.6. First-principle method -- 20. The empirical theory of field emission. 20.1. The empirical theory of field emission. 20.2. The generalized empirical theory of field emission. 20.3. The empirical theory of thermionic emission. 20.4. Connection between empirical theory and experimental data -- 21. Fundamental physics of field electron emission. 21.1. Field emission behavior and material properties. 21.2. Equilibrium and non-equilibrium currents. 21.3. Many-body effect. 21.4. Coherent and non-coherent emission currents. 21.5. Electron emission mechanism: nano versus bulk effects. 21.6. Universality versus finger effects. 21.7. Open problems and difficulties. 21.8. Perspectives.
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Introduction -- Quantum tunneling theory. 2. Quantum physics and quantum formalism. 2.1. Quantum phenomena. 2.2. Quantum characteristics. 2.3. Quantum formalism. 2.4. Probability current and current conservation. 2.5. Quantum physics versus classical physics. 2.6. Mesoscopic physics and characteristic length. 2.7. Mathematics in classical and quantum worlds -- 3. Basic physics of quantum scattering and tunneling. 3.1. Definitions of quantum scattering and tunneling. 3.2. Description of quantum scattering and tunneling. 3.3. Basic physical quantities in quantum tunneling. 3.4. Relationships between transmission coefficient and scattering matrix. 3.5. Basic properties of scattering and transfer matrices. 3.6. Constraints of scattering and transfer matrices -- 4. Wave function matching method. 4.1. Square barrier model. 4.2. Asymmetric square barrier model. 4.3. Double square barrier model. 4.4. Multi-mode square barrier model. 4.5. Triangle barrier. 4.6. Lattice models -- 5. WKB method. 5.1. Mathematics ofWKB method. 5.2. Validity. 5.3. Solution of Schrödinger equation. 5.4. Quantum tunneling. 5.5. Triangle barrier. 5.6. Triangle and image potential barrier -- 6. Lippmann-Schwinger formalism. 6.1. Lippmann-Schwinger equation. 6.2. Wave function and S matrix. 6.3. Green's function and T matrix. 6.4. S matrix. 6.5. Adiabatic transport model. 6.6. Quantum tunneling in time-dependent barrier -- 7. Non-equilibrium Green's function method. 7.1. Basic physics of non-equilibrium transport problems. 7.2. Model of nanodevices. 7.3. Green's functions and self-energy. 7.4. Spectral function, density of states, and correlation function. 7.5. Definitions and relationships. 7.6. Current. 7.7. Tunneling model and master equation -- 8. Spin tunneling. 8.1. Tunneling magnetoresistance phenomena. 8.2. Julliére model. 8.3. Giant magnetoresistance. 8.4. Spin tunneling in spin-orbital coupling semiconductors. 8.5. Spin polarization. 8.6. Remarks -- 9. Applications. 9.1. Josephson effect. 9.2. Theory of scanning tunneling microscopy. 9.3. Conductance of graphene. 9.4. Charge transfer in DNA. 9.5. Remarks -- Field Electron Emission Theory. 10. Introduction. 10.1. Field electron emission phenomenon. 10.2. Brief history of field electron emission. 10.3. Basic concepts of field electron emission. 10.4. Basic issues of field electron emission. 10.5. Novel phenomena and challenges of field emission -- 11. Theoretical model and methodology. 11.1. Theoretical model of field emission. 11.2. Theoretical methodology. 11.3. Remarks -- 12. Fowler-Nordheim theory. 12.1. Assumptions of Fowler-Nordheim theory. 12.2. Fowler-Nordheim theory. 12.3. Remarks. 12.4. Beyond triangular vacuum potential barrier. 12.5. Energy band effect. 12.6. Finite temperature effect. 12.7. Basic characteristic of current-field relation. 12.8. Energy distribution of emission electrons. 12.9. Nottingham effect.</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">13. Field emission from semiconductors. 13.1. Basic properties of semiconductors. 13.2. Model of field emission from semiconductors. 13.3. Supply function density. 13.4. Vacuum potential barrier and transmission coefficient. 13.5. Total energy distribution. 13.6. Basic characteristics of total energy distribution. 13.7. Emission current density -- 14. Surface effects and resonance. 14.1. Field emission model with surface effects. 14.2. Double-barrier vacuum potential and transmission coefficient. 14.3. Total energy distribution. 14.4. Emission current density -- 15. Thermionic emission theory. 15.1. The Richardson theory of thermionic emission. 15.2. Boundary of field emission and thermionic emission -- 16. Theory of dynamical field emission. 16.1. Adiabatic process and dynamic field emission model. 16.2. Supply function and time-dependent transmission coefficient. 16.3. Dynamic total energy distribution. 16.4. Dynamic normal energy distribution. 16.5. Dynamic emission current. 16.6. Quantum tunneling time -- 17. Theory of spin polarized field emission. 17.1. Basic physics of spin polarized field emission. 17.2. Energy band spin-split model. 17.3. Spin-dependent triangular potential barrier model. 17.4. Spin-dependent image potential barrier model. 17.5. Finite temperature effects. 17.6. Comparison of spin polarizations. 17.7. A scheme of pure spin polarized electron emission induced by quantum spin Hall effect. 17.8. Difficulties and possibilities of spin polarized field emission -- 18. Theory of field electron emission from nanomaterials. 18.1. Basic physics of field emission from nanoemitters. 18.2. Formulation of field emission current density. 18.3. Computational framework. 18.4. Special case I: Sommerfeld model. 18.5. Special case II: nanowires. 18.6. Special case III: coupled nanowires. 18.7. Thermionic emission of nanowires. 18.8. Theory of field electron emission from carbon nanotubes. 18.9. Theory of Luttinger liquid field emission -- 19. Computer simulations of field emission. 19.1. Basic idea on computer simulation. 19.2. Formulation of field emission based on non-equilibrium Green's function method. 19.3. Tight-binding approach. 19.4. Cap and doping effects. 19.5. Field penetration effect and field enhancement factor. 19.6. First-principle method -- 20. The empirical theory of field emission. 20.1. The empirical theory of field emission. 20.2. The generalized empirical theory of field emission. 20.3. The empirical theory of thermionic emission. 20.4. Connection between empirical theory and experimental data -- 21. Fundamental physics of field electron emission. 21.1. Field emission behavior and material properties. 21.2. Equilibrium and non-equilibrium currents. 21.3. Many-body effect. 21.4. Coherent and non-coherent emission currents. 21.5. Electron emission mechanism: nano versus bulk effects. 21.6. Universality versus finger effects. 21.7. Open problems and difficulties. 21.8. Perspectives.</subfield></datafield><datafield tag="520" ind1=" " ind2=" "><subfield code="a">Quantum tunneling is an essential issue in quantum physics. Especially, the rapid development of nanotechnology in recent years promises a lot of applications in condensed matter physics, surface science and nanodevices, which are growing interests in fundamental issues, computational techniques and potential applications of quantum tunneling. The book involves two relevant topics. One is quantum tunneling theory in condensed matter physics, including the basic concepts and methods, especially for recent developments in mesoscopic physics and computational formulation. The second part is the field electron emission theory, which covers the basic field emission concepts, the Fowler-Nordheim theory, and recent developments of the field emission theory especially in some fundamental concepts and computational formulation, such as quantum confinement effects, Dirac fermion, Luttinger liquid, carbon nanotubes, coherent emission current, quantum tunneling time problem, spin polarized field electron emission and non-equilibrium Green's function method for field electron emission. This book presents in both academic and pedagogical styles, and is as possible as self-complete to make it suitable for researchers and graduate students in condensed matter physics and vacuum nanoelectronics.</subfield></datafield><datafield tag="546" ind1=" " ind2=" "><subfield code="a">English.</subfield></datafield><datafield tag="650" ind1=" " ind2="0"><subfield code="a">Tunneling (Physics)</subfield><subfield code="0">http://id.loc.gov/authorities/subjects/sh85138672</subfield></datafield><datafield tag="650" ind1=" " ind2="0"><subfield code="a">Quantum theory.</subfield><subfield code="0">http://id.loc.gov/authorities/subjects/sh85109469</subfield></datafield><datafield tag="650" ind1=" " ind2="0"><subfield code="a">Electrons</subfield><subfield code="x">Emission.</subfield><subfield code="0">http://id.loc.gov/authorities/subjects/sh85042426</subfield></datafield><datafield tag="650" ind1=" " ind2="6"><subfield code="a">Effet tunnel.</subfield></datafield><datafield tag="650" ind1=" " ind2="6"><subfield code="a">Théorie quantique.</subfield></datafield><datafield tag="650" ind1=" " ind2="6"><subfield code="a">Émission électronique.</subfield></datafield><datafield tag="650" ind1=" " ind2="7"><subfield code="a">SCIENCE</subfield><subfield code="x">Energy.</subfield><subfield code="2">bisacsh</subfield></datafield><datafield tag="650" ind1=" " ind2="7"><subfield code="a">SCIENCE</subfield><subfield code="x">Mechanics</subfield><subfield code="x">General.</subfield><subfield code="2">bisacsh</subfield></datafield><datafield tag="650" ind1=" " ind2="7"><subfield code="a">SCIENCE</subfield><subfield code="x">Physics</subfield><subfield code="x">General.</subfield><subfield code="2">bisacsh</subfield></datafield><datafield tag="650" ind1=" " ind2="7"><subfield code="a">Electrons</subfield><subfield code="x">Emission</subfield><subfield code="2">fast</subfield></datafield><datafield tag="650" ind1=" " ind2="7"><subfield code="a">Quantum theory</subfield><subfield code="2">fast</subfield></datafield><datafield tag="650" ind1=" " ind2="7"><subfield code="a">Tunneling (Physics)</subfield><subfield code="2">fast</subfield></datafield><datafield tag="700" ind1="1" ind2=" "><subfield code="a">Yu, Song,</subfield><subfield code="e">editor.</subfield></datafield><datafield tag="776" ind1="0" ind2="8"><subfield code="i">Print version:</subfield><subfield code="a">Liang, Shi-Dong.</subfield><subfield code="t">Quantum tunneling and field electron emission theories.</subfield><subfield code="d">Singapore : World Scientific Publishing, ©2014</subfield><subfield code="h">xx, 387 pages</subfield><subfield code="z">9789814440219</subfield></datafield><datafield tag="856" ind1="4" ind2="0"><subfield code="l">FWS01</subfield><subfield code="p">ZDB-4-EBA</subfield><subfield code="q">FWS_PDA_EBA</subfield><subfield code="u">https://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&AN=703949</subfield><subfield code="3">Volltext</subfield></datafield><datafield tag="936" ind1=" " ind2=" "><subfield code="a">BATCHLOAD</subfield></datafield><datafield tag="938" ind1=" " ind2=" "><subfield code="a">EBL - Ebook Library</subfield><subfield code="b">EBLB</subfield><subfield code="n">EBL1681692</subfield></datafield><datafield tag="938" ind1=" " ind2=" "><subfield code="a">ebrary</subfield><subfield code="b">EBRY</subfield><subfield code="n">ebr10852268</subfield></datafield><datafield tag="938" ind1=" " ind2=" "><subfield code="a">EBSCOhost</subfield><subfield code="b">EBSC</subfield><subfield code="n">703949</subfield></datafield><datafield tag="938" ind1=" " ind2=" "><subfield code="a">Cengage Learning</subfield><subfield code="b">GVRL</subfield><subfield code="n">GVRL8RBQ</subfield></datafield><datafield tag="938" ind1=" " ind2=" "><subfield code="a">ProQuest MyiLibrary Digital eBook Collection</subfield><subfield code="b">IDEB</subfield><subfield code="n">cis27466935</subfield></datafield><datafield tag="938" ind1=" " ind2=" "><subfield code="a">YBP Library Services</subfield><subfield code="b">YANK</subfield><subfield code="n">11608551</subfield></datafield><datafield tag="994" ind1=" " ind2=" "><subfield code="a">92</subfield><subfield code="b">GEBAY</subfield></datafield><datafield tag="912" ind1=" " ind2=" "><subfield code="a">ZDB-4-EBA</subfield></datafield><datafield tag="049" ind1=" " ind2=" "><subfield code="a">DE-863</subfield></datafield></record></collection>
id	ZDB-4-EBA-ocn878144605
illustrated	Illustrated
indexdate	2024-11-27T13:25:56Z
institution	BVB
isbn	9789814440226 9814440221
language	English
oclc_num	878144605
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owner	MAIN DE-863 DE-BY-FWS
owner_facet	MAIN DE-863 DE-BY-FWS
physical	1 online resource (408 pages) : illustrations
psigel	ZDB-4-EBA
publishDate	2014
publishDateSearch	2014
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publisher	World Scientific Publishing,
record_format	marc
spelling	Liang, Shi-Dong, author. Quantum tunneling and field electron emission theories / Shi-Dong Liang ; in-house editor, Song Yu. Singapore : World Scientific Publishing, 2014. ©2014 1 online resource (408 pages) : illustrations text txt rdacontent computer c rdamedia online resource cr rdacarrier Includes bibliographical references and index. Print version record. 1. Introduction -- Quantum tunneling theory. 2. Quantum physics and quantum formalism. 2.1. Quantum phenomena. 2.2. Quantum characteristics. 2.3. Quantum formalism. 2.4. Probability current and current conservation. 2.5. Quantum physics versus classical physics. 2.6. Mesoscopic physics and characteristic length. 2.7. Mathematics in classical and quantum worlds -- 3. Basic physics of quantum scattering and tunneling. 3.1. Definitions of quantum scattering and tunneling. 3.2. Description of quantum scattering and tunneling. 3.3. Basic physical quantities in quantum tunneling. 3.4. Relationships between transmission coefficient and scattering matrix. 3.5. Basic properties of scattering and transfer matrices. 3.6. Constraints of scattering and transfer matrices -- 4. Wave function matching method. 4.1. Square barrier model. 4.2. Asymmetric square barrier model. 4.3. Double square barrier model. 4.4. Multi-mode square barrier model. 4.5. Triangle barrier. 4.6. Lattice models -- 5. WKB method. 5.1. Mathematics ofWKB method. 5.2. Validity. 5.3. Solution of Schrödinger equation. 5.4. Quantum tunneling. 5.5. Triangle barrier. 5.6. Triangle and image potential barrier -- 6. Lippmann-Schwinger formalism. 6.1. Lippmann-Schwinger equation. 6.2. Wave function and S matrix. 6.3. Green's function and T matrix. 6.4. S matrix. 6.5. Adiabatic transport model. 6.6. Quantum tunneling in time-dependent barrier -- 7. Non-equilibrium Green's function method. 7.1. Basic physics of non-equilibrium transport problems. 7.2. Model of nanodevices. 7.3. Green's functions and self-energy. 7.4. Spectral function, density of states, and correlation function. 7.5. Definitions and relationships. 7.6. Current. 7.7. Tunneling model and master equation -- 8. Spin tunneling. 8.1. Tunneling magnetoresistance phenomena. 8.2. Julliére model. 8.3. Giant magnetoresistance. 8.4. Spin tunneling in spin-orbital coupling semiconductors. 8.5. Spin polarization. 8.6. Remarks -- 9. Applications. 9.1. Josephson effect. 9.2. Theory of scanning tunneling microscopy. 9.3. Conductance of graphene. 9.4. Charge transfer in DNA. 9.5. Remarks -- Field Electron Emission Theory. 10. Introduction. 10.1. Field electron emission phenomenon. 10.2. Brief history of field electron emission. 10.3. Basic concepts of field electron emission. 10.4. Basic issues of field electron emission. 10.5. Novel phenomena and challenges of field emission -- 11. Theoretical model and methodology. 11.1. Theoretical model of field emission. 11.2. Theoretical methodology. 11.3. Remarks -- 12. Fowler-Nordheim theory. 12.1. Assumptions of Fowler-Nordheim theory. 12.2. Fowler-Nordheim theory. 12.3. Remarks. 12.4. Beyond triangular vacuum potential barrier. 12.5. Energy band effect. 12.6. Finite temperature effect. 12.7. Basic characteristic of current-field relation. 12.8. Energy distribution of emission electrons. 12.9. Nottingham effect. 13. Field emission from semiconductors. 13.1. Basic properties of semiconductors. 13.2. Model of field emission from semiconductors. 13.3. Supply function density. 13.4. Vacuum potential barrier and transmission coefficient. 13.5. Total energy distribution. 13.6. Basic characteristics of total energy distribution. 13.7. Emission current density -- 14. Surface effects and resonance. 14.1. Field emission model with surface effects. 14.2. Double-barrier vacuum potential and transmission coefficient. 14.3. Total energy distribution. 14.4. Emission current density -- 15. Thermionic emission theory. 15.1. The Richardson theory of thermionic emission. 15.2. Boundary of field emission and thermionic emission -- 16. Theory of dynamical field emission. 16.1. Adiabatic process and dynamic field emission model. 16.2. Supply function and time-dependent transmission coefficient. 16.3. Dynamic total energy distribution. 16.4. Dynamic normal energy distribution. 16.5. Dynamic emission current. 16.6. Quantum tunneling time -- 17. Theory of spin polarized field emission. 17.1. Basic physics of spin polarized field emission. 17.2. Energy band spin-split model. 17.3. Spin-dependent triangular potential barrier model. 17.4. Spin-dependent image potential barrier model. 17.5. Finite temperature effects. 17.6. Comparison of spin polarizations. 17.7. A scheme of pure spin polarized electron emission induced by quantum spin Hall effect. 17.8. Difficulties and possibilities of spin polarized field emission -- 18. Theory of field electron emission from nanomaterials. 18.1. Basic physics of field emission from nanoemitters. 18.2. Formulation of field emission current density. 18.3. Computational framework. 18.4. Special case I: Sommerfeld model. 18.5. Special case II: nanowires. 18.6. Special case III: coupled nanowires. 18.7. Thermionic emission of nanowires. 18.8. Theory of field electron emission from carbon nanotubes. 18.9. Theory of Luttinger liquid field emission -- 19. Computer simulations of field emission. 19.1. Basic idea on computer simulation. 19.2. Formulation of field emission based on non-equilibrium Green's function method. 19.3. Tight-binding approach. 19.4. Cap and doping effects. 19.5. Field penetration effect and field enhancement factor. 19.6. First-principle method -- 20. The empirical theory of field emission. 20.1. The empirical theory of field emission. 20.2. The generalized empirical theory of field emission. 20.3. The empirical theory of thermionic emission. 20.4. Connection between empirical theory and experimental data -- 21. Fundamental physics of field electron emission. 21.1. Field emission behavior and material properties. 21.2. Equilibrium and non-equilibrium currents. 21.3. Many-body effect. 21.4. Coherent and non-coherent emission currents. 21.5. Electron emission mechanism: nano versus bulk effects. 21.6. Universality versus finger effects. 21.7. Open problems and difficulties. 21.8. Perspectives. Quantum tunneling is an essential issue in quantum physics. Especially, the rapid development of nanotechnology in recent years promises a lot of applications in condensed matter physics, surface science and nanodevices, which are growing interests in fundamental issues, computational techniques and potential applications of quantum tunneling. The book involves two relevant topics. One is quantum tunneling theory in condensed matter physics, including the basic concepts and methods, especially for recent developments in mesoscopic physics and computational formulation. The second part is the field electron emission theory, which covers the basic field emission concepts, the Fowler-Nordheim theory, and recent developments of the field emission theory especially in some fundamental concepts and computational formulation, such as quantum confinement effects, Dirac fermion, Luttinger liquid, carbon nanotubes, coherent emission current, quantum tunneling time problem, spin polarized field electron emission and non-equilibrium Green's function method for field electron emission. This book presents in both academic and pedagogical styles, and is as possible as self-complete to make it suitable for researchers and graduate students in condensed matter physics and vacuum nanoelectronics. English. Tunneling (Physics) http://id.loc.gov/authorities/subjects/sh85138672 Quantum theory. http://id.loc.gov/authorities/subjects/sh85109469 Electrons Emission. http://id.loc.gov/authorities/subjects/sh85042426 Effet tunnel. Théorie quantique. Émission électronique. SCIENCE Energy. bisacsh SCIENCE Mechanics General. bisacsh SCIENCE Physics General. bisacsh Electrons Emission fast Quantum theory fast Tunneling (Physics) fast Yu, Song, editor. Print version: Liang, Shi-Dong. Quantum tunneling and field electron emission theories. Singapore : World Scientific Publishing, ©2014 xx, 387 pages 9789814440219 FWS01 ZDB-4-EBA FWS_PDA_EBA https://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&AN=703949 Volltext
spellingShingle	Liang, Shi-Dong Quantum tunneling and field electron emission theories / 1. Introduction -- Quantum tunneling theory. 2. Quantum physics and quantum formalism. 2.1. Quantum phenomena. 2.2. Quantum characteristics. 2.3. Quantum formalism. 2.4. Probability current and current conservation. 2.5. Quantum physics versus classical physics. 2.6. Mesoscopic physics and characteristic length. 2.7. Mathematics in classical and quantum worlds -- 3. Basic physics of quantum scattering and tunneling. 3.1. Definitions of quantum scattering and tunneling. 3.2. Description of quantum scattering and tunneling. 3.3. Basic physical quantities in quantum tunneling. 3.4. Relationships between transmission coefficient and scattering matrix. 3.5. Basic properties of scattering and transfer matrices. 3.6. Constraints of scattering and transfer matrices -- 4. Wave function matching method. 4.1. Square barrier model. 4.2. Asymmetric square barrier model. 4.3. Double square barrier model. 4.4. Multi-mode square barrier model. 4.5. Triangle barrier. 4.6. Lattice models -- 5. WKB method. 5.1. Mathematics ofWKB method. 5.2. Validity. 5.3. Solution of Schrödinger equation. 5.4. Quantum tunneling. 5.5. Triangle barrier. 5.6. Triangle and image potential barrier -- 6. Lippmann-Schwinger formalism. 6.1. Lippmann-Schwinger equation. 6.2. Wave function and S matrix. 6.3. Green's function and T matrix. 6.4. S matrix. 6.5. Adiabatic transport model. 6.6. Quantum tunneling in time-dependent barrier -- 7. Non-equilibrium Green's function method. 7.1. Basic physics of non-equilibrium transport problems. 7.2. Model of nanodevices. 7.3. Green's functions and self-energy. 7.4. Spectral function, density of states, and correlation function. 7.5. Definitions and relationships. 7.6. Current. 7.7. Tunneling model and master equation -- 8. Spin tunneling. 8.1. Tunneling magnetoresistance phenomena. 8.2. Julliére model. 8.3. Giant magnetoresistance. 8.4. Spin tunneling in spin-orbital coupling semiconductors. 8.5. Spin polarization. 8.6. Remarks -- 9. Applications. 9.1. Josephson effect. 9.2. Theory of scanning tunneling microscopy. 9.3. Conductance of graphene. 9.4. Charge transfer in DNA. 9.5. Remarks -- Field Electron Emission Theory. 10. Introduction. 10.1. Field electron emission phenomenon. 10.2. Brief history of field electron emission. 10.3. Basic concepts of field electron emission. 10.4. Basic issues of field electron emission. 10.5. Novel phenomena and challenges of field emission -- 11. Theoretical model and methodology. 11.1. Theoretical model of field emission. 11.2. Theoretical methodology. 11.3. Remarks -- 12. Fowler-Nordheim theory. 12.1. Assumptions of Fowler-Nordheim theory. 12.2. Fowler-Nordheim theory. 12.3. Remarks. 12.4. Beyond triangular vacuum potential barrier. 12.5. Energy band effect. 12.6. Finite temperature effect. 12.7. Basic characteristic of current-field relation. 12.8. Energy distribution of emission electrons. 12.9. Nottingham effect. 13. Field emission from semiconductors. 13.1. Basic properties of semiconductors. 13.2. Model of field emission from semiconductors. 13.3. Supply function density. 13.4. Vacuum potential barrier and transmission coefficient. 13.5. Total energy distribution. 13.6. Basic characteristics of total energy distribution. 13.7. Emission current density -- 14. Surface effects and resonance. 14.1. Field emission model with surface effects. 14.2. Double-barrier vacuum potential and transmission coefficient. 14.3. Total energy distribution. 14.4. Emission current density -- 15. Thermionic emission theory. 15.1. The Richardson theory of thermionic emission. 15.2. Boundary of field emission and thermionic emission -- 16. Theory of dynamical field emission. 16.1. Adiabatic process and dynamic field emission model. 16.2. Supply function and time-dependent transmission coefficient. 16.3. Dynamic total energy distribution. 16.4. Dynamic normal energy distribution. 16.5. Dynamic emission current. 16.6. Quantum tunneling time -- 17. Theory of spin polarized field emission. 17.1. Basic physics of spin polarized field emission. 17.2. Energy band spin-split model. 17.3. Spin-dependent triangular potential barrier model. 17.4. Spin-dependent image potential barrier model. 17.5. Finite temperature effects. 17.6. Comparison of spin polarizations. 17.7. A scheme of pure spin polarized electron emission induced by quantum spin Hall effect. 17.8. Difficulties and possibilities of spin polarized field emission -- 18. Theory of field electron emission from nanomaterials. 18.1. Basic physics of field emission from nanoemitters. 18.2. Formulation of field emission current density. 18.3. Computational framework. 18.4. Special case I: Sommerfeld model. 18.5. Special case II: nanowires. 18.6. Special case III: coupled nanowires. 18.7. Thermionic emission of nanowires. 18.8. Theory of field electron emission from carbon nanotubes. 18.9. Theory of Luttinger liquid field emission -- 19. Computer simulations of field emission. 19.1. Basic idea on computer simulation. 19.2. Formulation of field emission based on non-equilibrium Green's function method. 19.3. Tight-binding approach. 19.4. Cap and doping effects. 19.5. Field penetration effect and field enhancement factor. 19.6. First-principle method -- 20. The empirical theory of field emission. 20.1. The empirical theory of field emission. 20.2. The generalized empirical theory of field emission. 20.3. The empirical theory of thermionic emission. 20.4. Connection between empirical theory and experimental data -- 21. Fundamental physics of field electron emission. 21.1. Field emission behavior and material properties. 21.2. Equilibrium and non-equilibrium currents. 21.3. Many-body effect. 21.4. Coherent and non-coherent emission currents. 21.5. Electron emission mechanism: nano versus bulk effects. 21.6. Universality versus finger effects. 21.7. Open problems and difficulties. 21.8. Perspectives. Tunneling (Physics) http://id.loc.gov/authorities/subjects/sh85138672 Quantum theory. http://id.loc.gov/authorities/subjects/sh85109469 Electrons Emission. http://id.loc.gov/authorities/subjects/sh85042426 Effet tunnel. Théorie quantique. Émission électronique. SCIENCE Energy. bisacsh SCIENCE Mechanics General. bisacsh SCIENCE Physics General. bisacsh Electrons Emission fast Quantum theory fast Tunneling (Physics) fast
subject_GND	http://id.loc.gov/authorities/subjects/sh85138672 http://id.loc.gov/authorities/subjects/sh85109469 http://id.loc.gov/authorities/subjects/sh85042426
title	Quantum tunneling and field electron emission theories /
title_auth	Quantum tunneling and field electron emission theories /
title_exact_search	Quantum tunneling and field electron emission theories /
title_full	Quantum tunneling and field electron emission theories / Shi-Dong Liang ; in-house editor, Song Yu.
title_fullStr	Quantum tunneling and field electron emission theories / Shi-Dong Liang ; in-house editor, Song Yu.
title_full_unstemmed	Quantum tunneling and field electron emission theories / Shi-Dong Liang ; in-house editor, Song Yu.
title_short	Quantum tunneling and field electron emission theories /
title_sort	quantum tunneling and field electron emission theories
topic	Tunneling (Physics) http://id.loc.gov/authorities/subjects/sh85138672 Quantum theory. http://id.loc.gov/authorities/subjects/sh85109469 Electrons Emission. http://id.loc.gov/authorities/subjects/sh85042426 Effet tunnel. Théorie quantique. Émission électronique. SCIENCE Energy. bisacsh SCIENCE Mechanics General. bisacsh SCIENCE Physics General. bisacsh Electrons Emission fast Quantum theory fast Tunneling (Physics) fast
topic_facet	Tunneling (Physics) Quantum theory. Electrons Emission. Effet tunnel. Théorie quantique. Émission électronique. SCIENCE Energy. SCIENCE Mechanics General. SCIENCE Physics General. Electrons Emission Quantum theory
url	https://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&AN=703949
work_keys_str_mv	AT liangshidong quantumtunnelingandfieldelectronemissiontheories AT yusong quantumtunnelingandfieldelectronemissiontheories

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