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The classical and quantum dynamics of the multispherical nanostructures /

In this book, the issues regarding the theory of optics and quantum optics of spherical multilayered systems are studied. In such systems the spatial scale of layers becomes comparable with the wavelength of radiation, which complicates the analysis of important quantities such as reflectivity and t...

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Detalles Bibliográficos
Clasificación:Libro Electrónico
Autor principal: Burlak, Gennadiy
Formato: Electrónico eBook
Idioma:Inglés
Publicado: London : Hackensack, NJ : Imperial College Press ; Distributed by World Scientific Pub., ©2004.
Temas:
Acceso en línea:Texto completo
Tabla de Contenidos:
  • Cover
  • Preface
  • Contents
  • Introduction
  • I Classical Dynamics
  • 1. Maxwell Equations
  • 1.1 Basic Equations
  • 1.2 The Variational Principle
  • 1.3 Multilayered Microsphere
  • 1.4 The Transfer Matrix Method (Solving Equations for a System of Spherical Layers)
  • 1.5 Reflection Coefficient and Impedance of a Spherical Stack
  • 1.6 Conclusion
  • 2. Electromagnetic Field in Homogeneous Microspheres Without Surface Structures
  • 2.1 Experiments with Microspheres
  • 2.2 LorentzMie theory and its extensions
  • 2.3 Peculiarities of the modes of an open spherical cavity
  • 2.4 Quality factor of a whispering-gallery mode
  • 3. Electromagnetic Eigen Oscillations and Fields in a Dielectric Microsphere with Multilayer Spherical Stack
  • 3.1 Introduction
  • 3.2 Geometry and Basic Equations
  • 3.3 Eigenfrequencies of the Spherical Resonator Coated by the Stack
  • 3.4 Radial Distribution of Fields
  • 3.5 Discussions
  • 3.6 Conclusion
  • 4. Transmittance and Resonance Tunneling of the Optical Fields in the Microspherical Metal-Dielectric Structures
  • 4.1 Introduction
  • 4.2 Geometry and Basic Equations
  • 4.3 Results and Discussions
  • 4.4 Conclusion
  • 5. Confinement of Electromagnetic Oscillations in a Dielectric Microsphere Coated by the Frequency Dispersive Multilayers
  • 5.1 Introduction
  • 5.2 Basic Equations
  • 5.3 Results and Discussions
  • 5.4 Conclusion
  • 6. Oscillations in Microspheres with an Active Kernel
  • 6.1 Basic Equations
  • 6.2 Results and Discussions
  • 6.3 Conclusion
  • 7. Transfer Matrix Approach in a Non-Uniform Case
  • 7.1 Approach to a Non-Uniform Case
  • 7.2 Example. Non-Uniform Electrons Concentration
  • II The Quantum Phenomena in Microspheres
  • 8. Coupling of Two-Level Atom with Electromagnetic Field
  • 8.1 Transitions under the Action of the Electromagnetic Field
  • 8.2 The Equations for Probability Amplitudes
  • 8.3 Derivation of the Equation for Polarization of TLA: Dielectric Permittivity
  • 8.4 Temporal Dynamics of Polarization and the Probability Amplitudes
  • 9. Classical Field
  • 9.1 Schrodinger Equation
  • 9.2 Matrix Form for Two-Level Atom
  • 10. Quantization of Electromagnetic Field
  • 10.1 Energy of Field
  • 10.2 Structure of Vacuum Field
  • 11. Schrodinger and Interaction Pictures
  • 11.1 Equations for the State Vectors
  • 11.2 Equations for Operators
  • 12. Two-Level Atom (The Matrix Approach, a Quantized Field)
  • 12.1 Equations for Probability Amplitudes in Spherical Coordinates
  • 13. Dynamics of Spontaneous Emission of Two-Level Atom in Microspheres: Direct Calculation
  • 13.1 Introduction
  • 13.2 Basic Equations
  • 13.3 Results and Discussions
  • 13.4 Triple photon state
  • 13.5 Conclusions
  • III Numerical Methods and Object-Oriented Approach to the Problems of Multilayered Microsystems
  • 14. Use of Numerical Experiment
  • 14.1 Introduction
  • 14.2 The Brief Review of C++ Operators
  • 15. Exception Handling
  • 15.1 Code
  • 16. Visual Programming: Controls, Events and Handlers
  • 16.1 DOS and Visual Programming
  • 16.2 Controls, Events and Handlers
  • 16.3 Graphical User Interface
  • 17. Quantum Electromagnetic Field
  • 17.1 Introduction
  • 17.2 Code
  • 17.3 Classes
  • 18. Root Finding for Nonlinear and Complex Equations
  • 18.1 Introduction
  • 18.2 Code
  • 18.3 Cl.