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Table of Contents
Intro; Preface to Progress in Nanophotonics; Preface to Volume V; Contents; Contributors; 1 Historical Review of Dressed Photons: Experimental Progress and Required Theories; 1.1 Introduction; 1.2 History of the Modern Time; 1.3 Present Status of Experimental Studies; 1.4 Required Theories; 1.5 Toward Steps 1 and 2; 1.6 Application to Functional Devices; 1.6.1 Nano-Optical Condenser; 1.6.2 Energy Transmitter; 1.6.3 Autonomy in Dressed Photon Energy Transfer; 1.6.4 Temporal Evolution of Dressed Photon Energy Transfer; 1.7 Application to Optical Energy Conversion; 1.7.1 Principle.
1.7.2 Operating Characteristics1.7.3 Evaluation of the Optical Energy Conversion Efficiency; 1.8 Toward Step 3; 1.8.1 Principles of Creation and Measurement of Dressed Photons; 1.8.2 Performance of Fiber Probes; 1.8.3 Using Nanoparticles; 1.8.4 Requirements for Novel Theories; 1.9 Strategies for Novel Theories; 1.9.1 Problems to Be Solved; 1.9.2 Expected Theoretical Methods; 1.10 Summary; References; 2 Virtual Photon Model by Spatio-Temporal Vortex Dynamics; 2.1 Introduction; 2.2 On Longitudinal Electromagnetic Modes; 2.3 Physical Interpretation of Gauge Condition.
2.4 Clebsch Dual Field for Electromagnetic Waves2.4.1 Lightlike Case; 2.4.2 Non-lightlike Case; 2.5 New Model of Dressed Photon; 2.6 Concluding Remarks and on Extended Topics; References; 3 Quantum Probability for Dressed Photons: The Arcsine Law in Nanophotonics; 3.1 Introduction; 3.2 What is Dressed Photon?; 3.3 Toward Quantum Probability; 3.4 Quantum Probability Space; 3.4.1 What is Quantum Probability Space?; 3.4.2 ast-Algebras; 3.4.3 State; 3.4.4 Quantum Probability Space; 3.5 Algebraic Random Variables and Moments; 3.5.1 Algebraic Random Variables; 3.5.2 Moments.
3.5.3 Relation to Probability Measures3.5.4 Uncertaninty Principle; 3.6 Representation of Quantum Probability Space; 3.6.1 Representation of ast-Algebra; 3.6.2 GNS Representation; 3.7 Quantum-Classical Correspondence for Harmonic Oscillators; 3.7.1 What is Quantum-Classical Correnspondence?; 3.7.2 The Arcsine Law; 3.7.3 Quantum Harmonic Oscillator; 3.7.4 Quantum-Classical Correspondence for Harmonic Oscillator; 3.8 Quantum-Classical Correspondence for Interacting Fock space; 3.8.1 Interacting Fock Space; 3.8.2 Interacting Fock Spaces and Orthogonal Polynomials for Probability Measures.
1.7.2 Operating Characteristics1.7.3 Evaluation of the Optical Energy Conversion Efficiency; 1.8 Toward Step 3; 1.8.1 Principles of Creation and Measurement of Dressed Photons; 1.8.2 Performance of Fiber Probes; 1.8.3 Using Nanoparticles; 1.8.4 Requirements for Novel Theories; 1.9 Strategies for Novel Theories; 1.9.1 Problems to Be Solved; 1.9.2 Expected Theoretical Methods; 1.10 Summary; References; 2 Virtual Photon Model by Spatio-Temporal Vortex Dynamics; 2.1 Introduction; 2.2 On Longitudinal Electromagnetic Modes; 2.3 Physical Interpretation of Gauge Condition.
2.4 Clebsch Dual Field for Electromagnetic Waves2.4.1 Lightlike Case; 2.4.2 Non-lightlike Case; 2.5 New Model of Dressed Photon; 2.6 Concluding Remarks and on Extended Topics; References; 3 Quantum Probability for Dressed Photons: The Arcsine Law in Nanophotonics; 3.1 Introduction; 3.2 What is Dressed Photon?; 3.3 Toward Quantum Probability; 3.4 Quantum Probability Space; 3.4.1 What is Quantum Probability Space?; 3.4.2 ast-Algebras; 3.4.3 State; 3.4.4 Quantum Probability Space; 3.5 Algebraic Random Variables and Moments; 3.5.1 Algebraic Random Variables; 3.5.2 Moments.
3.5.3 Relation to Probability Measures3.5.4 Uncertaninty Principle; 3.6 Representation of Quantum Probability Space; 3.6.1 Representation of ast-Algebra; 3.6.2 GNS Representation; 3.7 Quantum-Classical Correspondence for Harmonic Oscillators; 3.7.1 What is Quantum-Classical Correnspondence?; 3.7.2 The Arcsine Law; 3.7.3 Quantum Harmonic Oscillator; 3.7.4 Quantum-Classical Correspondence for Harmonic Oscillator; 3.8 Quantum-Classical Correspondence for Interacting Fock space; 3.8.1 Interacting Fock Space; 3.8.2 Interacting Fock Spaces and Orthogonal Polynomials for Probability Measures.