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Affiner la rechercheSupersymmetric Gravity and Black Holes / Stefano, Bellucci
Titre : Supersymmetric Gravity and Black Holes : Proceedings of the INFN-Laboratori Nazionali di Frascati School on the Attractor Mechanism 2009 Type de document : texte imprimé Auteurs : Stefano, Bellucci, Auteur Editeur : Berlin : Springer Année de publication : 2012 Collection : Springer proceedings in physics num. 142 Importance : 204p Présentation : ill Format : 15.5 x 24 cm ISBN/ISSN/EAN : 978-3-642-31379-0 Langues : Français (fre) Résumé : This book is based upon lectures presented in the summer of 2009 at the INFN-Laboratori Nazionali di Frascati School on Attractor Mechanism, directed by Stefano Bellucci. It is the fifth volume in a series of books on the general topics of supersymmetry, supergravity, black holes and the attractor mechanism. Supersymmetric Gravity and Black Holes : Proceedings of the INFN-Laboratori Nazionali di Frascati School on the Attractor Mechanism 2009 [texte imprimé] / Stefano, Bellucci, Auteur . - Berlin : Springer, 2012 . - 204p : ill ; 15.5 x 24 cm. - (Springer proceedings in physics; 142) .
ISBN : 978-3-642-31379-0
Langues : Français (fre)
Résumé : This book is based upon lectures presented in the summer of 2009 at the INFN-Laboratori Nazionali di Frascati School on Attractor Mechanism, directed by Stefano Bellucci. It is the fifth volume in a series of books on the general topics of supersymmetry, supergravity, black holes and the attractor mechanism. Exemplaires
Code-barres Cote Support Localisation Section Disponibilité BC2014/4456-5 530.142 SUP Ouvrage Bibliothèque de la Faculté des Sciences Physique Disponible BC2014/4456-2 BC.12-04-028 Ouvrage Bibliothèque Universitaire Centrale Géologie - Pédologie Disponible BC2014/4456-3 BC.12-04-028 Ouvrage Bibliothèque Universitaire Centrale Géologie - Pédologie Disponible Quantum Electrodynamics of Strong Fields / Walter Greiner
Titre : Quantum Electrodynamics of Strong Fields : With an Introduction into Modern Relativistic Quantum Mechanics Type de document : texte imprimé Auteurs : Walter Greiner, Auteur ; J.Rafelski, Auteur ; Müller, B, Auteur Editeur : Berlin : Springer Année de publication : 1985 Importance : 596p Présentation : ill.with 258 Figures Format : 17*24 cm ISBN/ISSN/EAN : 978-3-642-82274-2 Prix : 142,99 EUR Note générale : Textes and Monographs-Index-References-Bibliogr.p.(571) Langues : Anglais (eng) Mots-clés : Quantum Electrodynamics Strong Fields Index. décimale : 537.6 RAF Résumé : The fundamental goal of physics is an understanding of the forces of nature in their simplest and most general terms. Yet there is much more involved than just a basic set of equations which eventually has to be solved when applied to specific problems. We have learned in recent years that the structure of the ground state of field theories (with which we are generally concerned) plays an equally funda mental role as the equations of motion themselves. Heisenberg was probably the first to recognize that the ground state, the vacuum, could acquire certain prop erties (quantum numbers) when he devised a theory of ferromagnetism. Since then, many more such examples are known in solid state physics, e. g. supercon ductivity, superfluidity, in fact all problems concerned with phase transitions of many-body systems, which are often summarized under the name synergetics. Inspired by the experimental observation that also fundamental symmetries, such as parity or chiral symmetry, may be violated in nature, it has become wide ly accepted that the same field theory may be based on different vacua. Practical ly all these different field phases have the status of more or less hypothetical models, not (yet) directly accessible to experiments. There is one magnificent ex ception and this is the change of the ground state (vacuum) of the electron-posi tron field in superstrong electric fields. Note de contenu : Inhaltsverzeichnis
1. Introduction.- 1.1 The Charged Vacuum.- 1.2 From Theory to Experimental Verification.- 1.2.1 Superheavy Quasimolecules.- 1.2.2 Nuclear Sticking.- 1.2.3 K-Shell Ionization.- 1.3 Theoretical Developments.- 1.4 Historical Annotations on the Vacuum.- 1.4.1 The Concept of Vacuum.- 1.4.2 The Vacuum in Strong Fields.- 1.5 The Vacuum in Modern Quantum Physics.- 1.5.1 Pion Condensation.- 1.5.2 Strong Gravitational Fields.- 1.5.3 Vacuum Structure of Strongly Interacting Fermions and Bosons.- Bibliographical Notes.- 2. The Wave Equation for Spin-1/2 Particles.- 2.1 The Dirac Equation.- 2.2 The Free Dirac Particle.- 2.3 Single-Particle Interpretation of Plane (Free) Dirac Waves.- 2.4 The Dirac Particle Coupled to Electromagnetic Fields - Non-Relativistic Limits and Spin of the Dirac Equation.- 2.5 Lorentz Covariance of the Dirac Equation.- 2.5.1 Formulation of Covariance (Form Invariance).- 2.5.2 Determining the ?(â) Operator for Infinitesimal Lorentz Transformations.- 2.5.3 The ?(â) Operator for Finite Lorentz Transformations.- 2.5.4 Finite, Proper Lorentz Transformations.- 2.5.5 The ? Operator for Finite Lorentz Transformations.- 2.5.6 The Four-Current Density.- 2.6 Spinor Under Space Inversion (Parity Transformation).- 2.7 Bilinear Covariants of Dirac Spinors.- 2.8 Gauge Invariant Coupling of Electromagnetic and Spinor Field.- Bibliographical Notes.- 3. Dirac Particles in External Potentials.- 3.1 A Dirac Particle in a One-Dimensional Square Well Potential.- 3.2 A Dirac Particle in a Scalar, One-Dimensional Square Well Potential.- 3.3 A Dirac Particle in a Spherical Well.- 3.4 Solutions of the Dirac Equation for a Coulomb and a Scalar 1/r Potential.- 3.4.1 Pure Scalar Potential.- 3.4.2 Pure Coulomb Potential.- 3.4.3 Coulomb and Scalar Potential of Equal Strength (?? = ??).- 3.5 Stationary Continuum Waves for a Dirac Particle in a Coulomb Potential.- Bibliographical Notes.- 4. The Hole Theory.- 4.1 The "Dirac Sea".- 4.1.1 Historical Context.- 4.2 Charge Conjugation Symmetry.- 4.3 Charge Conjugation of States in External Potential.- 4.3.1 Historical Note.- 4.4 Parity and Time-Reversal Symmetry.- 4.4.1 Parity Invariance.- 4.4.2 Time-Reversal Symmetry.- Bibliographical Notes.- 5. The Klein Paradox.- 5.1 The Klein Paradox in the Single-Particle Interpretation of the Dirac Equation.- 5.2 Klein's Paradox and Hole Theory.- Bibliographical Notes.- 6. Resonant States in Supercritical Fields.- 6.1 Resonances in the Negative Energy Continuum.- 6.2 One Bound State Diving into One Continuum.- 6.2.1 Filled K Shell.- 6.2.2 Empty K Shell.- 6.3 Two and More Bound States Imbedded in One Continuum.- 6.4 One Bound State Imbedded in Several Continua.- 6.5 Overcritical Continuum States.- 6.5.1 Continuum Solutions for Extended Nuclei.- 6.5.2 Comments on the Point Nucleus Problem for Z? > |?|.- 6.5.3 The Physical Phase Shifts.- 6.5.4 Resonances in the Lower Continuum for Z > Zcr.- 6.5.5 The Vacuum Charge Distribution.- 6.6 Some Useful Mathematical Relations.- 6.6.1 A Different Choice of Phases.- Bibliographical Notes.- 7. Quantum Electrodynamics of Weak Fields.- 7.1 The Non-Relativistic Propagator.- 7.2 The S Matrix.- 7.3 Propagator for Electrons and Positrons.- 7.4 Relativistic Scattering Theory.- Bibliographical Notes.- 8. The Classical Dirac Field Interacting with a Classical Electromagnetic Field - Formal Properties.- 8.1 Field Equations in Hamiltonian Form.- 8.2 Conservation Laws.- 8.3 Representation by Energy Eigenmodes.- 8.3.1 Time-Independent Potentials.- 8.3.2 Explicitly Time-Dependent Potentials.- 8.4 The Elementary Field Functions.- Bibliographical Notes.- 9. Second Quantization of the Dirac Field and Definition of the Vacuum.- 9.1 Canonical Quantization of the Dirac Field.- 9.2 Fock Space and the Vacuum State (I).- 9.3 Poincaré Invariance of the Quantum Theory.- 9.4 Gauge Invariance and Discrete Symmetries.- 9.5 The Vacuum State (II).- 9.6 The Feynman Propagator.- 9.7 Charge and Energy of the Vacuum (I).- 9.8 Charge and Energy of the Vacuum (II).- 9.9 Appendix: Feynman Propagator for Time-Dependent Fields.- Bibliographical Notes.- 10. Evolution of the Vacuum State in Supercritical Potentials.- 10.1 The In/Out Formalism.- 10.2 Evolution of the Vacuum State.- 10.3 Decay of a Supercritical K Vacancy - Projection Formalism.- 10.4 Decay of the Neutral Vacuum - Schrödinger Picture.- 10.5 The Vacuum in a Constant Electromagnetic Field.- 10.6 Quantum Electrodynamics in Strong Macroscopic Fields.- 10.7 Klein's Paradox Revisited.- Bibliographical Notes.- 11. Superheavy Quasimolecules.- 11.1 Heavy-Ion Collisions: General Remarks.- 11.2 The Two-Centre Dirac Equation.- 11.3 The Critical Distance Rcr.- Bibliographical Notes.- 12. The Dynamics of Heavy-Ion Collisions.- 12.1 Rutherford Scattering.- 12.2 Expansion in the Quasi-Molecular Basis.- 12.3 Heavy-Ion Collisions: A Quantal Description.- 12.4 The Semiclassical Approximation.- 12.5 Collisions with Nuclear Interaction.- 12.6 Status of Numerical Calculations.- Bib
mehrQuantum Electrodynamics of Strong Fields : With an Introduction into Modern Relativistic Quantum Mechanics [texte imprimé] / Walter Greiner, Auteur ; J.Rafelski, Auteur ; Müller, B, Auteur . - Berlin : Springer, 1985 . - 596p : ill.with 258 Figures ; 17*24 cm.
ISBN : 978-3-642-82274-2 : 142,99 EUR
Textes and Monographs-Index-References-Bibliogr.p.(571)
Langues : Anglais (eng)
Mots-clés : Quantum Electrodynamics Strong Fields Index. décimale : 537.6 RAF Résumé : The fundamental goal of physics is an understanding of the forces of nature in their simplest and most general terms. Yet there is much more involved than just a basic set of equations which eventually has to be solved when applied to specific problems. We have learned in recent years that the structure of the ground state of field theories (with which we are generally concerned) plays an equally funda mental role as the equations of motion themselves. Heisenberg was probably the first to recognize that the ground state, the vacuum, could acquire certain prop erties (quantum numbers) when he devised a theory of ferromagnetism. Since then, many more such examples are known in solid state physics, e. g. supercon ductivity, superfluidity, in fact all problems concerned with phase transitions of many-body systems, which are often summarized under the name synergetics. Inspired by the experimental observation that also fundamental symmetries, such as parity or chiral symmetry, may be violated in nature, it has become wide ly accepted that the same field theory may be based on different vacua. Practical ly all these different field phases have the status of more or less hypothetical models, not (yet) directly accessible to experiments. There is one magnificent ex ception and this is the change of the ground state (vacuum) of the electron-posi tron field in superstrong electric fields. Note de contenu : Inhaltsverzeichnis
1. Introduction.- 1.1 The Charged Vacuum.- 1.2 From Theory to Experimental Verification.- 1.2.1 Superheavy Quasimolecules.- 1.2.2 Nuclear Sticking.- 1.2.3 K-Shell Ionization.- 1.3 Theoretical Developments.- 1.4 Historical Annotations on the Vacuum.- 1.4.1 The Concept of Vacuum.- 1.4.2 The Vacuum in Strong Fields.- 1.5 The Vacuum in Modern Quantum Physics.- 1.5.1 Pion Condensation.- 1.5.2 Strong Gravitational Fields.- 1.5.3 Vacuum Structure of Strongly Interacting Fermions and Bosons.- Bibliographical Notes.- 2. The Wave Equation for Spin-1/2 Particles.- 2.1 The Dirac Equation.- 2.2 The Free Dirac Particle.- 2.3 Single-Particle Interpretation of Plane (Free) Dirac Waves.- 2.4 The Dirac Particle Coupled to Electromagnetic Fields - Non-Relativistic Limits and Spin of the Dirac Equation.- 2.5 Lorentz Covariance of the Dirac Equation.- 2.5.1 Formulation of Covariance (Form Invariance).- 2.5.2 Determining the ?(â) Operator for Infinitesimal Lorentz Transformations.- 2.5.3 The ?(â) Operator for Finite Lorentz Transformations.- 2.5.4 Finite, Proper Lorentz Transformations.- 2.5.5 The ? Operator for Finite Lorentz Transformations.- 2.5.6 The Four-Current Density.- 2.6 Spinor Under Space Inversion (Parity Transformation).- 2.7 Bilinear Covariants of Dirac Spinors.- 2.8 Gauge Invariant Coupling of Electromagnetic and Spinor Field.- Bibliographical Notes.- 3. Dirac Particles in External Potentials.- 3.1 A Dirac Particle in a One-Dimensional Square Well Potential.- 3.2 A Dirac Particle in a Scalar, One-Dimensional Square Well Potential.- 3.3 A Dirac Particle in a Spherical Well.- 3.4 Solutions of the Dirac Equation for a Coulomb and a Scalar 1/r Potential.- 3.4.1 Pure Scalar Potential.- 3.4.2 Pure Coulomb Potential.- 3.4.3 Coulomb and Scalar Potential of Equal Strength (?? = ??).- 3.5 Stationary Continuum Waves for a Dirac Particle in a Coulomb Potential.- Bibliographical Notes.- 4. The Hole Theory.- 4.1 The "Dirac Sea".- 4.1.1 Historical Context.- 4.2 Charge Conjugation Symmetry.- 4.3 Charge Conjugation of States in External Potential.- 4.3.1 Historical Note.- 4.4 Parity and Time-Reversal Symmetry.- 4.4.1 Parity Invariance.- 4.4.2 Time-Reversal Symmetry.- Bibliographical Notes.- 5. The Klein Paradox.- 5.1 The Klein Paradox in the Single-Particle Interpretation of the Dirac Equation.- 5.2 Klein's Paradox and Hole Theory.- Bibliographical Notes.- 6. Resonant States in Supercritical Fields.- 6.1 Resonances in the Negative Energy Continuum.- 6.2 One Bound State Diving into One Continuum.- 6.2.1 Filled K Shell.- 6.2.2 Empty K Shell.- 6.3 Two and More Bound States Imbedded in One Continuum.- 6.4 One Bound State Imbedded in Several Continua.- 6.5 Overcritical Continuum States.- 6.5.1 Continuum Solutions for Extended Nuclei.- 6.5.2 Comments on the Point Nucleus Problem for Z? > |?|.- 6.5.3 The Physical Phase Shifts.- 6.5.4 Resonances in the Lower Continuum for Z > Zcr.- 6.5.5 The Vacuum Charge Distribution.- 6.6 Some Useful Mathematical Relations.- 6.6.1 A Different Choice of Phases.- Bibliographical Notes.- 7. Quantum Electrodynamics of Weak Fields.- 7.1 The Non-Relativistic Propagator.- 7.2 The S Matrix.- 7.3 Propagator for Electrons and Positrons.- 7.4 Relativistic Scattering Theory.- Bibliographical Notes.- 8. The Classical Dirac Field Interacting with a Classical Electromagnetic Field - Formal Properties.- 8.1 Field Equations in Hamiltonian Form.- 8.2 Conservation Laws.- 8.3 Representation by Energy Eigenmodes.- 8.3.1 Time-Independent Potentials.- 8.3.2 Explicitly Time-Dependent Potentials.- 8.4 The Elementary Field Functions.- Bibliographical Notes.- 9. Second Quantization of the Dirac Field and Definition of the Vacuum.- 9.1 Canonical Quantization of the Dirac Field.- 9.2 Fock Space and the Vacuum State (I).- 9.3 Poincaré Invariance of the Quantum Theory.- 9.4 Gauge Invariance and Discrete Symmetries.- 9.5 The Vacuum State (II).- 9.6 The Feynman Propagator.- 9.7 Charge and Energy of the Vacuum (I).- 9.8 Charge and Energy of the Vacuum (II).- 9.9 Appendix: Feynman Propagator for Time-Dependent Fields.- Bibliographical Notes.- 10. Evolution of the Vacuum State in Supercritical Potentials.- 10.1 The In/Out Formalism.- 10.2 Evolution of the Vacuum State.- 10.3 Decay of a Supercritical K Vacancy - Projection Formalism.- 10.4 Decay of the Neutral Vacuum - Schrödinger Picture.- 10.5 The Vacuum in a Constant Electromagnetic Field.- 10.6 Quantum Electrodynamics in Strong Macroscopic Fields.- 10.7 Klein's Paradox Revisited.- Bibliographical Notes.- 11. Superheavy Quasimolecules.- 11.1 Heavy-Ion Collisions: General Remarks.- 11.2 The Two-Centre Dirac Equation.- 11.3 The Critical Distance Rcr.- Bibliographical Notes.- 12. The Dynamics of Heavy-Ion Collisions.- 12.1 Rutherford Scattering.- 12.2 Expansion in the Quasi-Molecular Basis.- 12.3 Heavy-Ion Collisions: A Quantal Description.- 12.4 The Semiclassical Approximation.- 12.5 Collisions with Nuclear Interaction.- 12.6 Status of Numerical Calculations.- Bib
mehrExemplaires
Code-barres Cote Support Localisation Section Disponibilité FSEI19/132-2 537.6 RAF Ouvrage Bibliothèque de la Faculté des Sciences Physique Disponible Relativistic Quantum Mechanics. Wave Equations / Walter Greiner
Titre : Relativistic Quantum Mechanics. Wave Equations : With 62 Figures and 89 Worked Examples and Problems Type de document : texte imprimé Auteurs : Walter Greiner, Auteur Mention d'édition : 3rd edition Editeur : Berlin : Springer Année de publication : 1996 Importance : 424 p Présentation : ill., couv. ill. en coul Format : 19*25 cm ISBN/ISSN/EAN : 978-3-540-67457-3 Prix : 96,29 € Note générale : Index Langues : Anglais (eng) Mots-clés : Dirac equation Neutrino Quantenmechanik Handbuch/Lehrbuch quantum mechanics Index. décimale : 530.12 GRE Résumé : Relativistic Quantum Mechanics - Wave Equations concentrates mainly on the wave equations for spin-0 and spin-1/2 particles. Chapter 1 deals with the Klein-Gordon equation and its properties and applications. The chapters that follow introduce the Dirac equation, investigate its covariance properties and present various approaches to obtaining solutions. Numerous applications are discussed in detail, including the two-center Dirac equation, hole theory, CPT symmetry, Klein's paradox, and relativistic symmetry principles. Chapter 15 presents the relativistic wave equations for higher spin (Proca, Rarita-Schwinger, and Bargmann-Wigner). The extensive presentation of the mathematical tools and the 62 worked examples and problems make this a unique text for an advanced quantum mechanics course. Note de contenu : 1. Relativistic Wave Equation for Spin-0 Particles: The Klein—Gordon Equation and Its Applications.- 2. A Wave Equation for Spin-½ Particles: The Dirac Equation.- 3. Lorentz Covariance of the Dirac Equation.- 4. Spinors Under Spatial Reflection.- 5. Bilinear Covariants of the Dirac Spinors.- 6. Another Way of Constructing Solutions of the Free Dirac Equation: Construction by Lorentz Transformations.- 7. Projection Operators for Energy and Spin.- 8. Wave Packets of Plane Dirac Waves.- 9. Dirac Particles in External Fields: Examples and Problems.- 10.The Two-Centre Dirac Equation.- 11. The Foldy-Wouthuysen Representation for Free Particles.- 12. The Hole Theory.- 13. Klein’s Paradox.- 14. The Weyl Equation — The Neutrino.- 15. Wave Equations for Particles with Arbitrary Spins.- 16. Lorentz Invariance and Relativistic Symmetry Principles. Relativistic Quantum Mechanics. Wave Equations : With 62 Figures and 89 Worked Examples and Problems [texte imprimé] / Walter Greiner, Auteur . - 3rd edition . - Berlin : Springer, 1996 . - 424 p : ill., couv. ill. en coul ; 19*25 cm.
ISBN : 978-3-540-67457-3 : 96,29 €
Index
Langues : Anglais (eng)
Mots-clés : Dirac equation Neutrino Quantenmechanik Handbuch/Lehrbuch quantum mechanics Index. décimale : 530.12 GRE Résumé : Relativistic Quantum Mechanics - Wave Equations concentrates mainly on the wave equations for spin-0 and spin-1/2 particles. Chapter 1 deals with the Klein-Gordon equation and its properties and applications. The chapters that follow introduce the Dirac equation, investigate its covariance properties and present various approaches to obtaining solutions. Numerous applications are discussed in detail, including the two-center Dirac equation, hole theory, CPT symmetry, Klein's paradox, and relativistic symmetry principles. Chapter 15 presents the relativistic wave equations for higher spin (Proca, Rarita-Schwinger, and Bargmann-Wigner). The extensive presentation of the mathematical tools and the 62 worked examples and problems make this a unique text for an advanced quantum mechanics course. Note de contenu : 1. Relativistic Wave Equation for Spin-0 Particles: The Klein—Gordon Equation and Its Applications.- 2. A Wave Equation for Spin-½ Particles: The Dirac Equation.- 3. Lorentz Covariance of the Dirac Equation.- 4. Spinors Under Spatial Reflection.- 5. Bilinear Covariants of the Dirac Spinors.- 6. Another Way of Constructing Solutions of the Free Dirac Equation: Construction by Lorentz Transformations.- 7. Projection Operators for Energy and Spin.- 8. Wave Packets of Plane Dirac Waves.- 9. Dirac Particles in External Fields: Examples and Problems.- 10.The Two-Centre Dirac Equation.- 11. The Foldy-Wouthuysen Representation for Free Particles.- 12. The Hole Theory.- 13. Klein’s Paradox.- 14. The Weyl Equation — The Neutrino.- 15. Wave Equations for Particles with Arbitrary Spins.- 16. Lorentz Invariance and Relativistic Symmetry Principles. Exemplaires
Code-barres Cote Support Localisation Section Disponibilité FSEI19/127-2 530.12 GRE Ouvrage Bibliothèque de la Faculté des Sciences Physique Disponible Physical Models of Semiconductor Quantum Devices / Ying, Fu
Titre : Physical Models of Semiconductor Quantum Devices Type de document : texte imprimé Auteurs : Ying, Fu, Auteur Mention d'édition : 2nd edition Editeur : Berlin : Springer Année de publication : 2014 Importance : 408p Présentation : ill Format : 16*24 cm ISBN/ISSN/EAN : 978-94-00-77173-4 Prix : 209,50 inkl. Note générale : Index Langues : Anglais (eng) Mots-clés : Eigenstates External ac dc bias photonic nanostructures Ultrafast Femtosecond Lasers wave functions Index. décimale : 537.622 PHY Résumé : The science and technology relating to nanostructures continues to receive significant attention for its applications to various fields including microelectronics, nanophotonics, and biotechnology.
This book describes the basic quantum mechanical principles underlining this fast developing field.
From the fundamental principles of quantum mechanics to nanomaterial properties, from device physics to research and development of new systems, this title is aimed at undergraduates, graduates, postgraduates, and researchers.Physical Models of Semiconductor Quantum Devices [texte imprimé] / Ying, Fu, Auteur . - 2nd edition . - Berlin : Springer, 2014 . - 408p : ill ; 16*24 cm.
ISBN : 978-94-00-77173-4 : 209,50 inkl.
Index
Langues : Anglais (eng)
Mots-clés : Eigenstates External ac dc bias photonic nanostructures Ultrafast Femtosecond Lasers wave functions Index. décimale : 537.622 PHY Résumé : The science and technology relating to nanostructures continues to receive significant attention for its applications to various fields including microelectronics, nanophotonics, and biotechnology.
This book describes the basic quantum mechanical principles underlining this fast developing field.
From the fundamental principles of quantum mechanics to nanomaterial properties, from device physics to research and development of new systems, this title is aimed at undergraduates, graduates, postgraduates, and researchers.Exemplaires
Code-barres Cote Support Localisation Section Disponibilité FSEI16/003-2D 537.622 PHY Ouvrage Bibliothèque de la Faculté des Sciences Physique Disponible The Ocean in Motion / Manuel ;G. Velarde
Titre : The Ocean in Motion : Circulation, Waves, Polar Oceanography Type de document : texte imprimé Auteurs : Manuel ;G. Velarde, Auteur ; Roman ,Yu. Tarakanov, Auteur ; Alexey ,V. Marchenko, Auteur Editeur : Berlin : Springer Année de publication : 2019 Importance : 634p Présentation : ill., couv. ill Format : 15 x 17 cm ISBN/ISSN/EAN : 978-3-03-010131-2 Langues : Français (fre) Résumé : This book commemorates the 70th birthday of Eugene Morozov, the noted Russian observational oceanographer. It contains many contributions reflecting his fields of interest, including but not limited to tidal internal waves, ocean circulation, deep ocean currents, and Arctic oceanography.
Special attention is paid to studies on internal waves and especially those on tidal internal waves in the Global Ocean. These papers describe the most important open problems concerning experimental studies of internal waves and their theoretical, numerical, and laboratory modeling.
Further contributions investigate the physics of surface waves and their interaction with internal waves. Here, the focus is on describing interaction processes between internal waves and deep currents in the ocean, especially currents of Antarctic Bottom Water in abyssal fractures. They also touch on the problem of oceanic circulation and related processes in fjords, including those occurring under sea ice.
Given its breadth of coverage, the book will appeal to anyone interested in a survey of ocean dynamics, ranging from historic perspectives to modern research topics.The Ocean in Motion : Circulation, Waves, Polar Oceanography [texte imprimé] / Manuel ;G. Velarde, Auteur ; Roman ,Yu. Tarakanov, Auteur ; Alexey ,V. Marchenko, Auteur . - Berlin : Springer, 2019 . - 634p : ill., couv. ill ; 15 x 17 cm.
ISBN : 978-3-03-010131-2
Langues : Français (fre)
Résumé : This book commemorates the 70th birthday of Eugene Morozov, the noted Russian observational oceanographer. It contains many contributions reflecting his fields of interest, including but not limited to tidal internal waves, ocean circulation, deep ocean currents, and Arctic oceanography.
Special attention is paid to studies on internal waves and especially those on tidal internal waves in the Global Ocean. These papers describe the most important open problems concerning experimental studies of internal waves and their theoretical, numerical, and laboratory modeling.
Further contributions investigate the physics of surface waves and their interaction with internal waves. Here, the focus is on describing interaction processes between internal waves and deep currents in the ocean, especially currents of Antarctic Bottom Water in abyssal fractures. They also touch on the problem of oceanic circulation and related processes in fjords, including those occurring under sea ice.
Given its breadth of coverage, the book will appeal to anyone interested in a survey of ocean dynamics, ranging from historic perspectives to modern research topics.Exemplaires
Code-barres Cote Support Localisation Section Disponibilité BC2022/058-1 BC.34-01-037 Ouvrage Bibliothèque Universitaire Centrale Sciences de la Mer Exclu du prêt Probability Theory / Alexandr A. Borovkov
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